Article
L-Arginine Modulates T Cell Metabolism and
Enhances Survival and Anti-tumor Activity
Graphical Abstract
Highlights
d Dataset on dynamic metabolome/proteome profiles of
activated human naive T cells
d Intracellular L-arginine levels regulate several metabolic
pathways in T cells
d T cells with increased L-arginine display enhanced survival
and anti-tumor activity
d LiP-MS identified proteins that are structurally modified by
high L-arginine levels
Authors
Roger Geiger, Jan C. Rieckmann,
Tobias Wolf, ..., Nicola Zamboni,
Federica Sallusto, Antonio Lanzavecchia
Correspondence
roger.geiger@irb.usi.ch (R.G.),
lanzavecchia@irb.usi.ch (A.L.)
In Brief
Metabolomic and proteomic profiling
unveil intracellular L-arginine as a crucial
regulator of metabolic fitness, survival
capacity, and anti-tumor activity of
central memory T cells.
Geiger et al., 2016, Cell 167, 829–842
October 20, 2016 ª 2016 The Author(s). Published by Elsevier Inc.
http://dx.doi.org/10.1016/j.cell.2016.09.031
Article
L-Arginine Modulates T Cell Metabolism
and Enhances Survival and Anti-tumor Activity
Roger Geiger,1,2,* Jan C. Rieckmann,3 Tobias Wolf,1,2 Camilla Basso,1 Yuehan Feng,4 Tobias Fuhrer,5 Maria Kogadeeva,5
Paola Picotti,4 Felix Meissner,3 Matthias Mann,3 Nicola Zamboni,5 Federica Sallusto,1,6 and Antonio Lanzavecchia1,2,7,*
1Institute for Research in Biomedicine, Universita` della Svizzera italiana, Bellinzona 6500, Switzerland
2Institute of Microbiology, ETH Zurich, Zurich 8093, Switzerland
3Department of Proteomics and Signal Transduction, Max Planck Institute of Biochemistry, Martinsried 82152, Germany
4Institute of Biochemistry, ETH Zurich, Zurich 8093, Switzerland
5Institute of Molecular Systems Biology, ETH Zurich, Zurich 8093, Switzerland
6Center of Medical Immunology, Institute for Research in Biomedicine, Universita` della Svizzera italiana, Bellinzona 6500, Switzerland
7Lead Contact
*Correspondence: roger.geiger@irb.usi.ch (R.G.), lanzavecchia@irb.usi.ch (A.L.)
http://dx.doi.org/10.1016/j.cell.2016.09.031
SUMMARY
Metabolic activity is intimately linked to T cell fate
and function. Using high-resolution mass spectrometry,
we generated dynamic metabolome and proteome
profiles of human primary naive T cells following
activation. We discovered critical changes in the
arginine metabolism that led to a drop in intracellular
L-arginine concentration. Elevating L-arginine levels
induced global metabolic changes including a shift
from glycolysis to oxidative phosphorylation in activated
T cells and promoted the generation of central
memory-like cells endowed with higher survival capacity
and, in a mouse model, anti-tumor activity.
Proteome-wide probing of structural alterations, validated
by the analysis of knockout T cell clones, identified
three transcriptional regulators (BAZ1B, PSIP1,
and TSN) that sensed L-arginine levels and promoted
T cell survival. Thus, intracellular L-arginine concentrations
directly impact the metabolic fitness and
survival capacity of T cells that are crucial for antitumor
responses.
INTRODUCTION
Upon antigenic stimulation, antigen-specific naive T cells proliferate
extensively and acquire different types of effector functions.
To support cell growth and proliferation, activated T cells
adapt their metabolism to ensure the generation of sufficient
biomass and energy (Fox et al., 2005). Unlike quiescent T cells,
which require little nutrients and mostly use oxidative phosphorylation
(OXPHOS) for their energy supply, activated T cells
consume large amounts of glucose, amino acids, and fatty acids
and adjust their metabolic pathways toward increased glycolytic
and glutaminolytic activity (Blagih et al., 2015; Rolf et al., 2013;
Sinclair et al., 2013; Wang et al., 2011).
At the end of the immune response, most T cells undergo
apoptosis, while a few survive as memory T cells that confer
long-term protection (Kaech and Cui, 2012; Sallusto et al.,
2010). T cell survival is regulated by extrinsic and intrinsic
factors. Prolonged or strong stimulation of the T cell receptor
(TCR) of CD4+
and CD8+
T cells promotes ‘‘fitness’’ by
enhancing survival and responsiveness to the homeostatic cytokines
IL-7 and IL-15, which in turn sustain expression of antiapoptotic
proteins (Gett et al., 2003; Schluns and Lefranc¸ ois,
2003; Surh et al., 2006). Metabolic activity is also critical to determine
T cell fate and memory formation (MacIver et al., 2013;
Pearce et al., 2013; Wang and Green, 2012). For instance, triglyceride
synthesis is central in IL-7-mediated survival of memory
CD8+
T cells (Cui et al., 2015), while increased mitochondrial
capacity endows T cells with a bioenergetic advantage for
survival and recall responses (van der Windt et al., 2012). Mitochondrial
fatty acid oxidation is required for the generation of
memory T cells (Pearce et al., 2009), while the mammalian target
of rapamycin (mTOR), a central regulator of cell metabolism, has
been shown to control T cell memory formation (Araki et al.,
2009).
Metabolic fitness and T cell survival are particularly crucial in
anti-tumor responses because nutrients are often scarce in the
tumor microenvironment leading to T cell dysfunction (Chang
et al., 2015; Ho et al., 2015), stress, and apoptosis (Alves et al.,
2006; Maciver et al., 2008; Siska and Rathmell, 2015). Depletion
of glucose may decrease production of interferon (IFN)-g (Chang
et al., 2013) and modulate the differentiation of regulatory T cells
(De Rosa et al., 2015). In addition, degradation of L-arginine by
myeloid-derived suppressor cells leads to reduced expression
of the CD3z chain, resulting in impaired T cell responsiveness
(Bronte and Zanovello, 2005; Rodriguez et al., 2007). L-arginine
is a versatile amino acid that serves as a building block for protein
synthesis and as a precursor for multiple metabolites,
including, polyamines, and nitric oxide (NO) that have strong
immunomodulatory properties (Grohmann and Bronte, 2010).
In this study, we took advantage of recent developments
in mass spectrometry (Bensimon et al., 2012; Meissner and
Mann, 2014; Zamboni et al., 2015) to obtain dynamic proteome
and metabolome profiles of human primary naive T cells
following activation and found several changes in metabolic
pathways. In particular, we found that L-arginine controls
Cell 167, 829–842, October 20, 2016 ª 2016 The Author(s). Published by Elsevier Inc. 829
This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/).
glycolysis and mitochondrial activity and enhances T cell survival
by interaction with transcriptional regulators. Moreover, L-arginine
enhanced the generation of central memory-like T (Tcm)
cells with enhanced anti-tumor activity in a mouse model.
RESULTS
Proteomic and Metabolomic Changes following
Activation of Human Naive CD4+
T Cells
To investigate the metabolic adaptations underlying T cell activation,
we analyzed the cellular proteome and metabolome of
human primary naive T cells using high-resolution mass spectrometry.
Naive CD45RA+
CCR7+
CD4+
T cells were sorted up
to >98% purity from blood of healthy donors (Figure S1A) and
either analyzed immediately after sorting or at different time
points following activation with antibodies to CD3 and CD28.
After cell lysis, proteins were digested and analyzed by liquid
chromatography-coupled mass spectrometry (LC-MS) (Meissner
and Mann, 2014; Nagaraj et al., 2011). In parallel, polar
metabolites were extracted from cells at each time point and
analyzed by non-targeted flow-injection metabolomics, a semiquantitative
method that allows rapid and deep profiling of metabolites,
with the limitations that isobaric compounds cannot
be discriminated and of possible in-source degradation (Fuhrer
et al., 2011) (Figure 1A).
We identified a total of 9,718 proteins, quantified the abundance
of 7,816 at each time point, and estimated their absolute
A
B C
Figure 1. Metabolic and Proteomic
Profiling Reveals Distinct Changes in
L-Arginine Metabolism in Activated Human
T Cells
(A) Schematic view of the experimental approach.
(B) Comparison of protein abundances between
72-hr-activated (CD3 + CD28 antibodies)
and freshly isolated non-activated human
naive CD4+
T cells. Closed circles indicate
proteins that changed significantly (FDR = 0.05,
S0 = 1). Colored dots are enzymes of the arginine
and proline metabolism that changed
significantly.
(C) Comparison of metabolite abundances in
72 hr-activated and freshly isolated non-activated
human naive CD4+
T cells. Closed circles indicate
metabolites that changed significantly
(jLog2 fcj > 1, p < 0.01). Colored dots are metabolites
of the arginine and proline metabolism
that changed significantly. Similar changes were
observed when 72 hr-activated CD4+
T cells
were compared with naive CD4+
T cells cultured
overnight in the absence of TCR stimulation.
See also Figure S1 and Tables S1, S2, and S3.
copy numbers. Expression profiles of
characteristic T cell proteins were in
agreement with the literature and copy
numbers of stable protein complexes
had correct ratios (Figures S1B–S1G;
Table S1). Non-targeted metabolomics
led to the identification of 429 distinct
ion species, which were putatively mapped to human metabolites
(Table S2).
A comparative analysis of the proteome and metabolome
of 72 hr activated and non-activated naive T cells identified
2,824 proteins whose relative expression changed significantly
(Welch-test, false discovery rate [FDR] = 0.05, S0 = 1), reflecting
the fundamental morphological and functional alterations that
T cells undergo upon activation (Figure 1B; Table S3). Upregulated
proteins were enriched in enzymes of several metabolic
pathways, including nucleotide synthesis, folate-mediated onecarbon
metabolism, as well as arginine and proline metabolism.
Out of 429 metabolites, 49 increased significantly (Log2 fold
change [fc] > 1; p < 0.01), but only 14 were less abundant in activated
T cells, of which three, arginine, ornithine, and N-acetylornithine,
belonged to the same metabolic pathway (Figure 1C).
Collectively, these data provide a comprehensive resource on
the dynamics occurring in the proteome and metabolome of
activated human primary naive CD4+
T cells.
Intracellular L-Arginine Is Rapidly Metabolized in
Activated T Cells
Based on the data obtained, we inspected the changes in the
arginine metabolism more closely. The decrease in intracellular
arginine occurred abruptly between 24 and 48 hr after T cell activation
(Figure 2A). This finding was surprising in view of the high
concentration of L-arginine in the medium (1 mM) and of the high
uptake rate of 3
H-L-arginine in activated T cells, which exceeded
830 Cell 167, 829–842, October 20, 2016
the requirement for protein synthesis by more than 2-fold (Figures
2C and 2B).
To gain insights into the metabolic fate of L-arginine, we
analyzed the activation-induced changes in metabolites and
proteins of the surrounding metabolic network (Figure 2D). While
metabolites around the urea cycle were decreased, the arginine
transporter cationic amino acid transporter 1 (CAT-1) and the
A
B
D E
C Figure 2. L-Arginine Is Rapidly Metabolized
upon Activation
(A) Intracellular abundance of L-arginine in nonactivated
(non-act) and activated naive CD4+
T cells (CD3 + CD28 antibodies). Boxplot, n = 30
from three donors, each in a different color.
(B) Kinetics of 3
H-L-arginine uptake during a
15-min pulse. Box plot, n = 5 from three donors.
(C) Uptake, proteome incorporation and intracellular
abundance of the indicated amino acids.
Barplot (left): 5 3 104
cells were activated for
4 days and consumption of amino acids from medium
was analyzed. Essential amino acids are in
gray; n = 4 from four donors, error bars represent
SEM. Barplot (center): proteome incorporation of
amino acids estimated from the copy numbers of
each protein. Heat map (right): intracellular amino
acid abundance relative to naive T cells over time
as determined by mass spectrometry (MS) n = 30
from three donors. Leucine and isoleucine could
not be distinguished as they have the same mass.
(D) Changes in the abundance of metabolites and
proteins of the arginine and proline metabolism
between non-activated and 72 hr-activated CD4+
T cells. Log2 fold changes of proteins and metabolites
are color-coded. Significant changes are in
bold (FDR = 0.05, S0 = 1 for proteins; and p < 0.05
[two-tailed unpaired Student’s t test], jLog2 fcj > 1
for metabolites). Black dots are metabolites that
were not detected by MS. Only enzymes that were
detected by MS are shown.
(E) Metabolic tracing of L-arginine. Ninety-six houractivated
T cells were pulsed with 13
C6-L-arginine
and the metabolic fate was analyzed by LC-MS/
MS at different time points. AFL, apparent fractional
labeling; n = 4 from two donors. 13
C Citrulline
was not detected. Error bars represent SEM.
For (A) and (B), upper whisker = min(max(x), Q_3 +
1.5 * IQR) and lower whisker = max(min(x), Q_1 –
1.5 * IQR).
enzymes arginase 2 (ARG2), ornithine
aminotransferase (OAT), and spermidine
synthase (SRM), which are required for
the conversion of L-arginine into ornithine,
L-proline, and spermidine, respectively,
were upregulated. These findings suggest
that L-arginine was rapidly converted into
downstream metabolites. Indeed, 13
C-Larginine
tracing experiments showed an
immediate and strong accumulation of
13
C in ornithine, putrescine, agmatine,
and, to a lower extent, in spermidine
and proline (Figure 2E). Addition of the
arginase inhibitor norNOHA did not affect the conversion of
L-arginine into agmatine, but markedly reduced the conversion
into ornithine, putrescine, spermidine, and proline (Figure 2E).
This indicated that in T cells L-arginine is mainly catabolized
through arginase, likely through mitochondrial ARG2, because
the cytosolic enzyme arginase 1 (ARG1) was not detected in
T cells.
Cell 167, 829–842, October 20, 2016 831
Fructose 1,6-bis-P
Glucose
3-P-Glycerate
Pyruvate
Glucose-6-P
ALDOC
GPI
2-P-Glycerate
ENO2
HK2
PKM
Glucose
SLC2A3 SLC2A1
Glucose
FBP1
Fructose-6-P
PFKP
PFKL
ENO1
PFKM
HK1
ALDOAGlycer-
aldehyde-3-P
Dihydroxy-
acetone-P
1,3-Bisphospho-
glycerate
GAPDH
TPI1
PGK1
Lactate
LDHA
ENO3
P-enolpyruvate
PGAM1
PROTEINSMETABOLITES
2
1
0
-1
-2
1.5
1
0.5
0
-0.5
-1
-1.5
Serine
PHGDH
PSPH
P-Serine
0.0
0.5
1.0
1.5
2.0
2.5
RelativeOCR
E
0
1
2
3
4
5
6
RelativeSRC
Glutamate
C
trlL-Arg
C
trlL-Arg
0 50 100 150
0
200
400
600
FCCPOligomycin Antimycin
Control
L-arginine
OCR[pMol/min]
D
SRCSRC
TCA
CYCLE
MDH2
B
Time (min)
0
1
2
3
4
CtrlL-Arg
Gluc.consum.[pmol/cell]
C F
Citrate
LDHB
PC PCK2
cis-
Aconitate
Isocitrate
α-Ketoglutarate
Succinate
Fumarate
Malate
PSAT1
ACO2
ACO2
IDH3A
IDH3B IDH3G
OGDH
SDHC
SDHB SDHD
SDHA
FH
CS
na
12h
24h
48h
72h
96h
120h
3h
na
12h
24h
48h
72h
96h
3h
L-Ornithine
L-Arginine
N-Acetyl-L-citrulline
L-2-Aminoglutaramic acid
L-Arginosuccinic acid
Serine
3-Mercaptopyruvate
Phenylalanine
Tyrosine
Leucine
4-Oxo-L-proline
2,4-Dioxotetrahydropyrimidine
L-Alanine
5-Amino-4-oxovaleric acid
2-Aminosuccinamic acid
L-Aspartate
Adenosine 5'-triphosphate
Uridine triphosphate
L-4-Aspartyl phosphate
2-Pyrrolidinecarboxylic acid
cis-Aconitic acid
Adenosine diphosphate ribose
5'-IMP
Ribose 5-phosphate
GABA
Coenzyme R
Glycerol-3-phosphate
Uridine 5'-diphosphate
Cytidine diphosphate
2'-Deoxycytidine 5'-diphosphate
2-Hydroxytricarballylic acid
(R)-Pantothenate
Dexfosfoserine
Glutamate
Cytidine
Glycerophosphoethanolamine
Glucose
UDP-N-acetylglucosamine
Clobenpropit
UDP-alpha-D-glucose
Reduced glutathione
Cytidylic acid
Guanylic acid
Adenosine 5'-phosphate
5'Uridylic acid
N-Formyl-GAR
Aminoethylsulfonic acid
O-Succinylhomoserine
N-Carbamoyl-L-aspartate
N2-citryl-N6-acetyl-N6-hydroxylysine
Malic acid
Uridine
N-Acetyl-L-aspartic acid
2-O-(alpha-Mannopyranosyl)-D-glycerate
1,3-Dihydroxypropan-2-one
L-OrnL-Arg
120h
0 2-2
Log2 fold change
A
Log2foldchange
**** **** ****
Oxalo
acetate
Acetyl-CoA
(legend on next page)
832 Cell 167, 829–842, October 20, 2016
Collectively, these data show that L-arginine is avidly taken up
by activated T cells in amounts exceeding the requirements for
protein synthesis and can be rapidly converted by metabolic
enzymes into downstream metabolites.
Elevated L-Arginine Levels Regulate Several Metabolic
Pathways
Because activated T cells showed a drop in their intracellular
arginine concentration—while all other amino acids either remained
steady or increased—we assessed the consequences
of increasing L-arginine availability on metabolism. We first performed
a kinetic metabolome analysis of naive T cells activated
in standard medium (containing 1 mM L-arginine) or in medium in
which the concentration of L-arginine was increased 4-fold.
Intracellular arginine and ornithine levels were increased 1.5- to
2.5-fold at all time points in T cells activated in L-arginine-supplemented
medium as compared to controls (Figure 3A), while
nitric oxide, which is generated from L-arginine by nitric oxide
synthase (NOS), did not increase (Figure S2A). Notably, at late
time points after activation (72–120 hr), several other metabolites,
including intermediates of the urea cycle, nucleotides,
sugar derivatives, and amino acids were increased (Figure 3A).
In contrast, an increased availability of L-arginine’s downstream
metabolites L-ornithine or L-citrulline (added to the culture
medium at the same concentration as L-arginine) only had minor
effects on metabolism (Figures 3A and S2B). These findings suggest
that L-arginine directly regulates several metabolic pathways
in activated T cells.
A proteome analysis showed that the expression of 202 out of
7,243 proteins was significantly different in T cells activated in
L-arginine-supplemented medium (Table S4, ANOVA, FDR =
0.005, S0 = 5, jLog2 fcj > 1), indicating that T cells were reprogrammed
under the influence of increased intracellular L-arginine
levels. In particular, PC, PCK2, and FBP1, which promote gluconeogenesis,
were increased, while glucose transporters and
glycolytic enzymes were decreased (Figure 3B). Indeed, these
T cells consumed less glucose (Figure 3C), indicating that the
glycolytic flux was diminished by L-arginine supplementation.
Moreover, the serine biosynthesis pathway that branches from
glycolysis and several intermediates of the mitochondrial tricarboxylic
acid (TCA) cycle were upregulated (Figure 3B). Consistent
with the fact that the TCA cycle fuels OXPHOS, L-arginine
supplementation increased oxygen consumption 1.7-fold and
augmented the mitochondrial spare respiratory capacity (SRC)
(Figures 3D–3F). Collectively, these data demonstrate that an
increase in intracellular L-arginine levels skewed the metabolism
in activated T cells from glycolysis toward mitochondrial
OXPHOS.
L-Arginine Influences Human T Cell Proliferation,
Differentiation, and Survival
Naive T cells start to divide after an initial period of growth that
lasts 24–40 hr. Subsequently, they divide rapidly and differentiate
into effector T cells that produce inflammatory cytokines,
such as IFN-g, and into memory T cells that survive through homeostatic
mechanisms (Schluns and Lefranc¸ ois, 2003; Surh
et al., 2006). We therefore asked whether elevated intracellular
L-arginine concentrations affect the fate of activated T cells.
Naive CD4+
T cells activated in L-arginine-supplemented medium
showed a slightly delayed onset of proliferation, but once
proliferation started, doubling rates were comparable to controls
(Figures S3A and S3B). The onset of proliferation was not
affected by D-arginine or by addition of L-lysine (a competitive
inhibitor of L-arginine uptake; Figure S3A) to L-arginine-supplemented
cultures (Figure S3C). Importantly, T cells activated in
L-arginine-supplemented medium secreted much less IFN-g
than T cells cultured in control medium (Figure 4A). However,
when these cells were re-activated, they were able to secrete
IFN-g in comparable amounts (Figure 4B), indicating that
T cells primed in the presence of high L-arginine concentrations
retained the capacity to differentiate into Th1 effector cells upon
secondary stimulation. Because low production of cytokines is
characteristic of CCR7+
lymph node-homing Tcm cells (Sallusto
et al., 1999), we analyzed the expression of CCR7 on day 10 after
activation and found a higher fraction of proliferating CCR7+
T cells in L-arginine supplemented cultures than in control cultures
(Figure 4C). Collectively, these data indicate that increased
intracellular L-arginine levels limit T cell differentiation and maintain
cells in a Tcm-like state.
To test whether L-arginine affects T cell survival, we activated
human naive CD4+
and CD8+
T cells, expanded them in the presence
of IL-2 or IL-15, and measured their viability upon cytokine
withdrawal. Strikingly, L-arginine supplementation significantly
increased the survival of activated CD4+
and CD8+
T cells
when cultured in the absence of exogenous cytokines (Figures
4D and 4E). L-arginine was most effective when added during
the first 48 hr following T cell activation (Figure 4F). Conversely,
L-lysine or D-arginine, which both inhibit L-arginine uptake
Figure 3. L-Arginine Globally Influences Metabolism of Activated Human T Cells
(A) Human naive CD4+
T cells were activated in control medium (Ctrl) or in medium supplemented with 3 mM L-arginine (L-Arg) or 3 mM L-ornithine (L-Orn) and
harvested at different time points. The heat map shows the difference between the abundance of metabolites in T cells cultured in L-Arg or L-Orn-medium and
controls. Shown are only metabolites with a Log2 fc > 1 and an adjusted p value of < 0.05; n = 12 from two donors.
(B) Differential analysis of the glycolytic pathway between naive CD4+
T cells cultured in L-Arg medium or Ctrl medium, 96 hr after activation. Log2 fold changes
of proteins and metabolites are color-coded. Proteins or metabolites whose abundance changed significantly are in bold (for proteins FDR = 0.005, S0 = 5,
jLog2 fcj > 1 and for metabolites p < 0.05 (Student’s t test), jLog2 fcj > 1). 3-P-glycerate and 2-P-glycerate could not be distinguished as they have the same mass.
(C) Seventy-two hour-activated T cells were plated in fresh medium and glucose consumption was determined enzymatically after 24 hr; n = 9 from three donors.
Error bars represent SEM.
(D) Seahorse experiment performed with activated (96 hr) T cells from one donor. Oligomycin was injected after 56 min, FCCP after 96 min, and antimycin (to
inhibit the respiratory chain) after 136 min. Data are representative of five independent experiments with different donors; n = 4. Error bars represent SEM.
(E and F) Relative oxygen consumption rate (OCR) (E) and relative spare respiratory capacity (SRC) (F) of activated (96 hr) T cells; n = 12 from three donors. ****p <
0.0001 (Student’s t test). Error bars represent SEM.
See also Figure S2 and Table S4.
Cell 167, 829–842, October 20, 2016 833
2 4 6 8 10
0
20
40
60
80
100
LivingCD4+Tcells[%]
Days after IL-2 withdrawal
-20
-10
0
10
20
30
40
F
**** ****
-20
0
20
40
60
Ctrl. 0 24 48 72 96
Addition of L-Arg [hours]
I K
Control
nor-
NOHA
BEC
CTV
E
-5
0
5
10
15 ** *J
G
C
trl
L-Arg.H
C
l
L-Lys
L-Arg
+
L-Lys
D
-Arg
L-O
rnL-C
itL-ProU
rea
C
reatine
Agm
atineSperm
idine
****
*********** *** n.s. n.s. n.s. n.s. n.s.
Putrescine
****
-40
-20
0
20
40
15
10
5
0
IFN-γ[fg/Th1cell]
C
trlL-Arg
A
0
10
20
30
40
50
IFN-γ[fg/Th1cell]
C
trlL-Arg
B C
C
trlL-Arg
CTVlowCD4+CCR7+Tcells[%]
90
95
D
Ctrl
L-Arg
-20
0
20
40
60
80
**** ****
Differenceoflivingcells[%]
L-Arg
Ctrl
L-Arg
Ctrl
CD4+ CD8+
Diff.oflivingCD4+Tcells[%]
CtrlnorNO
HA
BEC
CtrlnorNO
HA
BEC
Diff.oflivingCD4+Tcells[%]
Diff.oflivingCD4+Tcells[%]
Diff.oflivingCD4+Tcells[%]
**** n.s. ****
C
trlL-ArgD
iM
eArg
D
iM
eArg+L-ArgL-N
AM
E
L-N
AM
E
+L-Arg
-20
0
20
40
60H
Diff.oflivingCD4+Tcells[%]
Figure 4. L-Arginine Limits Human T Cell
Differentiation and Endows Cells with a
High Survival Capacity In Vitro
(A and B) Human naive CD4+
T cells were activated
in L-Arg medium or Ctrl medium in the presence of
10 ng/mL IL-12. IFN-g was quantified in culture
supernatants after 5 days (A) or after re-activation
for 5 hr with PMA/ionomycin (B); n = 9 from three
donors.
(C) Naive CD4+
T cells were labeled with CellTrace
Violet (CTV) and activated in L-Arg medium or
Ctrl medium. On day 10, proliferating CTVlo
T cells
were stained with an antibody to CCR7 and
analyzed by flow cytometry; n = 15 from three
donors.
(D) Naive CD4+
T cells were activated for 5 days in
L-Arg or Ctrl medium in the presence of exogenous
IL-2, washed extensively, and cultured in Ctrl
medium in the absence of IL-2. Shown is the percentage
of living T cells as determined by Annexin
V staining at different time points after IL-2 withdrawal.
One representative experiment out of
three performed.
(E) Same experiment as in (D). Shown is the difference
of living activated CD4+
and CD8+
T cells
5 days after withdrawal of IL-2; n = 46, from 16
donors (CD4+
T cells); n = 13, from four donors
(CD8+
T cells).
(F) Difference of living activated CD4+
T cells
5 days after IL-2 withdrawal. Naive CD4+
T cells
were activated and L-Arg (3 mM) was added to the
culture medium at the indicated time points; n = 12
from four donors.
(G) Difference of living activated CD4+
T cells
5 days after IL-2 withdrawal. Naive CD4+
T cells
were activated in Ctrl medium or medium supplemented
with the indicated metabolites (3 mM,
except for spermidine 0.1 mM). Ctrl, n = 21; D-Arg,
n = 9; L-lysine, n = 18; L-Arg-HCl, n = 10; L-Arg +
L-Lys, n = 12; L-Orn, n = 20; L-Cit, L-Pro, n = 12;
urea, creatine, agmatine, n = 6; putrescine, n = 18;
spermidine, n = 8, from at least three donors.
(H) Difference of living activated CD4+
T cells
5 days after IL-2 withdrawal. Naive CD4+
T cells
were activated in the presence or absence of
nitric oxide synthase inhibitors dimethylarginine
(DiMeArg) or L-NG-nitroarginine methyl ester
(L-NAME), both used at 1 mM. Ctrl and L-Arg,
n = 26; DiMeArg and L-NAME, n = 16; DiMeArg +
L-Arg and L-NAME + L-Arg, n = 12, from at least
three donors.
(I) Difference of living activated CD4+
T cells 5 days
after IL-2 withdrawal. Naive CD4+
T cells were
activated in absence (Ctrl) or presence of
the arginase inhibitors Nu
-Hydroxy-nor-L-arginine
(norNOHA, 300 mM) or S-(2-boronoethyl)-Lcysteine
(BEC, 300 mM); n = 21, from seven
donors.
(J) Same as in (I) but cultures were performed in
medium containing 150 mM L-arginine.
(K) Effect of norNOHA and BEC on proliferation of
CTV-labeled naive T cells measured 72 hr after
activation. *p < 0.05, **p < 0.01, ***p < 0.001,
****p < 0.0001 (Student’s t test).
(A–J) Error bars represent SEM throughout.
See also Figures S3 and S4.
834 Cell 167, 829–842, October 20, 2016
(Figure S3C), decreased T cell survival significantly (Figure 4G),
indicating that reduced availability of intracellular L-arginine
negatively affects T cell survival. L-arginine’s downstream
metabolites ornithine, citrulline, proline, urea, and creatine, as
well as nitric oxide, had no effect, while agmatine, putrescine,
or spermidine decreased T cell survival (Figure 4G and 4H).
L-arginine-HCl enhanced T cell survival to a similar extent
than free base L-arginine, ruling out a possible influence of
pH. The increased T cell survival induced by elevated intracellular
L-arginine concentration was independent of mTOR
signaling (Araki et al., 2009), based on the finding that L-arginine
supplementation did not change phosphorylation levels
of two targets of mTOR (p70 S6K1 and 4E-BP) and inhibition
of mTOR by rapamycin, although enhancing T cell survival,
affected metabolism in an entirely different way than L-arginine
(Figures S4A–S4D).
To further support the notion that L-arginine regulates T cell
survival, we inhibited arginase (that converts L-arginine into
L-ornithine) with norNOHA or BEC, which increase intracellular
L-arginine levels (Monticelli et al., 2016). Inhibition of arginase
significantly increased the survival capacity of activated CD4+
T cells, even in medium containing physiological levels of L-arginine
(150 mM) (Figures 4I and 4J). Inhibition of arginase did not
affect proliferation (Figure 4K), indicating that polyamines can
be synthesized from other sources than L-arginine, i.e., from
L-glutamate (Wang et al., 2011), a finding that is consistent
with the experiments showing that polyamine synthesis only
partially depends on L-arginine (Figure 2E).
Collectively, these data indicate that elevated intracellular
L-arginine levels directly induced metabolic changes and
longevity of human CD4+
and CD8+
T cells, independently of
mTOR signaling or downstream metabolites.
L-Arginine Influences Mouse T Cell Survival In Vivo
To address the impact of changes in intracellular L-arginine
levels in vivo, we performed experiments in mice. Naive TCR
transgenic CD4+
T cells specific for a hemagglutinin peptide
(HA110–119) were adoptively transferred into BALB/c mice that
received daily supplements of L-arginine (1.5 mg/g body weight)
or PBS as a control. This amount of arginine doubled the daily
dietary intake present in chow. Mice were immunized with
HA110–119 in CFA and the amount of transgenic T cells in draining
lymph nodes was measured 15 days later. Three times more
CD44hi
CD4+
TCR transgenic T cells were recovered in mice
fed with L-arginine compared to control mice (Figure 5A). In
control experiments, we found that 30 min after oral administration,
L-arginine levels in the serum increased from $160 mM
to 700 mM (Figure S5A) and intracellular L-arginine levels of
CD44hi
-activated T cells increased $2-fold (Figure S5B).
We then analyzed CD4+
and CD8+
T cells from Arg2-deficient
mice. When compared to wild-type T cells, Arg2–/–
T cells
showed 20% higher baseline intracellular L-arginine levels (Figure
S5C) and when stimulated in vitro with antibodies to CD3
and CD28, they survived significantly longer than wild-type
T cells after IL-2 withdrawal (Figures 5B and 5C). Moreover, activation
in the presence of the arginase inhibitor norNOHA, while
increasing the survival of wild-type T cells, did not affect survival
of Arg2–/–
T cells (Figures 5B and 5C), indicating that in mouse
T cells L-arginine degradation occurred mainly through ARG2.
Finally, equal numbers of congenically marked wild-type and
Arg2–/–
CD8+
T cells were co-transferred into wild-type mice
that were immunized with the ovalbumin-peptide SIINFEKL
(OVA257–264) in CFA. Fifteen days after immunization, the number
of MHC-I H-2Kb
haplotype (Kb)-restricted OVA257–264-specific
CD44hi
CD8+
T cells was measured in lymph nodes by multimer
0
2
4
6
8
CD90.1+CD4+CD44hiTcells(x10-4)
A ***
W
t
W
tnorN
O
H
A
-10
0
10
20
Diff.oflivingCD4+Tcells[%]
**** ******B C
n.s.
-10
0
10
20
Diff.oflivingCD8+Tcells[%]
W
t
Arg2-/-
0
1
2
3
4D**** *****
n.s.
*
PBS-fedL-Arg-fed
H2Kb/OVA+CD8+CD44hiTcells(x10-3)
Arg2-/-
norN
O
H
A
W
t
W
tnorN
O
H
AArg2-/-
Arg2-/-
norN
O
H
A
Arg2-/Figure
5. Increased Intracellular L-Arginine
Levels Endow Mouse T Cells with a High
Survival Capacity In Vitro and In Vivo
(A) BALB/c CD90.1+
CD4+
TCR transgenic T cells
specific for the influenza HA110–119 peptide were
adoptively transferred into CD90.2+
host mice that
were then immunized subcutaneously (s.c.) with
HA110–119 in complete Freund’s adjuvant (CFA).
Mice were fed with L-arginine-HCl (1.5 mg/g body
weight) or PBS, administrated daily starting 1 day
before immunization. Fifteen days later, the
amount of CD44hi
CD90.1+
CD4+
TCR transgenic
T cells in draining lymph nodes was measured by
fluorescence-activated cell sorting (FACS) analysis;
n = 9 from two independent experiments.
(B and C) In vitro T cell survival experiment with
C57BL/6 wild-type (WT) or Arg2–/–
T cells. Naive
CD62Lhi
CD44lo
CD4+
T cells and CD8+
T cells
were activated for 4 days in L-Arg or Ctrl medium
in the absence or presence of the arginase inhibitor norNOHA (500 mM). On day 2 exogenous IL-2 was added to the cultures, on day 4 cells were washed
extensively and cultured in medium without IL-2. Shown is the difference in the percentage of living CD4+
(B) and CD8+
(C) T cells relative to WT T cells as
determined by Annexin V staining 2 days after IL-2 withdrawal. WT, n = 6-19; WT norNOHA, n = 6–8; Arg2–/–
, n = 4–6; Arg2–/–
norNOHA, n = 4.
(D) Equal numbers of CD45.1+
WT and CD45.2+
CD90.2+
Arg2–/–
naive CD8+
T cells were transferred into CD45.2+
CD90.1+
host mice. Mice were immunized with
the OVA257–264 peptide in CFA. Fifteen days after immunization, the amount of OVA257–264-specific CD44hi
CD8+
T cells was measured in draining lymph nodes by
flow cytometry using OVA257–264/H-2Kb multimers; n = 4. One representative experiment out of two performed. *p < 0.05, **p < 0.01, ***p < 0.001, ****p < 0.0001
(Student’s t test).
Error bars represent SEM throughout.
See also Figure S5.
Cell 167, 829–842, October 20, 2016 835
ACTR2
B2M
BAZ1B
CAP1MTPN
PTPN6
TSN
XRCC6
APOPTOSIS
DNAREPAIR
CYTOSKELETON
RIBOSOME
SPLICING
RPL4
RPL6
RPS10
RPS11
RPS25
RPS3A
ACIN1
DDX17
DDX54
PSIP1
SSB
WIBG
Denature
&Trypsin
half-tryptic tryptic
Proteinase K
Metabolite
A B
C
trlC
as9
C
trlBAZ1B-KOPSIP1-KOPTPN
6-KO
C
TSN
-KOB2M
-KO
C
as9
C
trl
Differenceoflivingcells[%]
Differenceoflivingcells[%]
D* n.s.**** ***
0
20
40
60
80
100
MHC-I
Ctrl
B2M-KO
Percentofmax
-20
0
20
40
60
n.s.**
Tub
TSN
1 2 3 4 5CC
PTPN6
Tub
1 2 3 4 5 6 7C CBAZ1B
*
1 2 3 4 5 6CC
PSIP1
Tub
1 2 CCF G H
I J
n.s. n.s. n.s.
Totallivingcells[%]
E
-20
0
20
40
60
*
0
20
40
60
80
100
C
trlC
as9
C
trlBAZ1B-KOPSIP1-KO
TSN
-KO
Figure 6. BAZ1B, PSIP1, and TSN Mediate the L-Arginine-Dependent Reprogramming of T Cells toward Increased Survival Capacity
(A) Scheme of the limited proteolysis workflow.
(B) Proteins that experience a structural change in response to 1 mM L-arginine but not to 1 mM D-arginine or L-ornithine. Transcriptional regulators are in orange,
proteins are grouped according to their functions. Known interactions are indicated based on http://string-db.org/ and http://www.genemania.org/.
(C) Survival experiment with human CD4+
T cell clones devoid of the indicated proteins. Control (Ctrl), n = 39; Cas9-transduced control (Cas9 Ctrl),
n = 45; BAZ1B-KO, PSIP1-KO, and PTPN6-KO, n = 46, n = 9, and n = 29, respectively. Each T cell clone was analyzed in triplicate. Bars represent the
mean ± SEM.
(D) Same as in (C). Cas9 Ctrl, n = 20; TSN-KO and B2M-KO, n = 23 and n = 3, respectively.
(E) Percentage of living cells after IL-2 withdrawal of T cells cultured in Ctrl medium. Ctrl, n = 39; Cas9 Ctrl, n = 45; BAZ1B-KO, PSIP1-KO, and TSN-KO, n = 46,
n = 9, and n = 29, respectively.
(legend continued on next page)
836 Cell 167, 829–842, October 20, 2016
staining. As shown in Figure 5D, OVA-specific Arg2–/–
T cells
were more numerous than OVA-specific wild-type T cells. Taken
together, these findings provide evidence that intracellular
L-arginine concentrations, which can be elevated by dietary
supplementation, can increase the survival capacity of antigenactivated
T cells in vivo.
Global Analysis of Structural Changes Identifies
Putative L-Arginine Sensors
To elucidate the mechanism by which L-arginine promotes
T cell survival, we first examined the list of differentially expressed
proteins (Table S4) and found among the top hits Sirtuin-1,
a histone deacetylase, which is known to increase the
lifespan of different organisms (Tissenbaum and Guarente,
2001). However, a role for Sirtuin-1 was excluded based on
the findings that human naive T cells activated in the presence
of the Sirtuin-1 inhibitor Ex-527 and Sirtuin-1-deficient T cells
generated using the CRISPR/Cas9 technology displayed a
L-arginine-mediated increase in survival comparable to controls
(Figure S6).
Given that L-arginine directly promotes T cell survival, we set
out to identify putative protein interactors that may be modified
by binding of L-arginine and initiate the pro-survival program.
For this, we probed structural changes across the T cell proteome
that occur in response to L-arginine following a recently
developed workflow (Feng et al., 2014) (Figure 6A). T cells
were homogenized and incubated in the absence or presence
of 1 mM L-arginine, D-arginine, or L-ornithine. Subsequently,
samples were subjected to limited proteolysis (LiP) with proteinase
K, which preferentially cleaves flexible regions of a protein.
After denaturation and trypsin digestion, peptide mixtures were
analyzed by LC-MS. Because trypsin cleaves polypeptides
specifically after lysine or arginine, cleavages after other amino
acids were introduced by proteinase K, leading to half-tryptic
peptides. Significant changes in the abundances of half-tryptic
peptides (fc > 5, p < 0.05, > 2 peptides per protein) were used
as readout for structural changes induced by the addition of
metabolites.
Because L-arginine, but not D-arginine or L-ornithine, promoted
T cell survival, we searched for proteins that were exclusively
affected by L-arginine and were cleaved by proteinase K
at identical sites in all samples from six donors. Out of 5,856
identified proteins, only 20 candidates fulfilled these stringent
criteria (Figure 6B). These proteins differed widely in molecular
weight and abundance (Table S5), excluding a bias toward
large or abundant proteins. Most candidates were assigned
to four functional groups: mRNA splicing, DNA repair, regulation
of the cytoskeleton, and the ribosome, while seven were
transcriptional regulators (in orange in Figure 6B). Thus, our
global approach revealed several proteins with various functions
that structurally respond to elevated intracellular L-arginine
levels.
BAZ1B, PSIP1, and TSN Are Required for the L-ArginineMediated
Effect on T Cell Survival
To test whether selected candidates identified through the
structural analysis were involved in the L-arginine-mediated survival
benefit, we generated gene knockout human T cell clones
using the CRISPR/Cas9 system that were screened for loss of
the corresponding protein by western blot or flow cytometry.
Knockout of PTPN6 (Shp-1) or B2M did not alter the effect of
L-arginine on T cell survival (Figures 6C and 6D), while no viable
clones were obtained after knockout of XRCC6, ACIN1, and
SSB (not shown). Strikingly, knockout of the transcriptional regulators
BAZ1B, PSIP1, and TSN significantly reduced L-arginine’s
beneficial effect on T cell survival (Figures 6C, 6D, and
6F–6J). Importantly, when cultured in control medium prior to
the IL-2 withdrawal, T cell clones lacking these transcriptional
regulators proliferated and survived like controls (Figure 6E),
indicating that their viability was unaffected but they were unable
to sense increased L-arginine levels and to induce the
pro-survival program. Taken together, these data provide evidence
that BAZ1B, PSIP1, and TSN interact with L-arginine
and play a role in the reprograming of T cells toward increased
survival capacity.
L-Arginine Improves Anti-tumor T Cell Response In Vivo
Because L-arginine increased the survival capacity of human
and mouse T cells and favored the formation of Tcm-like cells
that have been shown to be superior than effector memory
T cells (Tem) in eradicating tumors in mouse models (Klebanoff
et al., 2005), we reasoned that increased intracellular L-arginine
levels might positively affect anti-tumor T cell responses in vivo.
We stimulated naive TCR transgenic CD8+
OT-I T cells specific
for the OVA257–264 peptide in control or L-arginine-supplemented
medium for 4 days and measured their survival in vitro
following IL-2 withdrawal and in vivo after adoptive transfer
into lymphopenic Cd3e–/–
mice. Consistent with our previous
data, L-arginine endowed OT-I T cells with a higher survival capacity
both in vitro and in vivo (Figures 7A and 7B). Moreover,
these T cells maintained a Tcm-like state and secreted less
IFN-g than controls after in vitro priming but upon reactivation,
they produced even more IFN-g than controls (Figures 7C–
7E). Remarkably, when adoptively transferred into wild-type
mice bearing B16 melanoma tumors expressing the OVA antigen,
L-arginine-treated OT-I T cells mounted a superior antitumor
response, as measured by the reduction of tumor size
and by the increased survival of mice (Figures 7F and 7G). Naive
OT-I T cells primed in vivo by OVA + Alum immunization of
tumor-bearing mice that were fed with L-arginine were also
superior in mediating an anti-tumor response compared to
OT-I T cells primed in mice fed with PBS (Figure 7H). Collectively,
these data demonstrate that elevated L-arginine levels
increased the survival capacity of CD8+
T cells and their antitumor
activity in vivo.
(F–I) Western blots or FACS analysis of T cell clones showing deletion of target proteins. C refers to Cas9 Ctrl clones. Unspecific bands are marked with asterisk.
An antibody to tubulin (Tub) was used as a loading control. B2M-KO was verified by staining cells with an antibody against MHC-I. *p < 0.05, **p < 0.01, ***p <
0.001, ****p < 0.0001 (Student’s t test).
(C–E) Error bars represent SEM throughout.
See also Figure S6 and Table S5.
Cell 167, 829–842, October 20, 2016 837
DISCUSSION
Using proteomics, metabolomics, and functional approaches,
we have shown that increased L-arginine levels can exert pleiotropic
effects on T cell activation, differentiation, and function,
ranging from increased bioenergetics and survival to in vivo
anti-tumor activity.
We found that activated T cells heavily consume L-arginine and
rapidly convert it into downstream metabolites, which lead to a
marked decrease in intracellular levels after activation. Addition
of exogenous L-arginine to the culture medium increased intracellular
levels of free L-arginine and of several other metabolites
and induced a metabolic switch from glycolysis to OXPHOS,
thus counteracting the Warburg effect (Vander Heiden et al.,
2009). While the mechanism by which L-arginine induces the
broad metabolic changes remainselusive, apossible explanation
for the switch toward OXPHOS is that increased L-arginine levels
upregulate the serine biosynthesis pathway, which has been
shown to fuel the TCA cycle and consequently OXPHOS (Possemato
et al., 2011). Suggestive evidence for a link between L-arginine
and the functionality of mitochondria has been provided by
earlier observations; L-arginine improves mitochondrial function
and reduces apoptosis of bronchial epithelial cells after injury
induced by allergic airway inflammation (Mabalirajan et al.,
2010) and had a beneficial effect for the treatment of patients
with a mitochondrial disorder (Koga et al., 2010).
A striking finding is that a 2-fold increase in intracellular L-arginine
concentrations induces human and mouse T cells to acquire
Relativetumorsize
Survival[%]
Days
F
Days
10 20 30 40
0
20
40
60
80
100
G
Ctrl L-Arg
A
1
2
0
3
4
LivingOT-Icells(x10-5)
B
1 3 6 10
Days after injection
Ctrl
L-Arg
5
30
40
50
60
70
80
CTVlowCD44hiCD62L+Tcells[%]
0
20
40
60
80
0
50
100
150
Ctrl L-Arg Ctrl L-Arg Ctrl L-Arg
DC E
IFN-γ[fg/cell]
IFN-γ[fg/cell]
-20
0
20
40
60
7 10 12 14 17 19 21 24 26 28 31 33
0
10
20
30
Relativetumorsize
Days
No T cells L-ArgCtrl
10 20 30 40
0
1
2
3
4
5
No T cells L-ArgCtrl
H
Diff.oflivingCD8+Tcells[%]
*
**
*
*** * **
*
**** ******** **
**
****
***
*
No T cells L-ArgCtrl
Figure 7. CD8+
T Cells with Increased L-Arginine Levels Display Improved Anti-tumor Activity In Vivo
(A) Survival of activated mouse CD8+
OT-I T cells (4 days) after IL-2 withdrawal. Data points represent the difference between the percentage of living T cells from
cultures performed in L-Arg medium or Ctrl medium; n = 11.
(B) CD90.1+
CD45.1/2+
and CD90.1+
CD45.1+
naive CD8+
OT-I T cells were activated for 4 days in Ctrl medium or L-Arg medium, respectively. Equal numbers of
the congenically marked activated OT-I cells were co-transferred into Cd3e–/–
mouse and the number of living T cells was measured in pooled spleen and lymph
nodes at the indicated time points; n = 3 at each time point.
(C) Naive CD8+
OT-I T cells were activated with CD3 + CD28 antibodies in L-Arg medium or Ctrl medium. Five days after activation, the percentage of Tcm-like
cells (CD44hi
, CD62L+
) was measured by flow cytometry; n = 15.
(D) Naive OT-I CD8+
T cells were activated in L-Arg medium or Ctrl medium and IFN-g was quantified in culture supernatants after 5 days; n = 15.
(E) Same as in (D) but T cells were re-activated on day 5 day with PMA/Ionomycin; n = 15.
(F and G) B16.OVA melanoma cells were injected into C57BL/6 mice and tumors were allowed to grow for 10 days. Naive OT-I CD8+
T cells were activated in vitro
in L-Arg medium or Ctrl medium and injected into tumor bearing mice. Tumor burden (F) and survival (G) were assessed over time. Data are representative of three
independent experiments, each performed with seven to nine mice per group.
(H) B16.OVA melanoma cells were injected into C57BL/6 mice and tumors were allowed to grow for 6 days. At day 6, naive CD8+
OT-I T cells were transferred into
tumor bearing mice and at day 7 mice were immunized with OVA peptide. Starting one day before the T cell transfer, PBS or L-arginine (1.5 mg/g body weight) was
orally administered daily; n = 19 from three independent experiments. Bars represent the SEM. *p < 0.05, **p < 0.01, ***p < 0.001, ****p < 0.0001 (Student’s t test).
In (G), *p < 0.05 as determined by log-rank test comparison between curves.
Error bars represent SEM throughout.
838 Cell 167, 829–842, October 20, 2016
a Tcm-like phenotype with high expression of CCR7 and CD62L
and a decreased production of IFN-g. This may be a consequence
of decreased glycolysis induced by L-arginine, as previous
studies demonstrated that glycolytic activity supports IFN-g
mRNA translation (Chang et al., 2013). Although we observed a
delayed onset of cell proliferation, L-arginine-treated T cells progressed
through cell division in a way comparable to controls
and readily proliferated and differentiated to effector cells upon
secondary stimulation. Furthermore, inhibition of arginases in
human T cells or deletion of ARG2 in mouse T cells did not affect
cell proliferation, suggesting that the downstream fate of L-arginine
is less important in T cells than the levels of free L-arginine.
L-arginine may induce some of its pleiotropic effects through
interfering with arginine methyltransferases, which can affect
the functions of various proteins (Geoghegan et al., 2015).
Improved T cell survival is another striking effect induced by
elevated intracellular L-arginine levels. Having excluded a role
for L-arginine-derived nitric oxide and for the metabolic regulator
Sirtuin-1 that has been shown to increase lifespan of lower eukaryotes
(Tissenbaum and Guarente, 2001) and reduce glycolytic
activity (Rodgers et al., 2005), which in T cells may enhance
memory T cell formation and anti-tumor responses (Sukumar
et al., 2013), we considered a direct effect of L-arginine on
protein functions. Metabolite-protein interactions are more
frequent than previously appreciated (Li et al., 2010), and in
some cases, such interactions may have functional consequences.
For instance, cholesterol binds to $250 proteins (Hulce
et al., 2013) and succinate, an intermediate of the TCA cycle, stabilizes
HIF-1a in macrophages, leading to increased secretion of
IL-1b (Tannahill et al., 2013). We took advantage of a novel
method that allows proteome-wide probing of metabolite-protein
interactions without modifying metabolites (Feng et al.,
2014) and identified several proteins that changed their structure
in the presence of L-arginine, which were likely sensors required
to mediate the metabolic and functional response. We provide
evidence that three nuclear proteins (BAZ1B, PSIP1, and TSN)
were required in T cells for mediating L-arginine’s effect on survival.
BAZ1B is a transcriptional regulator containing a PHD
domain that supposedly binds to methylated histones. PSIP1
is a transcriptional co-activator implicated in protection from
apoptosis (Ganapathy et al., 2003). Interestingly, the structural
changes induced by L-arginine affect the PHD domain of
BAZ1B and the AT-hook DNA-binding domain of PSIP1, which
may affect DNA binding and lead to the induction of the pro-survival
program. Finally, TSN, a small DNA and RNA binding protein,
has been implicated in DNA repair, regulation of mRNA
expression, and RNAi (Jaendling and McFarlane, 2010) and
can thus influence the cellular phenotype in various ways. The
conclusion that these three proteins are involved in the pro-survival
effect mediated by L-arginine is based on the analysis of
several different knockout T cell clones. Yet, there was variability
in the response to L-arginine, which may suggest compensatory
mechanisms. This would be consistent with our finding
that several independent proteins can sense L-arginine and
contribute to the improved survival capacity. Future studies are
needed to clarify the mechanism of how L-arginine affects the
structure and functions of the identified sensors in vivo and
how this translates into increased survival.
While in this study we addressed the response to elevated
L-arginine levels, it is well established that T cells also sense
L-arginine depletion, as it may occur in tumor microenvironments
or when myeloid suppressor cells degrade L-arginine
through ARG1 (Bronte and Zanovello, 2005). We have shown
that moderately reduced uptake of L-arginine has a negative
impact on T cell survival without affecting proliferation. However,
when L-arginine was completely depleted from the culture medium,
T cells no longer proliferated (data not shown and Rodriguez
et al., 2007). Lack of L-arginine in T cells can be sensed
by GCN2, leading to an amino acid starvation response (Rodriguez
et al., 2007) and by SLC38A9, leading to inhibition of
mTOR (Rebsamen et al., 2015; Wang et al., 2015), which in
turn inhibits T cell growth and proliferation.
Our findings that T cells with increased L-arginine levels
display improved anti-tumor activity may be due to a combination
of phenotypic changes, including improved survival capacity,
metabolic adaptations, and maintenance of a Tcm-like
phenotype. L-arginine may also impact on other cell types in vivo,
e.g., oral administration of L-arginine to healthy volunteers has
been shown to enhance the numbers and activity of natural killer
cells (Park et al., 1991). Future work is needed to address the
exact mechanism by which L-arginine acts in vivo and favors
memory T cell formation and anti-tumor responses.
Generally, metabolite levels can be influenced without genetic
manipulations, offering the possibility for therapeutic applications.
The beneficial effect of L-arginine on T cell survival and
anti-tumor functionality may be exploited therapeutically, for
instance to improve adoptive T cell therapies. Additionally, our
dataset on the dynamics of the proteome and metabolome during
the T cell response constitute a framework for future studies
addressing the complex interplay between metabolism and
cellular functions.
STAR+METHODS
Detailed methods are provided in the online version of this paper
and include the following:
d KEY RESOURCES TABLE
d CONTACT FOR REAGENT AND RESOURCE SHARING
d EXPERIMENTAL MODEL AND SUBJECT DETAILS
B Human Primary T Cells
B Mice
d METHOD DETAILS
B Isolation of Human T Cells
B Cell Culture
B Metabolomics
B Metabolic Flux Experiments
B Detection of Amino Acids and Polyamines by HILIC
LC-MS/MS
B Sample Preparation for Proteome MS Analysis
B LC-MS/MS for Analysis of Proteome
B Analysis of Proteomics Data
B Limited Proteolysis and Mass Spectrometry
B Quantitative Amino Acid Uptake and Calculation of
Proteome Incorporation
B
3
H-Arginine Uptake Assay
Cell 167, 829–842, October 20, 2016 839
B OCR Measurements
B IL-2 Withdrawal Assay
B Cytokine Analysis
B Glucose Consumption Assay
B Analysis of Phosphorylation Levels of 4E-BP and S6K1
B CRISPR/Cas9-Mediated Gene Disruption
B Isolation and Culturing of Mouse CD8+
T Cells
B Adoptive T Cell Transfers and Survival Experiments
B Tumor Experiments: In Vitro Activation of T Cells
B Tumor Experiments: In Vivo Priming of T Cells
B Experiments with Arg2–/–
Mouse T Cells
B Mouse Experiments with Dietary L-Arginine
d QUANTIFICATION AND STATISTICAL ANALYSIS
B Proteome Data
B Enrichment Analysis
d DATA AND SOFTWARE AVAILABILITY
SUPPLEMENTAL INFORMATION
Supplemental Information includes six figures and six tables and can be found
with this article online at http://dx.doi.org/10.1016/j.cell.2016.09.031.
AUTHOR CONTRIBUTIONS
R.G. conceived the project, designed and performed experiments, analyzed
the data, and wrote the manuscript. T.W. designed and performed experiments
and analyzed the data. J.R., R.G., and F.M. performed the proteomic
experiments and analyzed the data. T.F., M.K., and N.Z. designed and performed
metabolome and flux experiments and analyzed data. C.B. designed
and performed mouse experiments. Y.F. and P.P. designed and performed
limited proteolysis experiments. A.L., F.S., M.M., and N.Z. supervised the
work and edited the manuscript.
ACKNOWLEDGMENTS
We thank Walter Reith, Isabelle Dunand-Sauthier, and Adria-Arnau Marti Lindez
for providing the Arg2–/–
mice, David Jarrossay for cell sorting, Luana Perlini
for help with mouse experiments, Peter Mirtschink and Wilhelm Krek for
providing access to the Seahorse analyzer, and members of the A.L., F.S.,
N.Z., and M.M. laboratories for discussions. This work was supported in
part by the Swiss Vaccine Research Institute, the Swiss National Science
Foundation (grant 149475 to A.L.), and the European Research Council (grant
323183 PREDICT to F.S.). R.G. was supported by a grant from the Swiss
SystemsX.ch initiative, evaluated by the Swiss National Science Foundation.
A.L. is supported by the Helmut Horten Foundation.
Received: February 3, 2016
Revised: March 18, 2016
Accepted: September 19, 2016
Published: October 13, 2016
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STAR+METHODS
KEY RESOURCES TABLE
REAGENT or RESOURCE SOURCE IDENTIFIER
Antibodies
Human CD4-APC (clone 13B8.2) Beckman Coulter Cat#IM2468; RRID: AB_130781
Human CD45RA-PE (clone ALB11) Beckman Coulter Cat#IM1834U
Human CCR7-BV421 (clone G043H7) BioLegend Cat#353208; RRID: AB_11203894
Human CCR7 (clone 15053) R&D Systems Cat#MAB197
Human CD25-FITC (clone B1.49.9) Beckman Coulter Cat#IM0478U; RRID: AB_130985
Human CD8-FITC (clone B9.11) Beckman Coulter Cat#A07756; RRID: AB_1575981
Human CD3 (clone TR66) In house Lanzavecchia and Scheidegger, 1987
Human CD28 (clone CD28.2) BD Biosciences Cat#555725; RRID: AB_396068
Human BAZ1B (WSTF) polyclonal Abcam Cat#AB50850; RRID: AB_870595
Human PSIP1 (LEDGF/p75) polyclonal Bethyl laboratories Cat#A300-848A
Human TSN polyclonal Atlas antibodies/Sigma Cat#HPA059561
Human PTPN6 (SH-PTP1, SHP-1) polyclonal Santa Cruz Cat#sc-287; RRID: AB_2173829
Human MHC-I (HLA-ABC) FITC (clone W6/32) eBiosciences Cat#11-9983-42
Human p70 S6 Kinase Cell Signaling Cat#9202; RRID: AB_331676
Human Phospho-p70 S6 Kinase (Thr389) Cell Signaling Cat#9205; RRID: AB_330944
Human 4E-BP1 Cell Signaling Cat#9644; RRID: AB_2097841
Human Phospho-4EBP1 (Thr37/46) Cell Signaling Cat#2855; RRID: AB_560835
Anti-mouse CD4, Pacific Orange (clone RM4-5) Invitrogen Cat#MCD0430
Anti-mouse CD8a, Pacific Blue (clone 53-6.7) Biolegend Cat#100725; RRID: AB_493425
Anti-mouse/human CD44, APC/Cy7 (clone IM7) Biolegend Cat#103028; RRID: AB_830785
Anti-mouse/human CD44, FITC (clone IM7) Biolegend Cat#103022; RRID: AB_493685
Anti-mouse/human CD44, APC (clone IM7) Biolegend Cat#103012; RRID: AB_312963
Anti-mouse CD62L, PE/Cy7 (clone MEL-14) Biolegend Cat#104418; RRID: AB_313103
Anti-mouse 90.1, APC/Cy7 (clone OX-7) Biolegend Cat#202520; RRID: AB_2303153
LEAF purified anti-mouse CD3ε (clone 145-2C11) Biolegend Cat#100331; RRID: AB_1877073
Purified hamster anti-mouse CD28 (clone37.51) BD Biosciences Cat#553295; RRID: AB_394764
Chemicals, Peptides, and Recombinant Proteins
L-arginine Sigma Cat#A5006
L-arginine monohydrochloride Sigma Cat#A4599
D-arginine Sigma Cat#A2646
L-Arginine-13C6 hydrochloride Sigma Cat#643440
L-[2,3,4-3
H]-arginine-monohydrochloride Perkin Elmer Cat#NET1123001MC
Annexin-V-FITC Biolegend Cat#640906
Cell-Tak BD Biosciences Cat#354240
Oligomycin Sigma Cat#75351
Carbonyl cyanide-4-(trifluoromethoxy)
phenylhydrazone (FCCP)
Sigma Cat#C2920
Antimycin Sigma Cat#A8674
Recombinant human interleukin-2 BD Biosciences Cat#554603
Recombinant human interleukin-12 Biolegend Cat#573002
Human recombinant interleukin-2 (transfected J588L
cell supernatant)
In house N/A
FlowCytomix basic kit eBioscience Cat#BMS8420FF
Flow Cytomix human Th1/Th2/Th9/Th17/Th22 13plex eBioscience Cat#BMS817FF
(Continued on next page)
Cell 167, 829–842.e1–e7, October 20, 2016 e1
CONTACT FOR REAGENT AND RESOURCE SHARING
Further information and requests for reagents may be directed to, and will be fulfilled by the corresponding author Antonio Lanzavecchia
(lanzavecchia@irb.usi.ch).
EXPERIMENTAL MODEL AND SUBJECT DETAILS
Human Primary T Cells
Blood from healthy male or female donors was obtained from the Swiss Blood Donation Center of Basel and Lugano, and used in
compliance with the Federal Office of Public Health (authorization no. A000197/2 to F.S).
Mice
Wild-type (WT) C57BL/6J and BALB/c mice were obtained from Harlan (Italy). Cd3e–/–
C57BL/6 mice, which lack all T cells but exhibit
organized lymphoid organ structures and normal B cell development, have been described previously (Malissen et al., 1995). OT-I
Continued
REAGENT or RESOURCE SOURCE IDENTIFIER
Phorbol 12-myristate 13-acetate (PMA) Sigma Cat#P1585
Ionomycin Sigma Cat#I0634
Rapamycin Sigma Cat#R8781
Proteinase K Sigma Cat#P2308
Critical Commercial Assays
Glucose (GO) Assay Kit Sigma Cat#GAGO20-1KT
Experimental Models: Cell Lines
Human: primary T lymphocytes This paper N/A
Mouse: primary T lymphocytes This paper N/A
HEK293T/17 ATCC Cat#CRL-11268
B16.OVA Matteo Bellone Bellone et al., 2000
Experimental Models: Organisms/Strains
Mouse: C57BL/6: (C57BL/6JOlaHsd) Harlan Cat#57
Mouse: BALB/c: (BALB/cOlaHsd) Harlan Cat#162
Mouse: Cd3e–/–
C57BL/6 Malissen et al., 1995 N/A
Mouse: OT-I: (C57BL/6-Tg(TcraTcrb)1100Mjb/J) The Jackson Laboratory Cat#JAX003831
Mouse: Rag1–/–
: (B6.129S7-Rag1tm1Mom
/J) The Jackson Laboratory Cat#JAX002216
Mouse: Arg2–/–
: C57BL/6 (Arg2tm1Weo
/J) The Jackson Laboratory Cat#JAX020286
Mouse: Hemagglutinin (HA) TCR-transgenic (6.5)
BALB/c
Kirberg et al., 1994 N/A
Recombinant DNA
lentiCRISPR v2 Addgene Cat#52961
psPAX Addgene Cat#12260
pMD2.G Addgene Cat#12259
Sequence-Based Reagents
Short guide RNAs, see Table S6 This paper N/A
Software and Algorithms
MaxQuant Cox and Mann, 2008 http://www.coxdocs.org/doku.php?
id=maxquant:start
Perseus Cox and Mann, 2012 http://www.coxdocs.org/doku.php?id=perseus:start
Progenesis-QI Version 2.0 Nonlinear Dynamics, Waters http://www.nonlinear.com/progenesis/qi/
Proteome Discoverer 1.4 (SEQUEST HT search
engine)
Thermo Fisher https://www.thermofisher.com/order/catalog/
product/IQLAAEGABSFAKJMAUH
R environment for statistical computing N/A https://www.r-project.org/
e2 Cell 167, 829–842.e1–e7, October 20, 2016
(JAX 003831) mice were bred and maintained on a Rag1–/–
(JAX 002216) background. WT C57BL/6 mice with different CD45 and
CD90 alleles were bred in our facility, and crossed with Rag1–/–
OT-I transgenic mice, to perform adoptive transfer experiments.
Arg2–/–
C57BL/6 (JAX 020286) mice were kindly provided by W. Reith. Hemagglutinin (HA) TCR-transgenic (6.5) BALB/c mice (Kirberg
et al., 1994) specific for peptide 111-119 from influenza HA were kindly provided by J. Kirberg and bred in our facility. All mice
were bred and maintained under specific pathogen-free conditions. Animals were treated in accordance with guidelines of the Swiss
Federal Veterinary Office and experiments were approved by the Dipartimento della Sanita` e Socialita` of Canton Ticino.
METHOD DETAILS
Isolation of Human T Cells
Peripheral blood mononuclear cells (PBMCs) were isolated by Ficoll gradient centrifugation. CD4+
T cells were enriched with magnetic
microbeads (Miltenyi Biotec). Naive CD4+
T cells were sorted as CD4+
CCR7+
CD45RA+
CD25–
CD8–
on a FACS Aria III cell
sorter (BD Biosciences). For cell staining, the following antibodies were used: anti-CD4-APC (allophycocyanin), clone 13B8.2;
anti-CD8-APC, clone B9.11; anti-CD8-FITC (fluorescein isothiocyanate), clone B9.11; anti-CD4-FITC, clone 13B8.2; antiCD45RA-PE
(phycoerythrin), clone alb11; anti-CD25-FITC, clone B1.49.9 (all from Beckman Coulter); anti-CCR7-Brilliant Violet
421, clone G043H7 (Biolegend).
Cell Culture
Cells were cultured in RPMI-1640 medium supplemented with 2mM glutamine, 1% (v/v) non-essential amino acids, 1% (v/v) sodium
pyruvate, penicillin (50 U mlÀ1
), streptomycin (50 mg mlÀ1
; all from Invitrogen), and 5% (v/v) human serum (Swiss Blood Center). Human
T cells were activated with plate bound anti-CD3 (5 mg/ ml, clone TR66) and anti-CD28 (1 mg/ml, clone CD28.2, BD Biosciences)
for 48 hr. Then, cells were cultured in IL-2 containing media (500 U/ml).
Metabolomics
Naive CD4+
T cells were either analyzed directly after isolation or at different time points after activation with CD3 and CD28 antibodies.
Cells were washed twice in 96-well plates with 75 mM ammonium carbonate at pH 7.4 and snap frozen in liquid nitrogen.
Metabolites were extracted three times with hot (> 70
C) 70% ethanol. Extracts were analyzed by flow injection – time of flight
mass spectrometry on an Agilent 6550 QTOF instrument operated in the negative mode, as described previously (Fuhrer et al.,
2011). Typically 5,000-12,000 ions with distinct mass-to-charge (m/z) ratio could be identified in each batch of samples. Ions
were putatively annotated by matching their measured mass to that of the compounds listed by the KEGG database for Homo sapiens,
allowing a tolerance of 0.001 Da. Only deprotonated ions (without adducts) were considered in the analysis. In case of multiple
matching, such as in the case of structural isomers, all candidates were retained.
Metabolic Flux Experiments
Naive CD4+
T cells were activated and 4 days later extensively washed and pulsed with L-arginine free RPMI medium containing
1 mM [U-13
C]-L-Arginine hydrochloride (Sigma). After increasing pulse-times, cells were washed and snap frozen in liquid nitrogen.
Metabolites were extracted and analyzed by HILIC LC-MS/MS.
Detection of Amino Acids and Polyamines by HILIC LC-MS/MS
Supernatants from extraction were dried at 0.12 mbar to complete dryness in a rotational vacuum concentrator setup (Christ, Osterode
am Harz, Germany) and dried metabolite extracts were stored at À80
C. Dry metabolite extracts were resuspended in 100 ml
water and 5 ml were injected on an Agilent HILIC Plus RRHD column (100 3 2.1mm 3 1.8 mm; Agilent, Santa Clara, CA, USA).
A gradient of mobile phase A (10 mM ammonium formate and 0.1% formic acid) and mobile phase B (acetonitrile with 0.1% formic
acid) was used as described previously (Link et al., 2015). Flow rate was held constant at 400 ml/min and metabolites were detected
on a 5500 QTRAP triple quadrupole mass spectrometer in positive MRM scan mode (SCIEX, Framingham, MA, USA).
Sample Preparation for Proteome MS Analysis
Samples were processed as described by (Hornburg et al., 2014). In brief, cell pellets were washed with PBS and lysed in 4% SDS,
10 mM HEPES (pH 8), 10 mM DTT. Cell pellets were heat-treated at 95
C for 10 min and sonicated at 4
C for 15 min (level 5, Bioruptor,
Diagenode). Alkylation was performed in the dark for 30 min by adding 55 mM iodoacetamide (IAA). Proteins were precipitated overnight
with acetone at À20
C and resuspended the next day in 8 M Urea, 10 mM HEPES (pH 8). A two-step proteolytic digestion was
performed. First, samples were digested at room temperature (RT) with LysC (1:50, w/w) for 3h. Then, they were diluted 1:5 with
50 mM ammoniumbicarbonate (pH 8) and digested with trypsin (1:50, w/w) at RT overnight. The resulting peptide mixtures were
acidified and loaded on C18 StageTips (Rappsilber et al., 2007). Peptides were eluted with 80% acetonitrile (ACN), dried using a
SpeedVac centrifuge (Eppendorf, Concentrator plus, 5305 000.304), and resuspended in 2% ACN, 0.1% trifluoroacetic acid
(TFA), and 0.5% acetic acid. For deeper proteome analysis a peptide library was built. For this, peptides from naive and activated
T cells were separated according to their isoelectric point on dried gel strips with an immobilized pH gradient (SERVA IPG BlueStrips,
3-10 / 11 cm) into 12 fractions as described by Hubner et al., 2008 (Hubner et al., 2008).
Cell 167, 829–842.e1–e7, October 20, 2016 e3
LC-MS/MS for Analysis of Proteome
Peptides were separated on an EASY-nLC 1000 HPLC system (Thermo Fisher Scientific, Odense) coupled online to a Q Exactive
mass spectrometer via a nanoelectrospray source (Thermo Fisher Scientific)(Michalski et al., 2011). Peptides were loaded in buffer
A (0.5% formic acid) on in house packed columns (75 mm inner diameter, 50 cm length, and 1.9 mm C18 particles from Dr. Maisch
GmbH). Peptides were eluted with a non-linear 270 min gradient of 5%–60% buffer B (80% ACN, 0.5% formic acid) at a flow rate of
250 nl/min and a column temperature of 50
C. Operational parameters were real-time monitored by the SprayQC software (Scheltema
and Mann, 2012). The Q Exactive was operated in a data dependent mode with a survey scan range of 300-1750 m/z and a
resolution of 70’000 at m/z 200. Up to 5 most abundant isotope patterns with a charge R 2 were isolated with a 2.2 Th wide isolation
window and subjected to higher-energy C-trap dissociation (HCD) fragmentation at a normalized collision energy of 25 (Olsen et al.,
2007). Fragmentation spectra were acquired with a resolution of 17,500 at m/z 200. Dynamic exclusion of sequenced peptides was
set to 45 s to reduce the number of repeated sequences. Thresholds for the ion injection time and ion target values were set to 20 ms
and 3E6 for the survey scans and 120 ms and 1E5 for the MS/MS scans, respectively. Data were acquired using the Xcalibur software
(Thermo Scientific).
Analysis of Proteomics Data
MaxQuant software (version 1.3.10.18) was used to analyze MS raw files (Cox and Mann, 2008). MS/MS spectra were searched
against the human Uniprot FASTA database (Version May 2013, 88’847 entries) and a common contaminants database (247 entries)
by the Andromeda search engine (Cox et al., 2011). Cysteine carbamidomethylation was applied as fixed and N-terminal acetylation
and methionine oxidation as variable modification. Enzyme specificity was set to trypsin with a maximum of 2 missed cleavages and a
minimum peptide length of 7 amino acids. A false discovery rate (FDR) of 1% was required for peptides and proteins. Peptide identification
was performed with an allowed initial precursor mass deviation of up to 7 ppm and an allowed fragment mass deviation of 20
ppm. Nonlinear retention time alignment of all measured samples was performed in MaxQuant. Peptide identifications were matched
across different replicates within a time window of 1 min of the aligned retention times. A library for ‘match between runs’ in MaxQuant
was built from additional single shot analysis at various time points as well as from OFF gel fractionated peptides of naive and memory
CD4 T cells. Protein identification required at least 1 razor peptide. A minimum ratio count of 1 was required for valid quantification
events via MaxQuant’s Label Free Quantification algorithm (MaxLFQ)(Cox and Mann, 2008; Luber et al., 2010). Data were filtered for
common contaminants and peptides only identified by side modification were excluded from further analysis. In addition, it was
required to have a minimum of two valid quantifications values in at least one group of replicates. Copy numbers were estimated
based on the protein mass of cells (Wisniewski et al., 2012). We set the protein mass of a naive T cell to 25 pg and of an activated
T cell to 75 pg.
Limited Proteolysis and Mass Spectrometry
Naive CD4+
T cells were washed twice with PBS and homogenized on ice under non-denaturing conditions (20 mM HEPES, 150 mM
KCl and 10 mM MgCl2 [pH 7.5]) using a tissue grinder (Wheaton, Millville, NJ, NSA). Homogenates were further passed several times
through a syringe (0.45x12mm) on ice. Next, cell debris was removed by centrifugation and protein concentration of supernatants
was determined by BCA assay (BCA Protein Assay Kit, Thermo Scientific, Rockford, IL, USA). L-arginine, D-arginine or L-ornithine
was added to homogenates to a final concentration of 1 nmol per mg total protein, and incubated for 5 min at room temperature. As a
control, samples without added metabolites were processed in parallel. Then, proteinase K from Tritirachium album (Sigma) was
added at an enzyme to substrate ratio of 1:100, followed by an incubation of 5 min at room temperature. The digestion was stopped
by boiling the reaction mixture for 3 min. Proteins were denatured by adding 10% sodium deoxycholate (DOC) solution (1:1, v/v) to the
reaction mixture, followed by a second boiling step of 3 min. Disulfide bridges were reduced with 5 mM Tris(2-carboxyethyl)phosphine
hydrochloride (Thermo Scientific) at 37
C for 30 min and subsequently free cysteines were alkylated with 40 mM IAA at
25
C for 30 min in the dark. DOC concentration of the mixture was diluted to 1% with 0.1 M ammonium bicarbonate (AmBiC) prior
to a stepwise protein digestion with LysC (1:100, w/w) for 4 hr at 37
C and trypsin (1:100, w/w) overnight at 37
C. The resulting peptide
mixture was acidified to pH < 2, loaded onto Sep-Pak tC18 cartridges (Waters, Milford, MA, USA), desalted and eluted with 80%
acetonitrile. Peptide samples were dried using a vacuum centrifuge and resuspended in 0.1% formic acid for analysis by mass
spectrometry.
Peptides were separated using an online EASY-nLC 1000 HPLC system (Thermo Fisher Scientific) operated with a 50 cm long in
house packed reversed-phase analytical column (Reprosil Pur C18 Aq, Dr. Maisch, 1.9 mm) (Reprosil Pur C18 Aq, Dr. Maisch, 1.9 mm)
before being measured on a Q-Exactive Plus (QE+) mass spectrometer. A linear gradient from 5%–25% acetonitrile in 240 min at a
flowrate of 300 nl/min was used to elute the peptides from the column. Precursor ion scans were measured at a resolution of 70,000 at
200 m/z and 20 MS/MS spectra were acquired after higher-energy collision induced dissociation (HCD) in the Orbitrap at a resolution
of 17,500 at 200 m/z per scan. The ion count threshold was set at 1,00 to trigger MS/MS, with a dynamic exclusion of 25 s. Raw data
were searched against the H. sapiens Uniprot database using SEQUEST embedded in the Proteome Discoverer software (both
Thermo Fisher Scientific). Digestion enzyme was set to trypsin, allowing up to two missed cleavages, one non-tryptic terminus
and no cleavages at KP (lysine-proline) and RP (arginine-proline) sites. Precursor and fragment mass tolerance was set at 10 ppm
and 0.02 Da, respectively. Carbamidomethylation of cysteines (+57.021 Da) was set as static modification whereas oxidation
e4 Cell 167, 829–842.e1–e7, October 20, 2016
(+15.995 Da) of methionine was set as dynamic modification. False discovery rate (FDR) was estimated by the Percolator (embedded
in Proteome Discoverer) and the filtering threshold was set to 1%.
Label-free quantitation was performed using the Progenesis-QI Software (Nonlinear Dynamics, Waters). Raw data files were imported
directly into Progenesis for analysis. MS1 feature identification was achieved by importing the filtered search results (as
described above) from Proteome Discoverer into Progenesis to map the corresponding peptides based on their m/z and retention
times. Annotated peptides were then quantified using the areas under their extracted ion chromatograms. Pairwise comparisons
were performed with the untreated (no metabolite added) sample as a reference and peptide fold changes were calculated using
three biological replicates per condition where the statistical significance was assessed with a two-tailed heteroscedastic Student’s
t test. A fold change was considered significant with an absolute change > 5 and a corresponding p value < 0.05. Only proteins with
two or more peptides changing significantly (according to the aforementioned criteria) were taken into consideration.
Quantitative Amino Acid Uptake and Calculation of Proteome Incorporation
150,000 freshly isolated naive CD4+
T cells were activated with plate bound CD3 and CD28 antibodies and cultured in the same medium
for four days. As a control, medium without cells was co-cultured. Then cell supernatants and control media were analyzed by
quantitative amino acid analysis (MassTrak, Waters) at the Functional Genomic Center in Zurich. Amino acid uptake was calculated
as the difference between control media and cell supernatants. At the time of the measurement, we counted on average 1 Mio cells.
We then calculated how much of each amino acid is incorporated into the proteome of 850,000 cells based on the amino acid
sequences and copy numbers of each protein. Average copy numbers from the time point 72 hr were used.
3
H-Arginine Uptake Assay
Arginine uptake was measured as previously described for glutamine uptake (Carr et al., 2010). Briefly, resting or activated T cells
were resuspended at a concentration of 1.5x107
cells/ml in serum-free RPMI 1640 lacking L-arginine. 50 ml 8% sucrose/20%
perchloric acid were layered to the bottom of a 0.5 ml Eppendorf tube and 200 ml 1-bromododecane on top of it (middle layer), followed
by 50 ml L-arginine-free medium containing 1.5 mCi L-[2,3,4-3
H]-arginine-monohydrochloride (Perkin Elmer). Then, 100 ml cell
suspension was added to the top layer and cells were allowed to take up radiolabeled L-arginine for 15 min at room temperature.
Cells were then spun through the bromododecane into the acid/sucrose. This stops the reaction and separates cells from unincorporated
3
H-L-arginine. The bottom layer containing the cells was carefully removed and analyzed by liquid scintillation. As controls
cell-free media were used.
OCR Measurements
Measurements were performed using a Seahorse XF-24 extracellular flux analyzer (Seahorse Bioscience). Naive CD4+
T cells were
sorted and activated with plate-bound CD3 and CD28 antibodies in complete medium or medium supplemented with 3 mM L-arginine.
Four days later (in the morning), cells were pooled, carefully count and plated (7 3 105
cells/well) in serum-free unbuffered RPMI-
1640 medium (Sigma) onto Seahorse cell plates coated with Cell-Tak (BD Bioscience). The serum-free unbuffered medium was not
supplemented with L-arginine. Oligomycin (1.4 mM, Sigma), Carbonyl cyanide-4-(trifluoromethoxy)phenylhydrazone (FCCP, 0.6 mM,
Sigma) and antimycin (1.4 mM, Sigma) were injected.
IL-2 Withdrawal Assay
Naive CD4 T cells were activated with plate-bound CD3 and CD28 antibodies. 48 hr after activation IL-2 was added to culture media
(500 U mlÀ1
). After a further 3 days of culturing, cells were washed, counted, and equal cell numbers were plated in medium devoid of
IL-2. The withdrawal medium was no longer supplemented with e.g., L-arginine. Cell viability was assessed with annexin V.
Cytokine Analysis
105
naive T cells were stimulated with plate bound anti-CD3 (5mg/mlÀ1
) and anti-CD28 (1mg/mlÀ1
) in the presence of IL-12
(10 ng/ml, R&D Systems) to polarize cells toward a Th1 phenotype. After 48 hr, cells were transferred into U-bottom plates and
IL-2 (10 ng/ml, R&D Systems) was added. Three days later, supernatants were collected and interferon-g was quantified using
FlowCytomix assays (eBioscience). Samples were analyzed on a BD LSR Fortessa FACS instrument and quantification was performed
with the FlowCytomix Pro 3.0 software. For re-stimulation, cells were cultured for 5 hr in the presence of 0.2 mM phorbol
12-myristate 13-acetate (PMA) and 1 mg/ml ionomycin (both from Sigma).
Glucose Consumption Assay
The amount of glucose in media was determined using the Glucose (GO) Assay Kit from Sigma. Consumption was calculated as the
difference between glucose content in reference medium (co-incubated medium without cells) and cell supernatants.
Analysis of Phosphorylation Levels of 4E-BP and S6K1
Naive CD4+
T cells were activated with plate-bound antibodies to CD3 and CD28. Four days after activation, cells were lysed and
analyzed by western blot with the following antibodies obtained from Cell Signaling Technology. Phospho-p70 S6K(Thr389)
#9205; p70 S6 Kinase #9202; Phospho-4E-BP1 (Thr37/46) #2855; 4E-BP1 #9644. Rapamycin (Sigma) was used at 100 nM.
Cell 167, 829–842.e1–e7, October 20, 2016 e5
CRISPR/Cas9-Mediated Gene Disruption
Two to four short guide RNAs (sgRNAs) per gene (Table S6) were designed using the online tool provided by the Zhang laboratory
(http://tools.genome-engineering.org). Oligonucleotide pairs with BsmBI-compatible overhangs were annealed and cloned into the
lentiviral vector lentiCRISPR v2 (Addgene plasmid # 52961) (Sanjana et al., 2014). For virus production, HEK293T/17 cells were transfected
with lentiCRISPR v2, psPAX2 (Addgene # 12260) and pMD2.G (Addgene plasmid # 12259) at a 8:4:1 ratio using polyethylenimine
and cultured in Dulbecco’s modified Eagle medium supplemented with 10% fetal bovine serum (FBS), 1% sodium pyruvate,
1% non-essential amino acids, 1% kanamycin, 50 units/ml penicilin/streptomycin and 50 mM b-mercaptoethanol. The medium was
replaced 12 hr after transfection and after a further 48 hr virus was harvested from supernatant. Cell debris was removed by centrifugation
(10 min at 2000 rpm followed) followed by ultra-centrifugation (2.5 hr at 24’000 rpm) through a sucrose cushion.
Freshly isolated naive CD4+
T cells were lentivirally transduced and activated with plate-bound CD3 and CD28 antibodies. 48 hr
after activation IL-2 was added to culture media (500 U/mlÀ1
). 6 days after activation, cells were cultured for 2 days in medium supplemented
with 1 mg/ml puromycin to select for cells expressing the lentiCRISPR v2 vector. Subsequently, cells were cultured in
normal medium followed by additional two days in medium containing puromycin for a second selection step. Then, single cell clones
were generated by limiting dilution as described in (Messi et al., 2003).
To screen for clones with disrupted target genes, individual clones were lysed with sample buffer containing 80 mM Tris (pH 6.8),
10.5% glycerol, 2% SDS and 0.00004% Bromophenol blue. Lysate of 100’000 cells was separated by SDS-PAGE followed, blotted
onto PVDF membranes and analyzed with antibodies to target proteins, Baz1B (Abcam, ab50850), PSIP1 (Bethyl, A300-848A),
DDX17 (Abcam, ab180190), PTPN6 (Santa Cruz, sc-287) or TSN (Sigma, HPA059561). As loading control membranes were reprobed
with an antibody to beta-tubulin (Sigma, T6074). To screen for clones with disrupted B2M, single cell clones were stained with an
antibody to MHC-I (eBioscience, HLA-ABC-FITC) and analyzed by flow cytometry.
Isolation and Culturing of Mouse CD8+
T Cells
Naive CD8+
OT-I cells were isolated from Rag1–/–
OT-I transgenic mice. Lymph nodes and spleens were harvested and homogenized
using the rubber end of a syringe and cell suspensions were filtered through a fine mesh. Cells were first enriched with anti-CD8 magnetic
microbeads (CD8a, Ly-2 microbeads, mouse, Miltenyi Biotec) and then sorted on a FACSAria III Cell Sorter (BD Biosciences) to
obtain cells with a CD44lo
CD62Lhi
CD8+
phenotype. OT-I cells (CD90.1+
) were cultured for 2 days in aCD3/aCD28 (2mg/ml) bound to
NUNC 96 well MicroWell MaxiSorp plates (Sigma-Aldrich M9410) in the presence or absence of 3 mM L-arginine in the culture
medium. On day 2 cells were transferred to U-bottom plates and cultured for 2 additional days in the presence of IL-2 (500 U/ml).
Adoptive T Cell Transfers and Survival Experiments
CD90.1+
CD45.1/2+
OT-I T cells were activated with plate-bound antibodies to CD3 and CD28 in control medium. OT-I cells with a
different congenic marker (CD90.1+
CD45.1+
) were activated in L-arginine-supplemented medium. At day 4, equal cell numbers
were injected into the tail vein of Cd3e–/–
host mice. To study the expansion of OT-I effector cells, host mice were sacrificed after
1, 3, 6, and 10 days post transfer and CD90.1+
OT-I T cells from lymphoid organs (spleen and lymph nodes) were enriched with
anti-CD90.1 microbeads (Miltenyi Biotec), stained and analyzed by FACS. The following monoclonal antibodies were used
a-CD8a (53-6.7), a-CD44 (IM7), a-CD62L (MEL-14), a-CD90.1 (OX-7), a-CD90.2 (30-H12), a-CD45.1 (A20), a-CD45.2 (104).
Tumor Experiments: In Vitro Activation of T Cells
B16-OVA melanoma cells were cultured in RPMI 1640 plus 10% FCS, 1% penicillin/streptomycin and 2 mM glutamine. Before injection
into mice, cells were trypsinized and washed twice in PBS. Then, 5x105
cells were subcutaneously injected in the dorsal region of
WT C57BL/6 mice. Ten days post injection, 5x106
OT-I cells, that have been activated in vitro as described above, were injected into
the tail vein of tumor-bearing mice. The size of tumors was measured in a blinded fashion using calipers.
Tumor Experiments: In Vivo Priming of T Cells
B16-OVA melanoma cells were cultured and injected into WT C57BL/6 mice as described above. Five days post injection, when
tumors were very small, mice were g-irradiated (5 Gy) and 24 hr later they received 4x105
OT-I cells intravenously (i.v.). The day after
mice were immunized intraperitoneally (i.p.) with SIINFEKL peptide (OVA257-264) in Imject Alum Adjuvant (Thermo Fisher Scientific).
L-Arg (1.5 g/Kg body weight) or PBS, as control, was daily orally administrated, starting one day before T cell transfer and until the end
of the experiment. The size of tumors was measured in a blinded fashion using calipers.
Experiments with Arg2–/–
Mouse T Cells
For in vitro experiments, 5x104
FACS-sorted naive T cells were activated with plate-bound antibodies to CD3 (2 mg/ml) and CD28
(2 mg/ml). Two days after activation, T cells were transferred into U-bottom plates and IL-2 was added to culture media. Four
days after activation, cells were washed extensively and plated in medium devoid of IL-2. Cell viability was measured two days after
IL-2 withdrawal by Annexin V staining. For in vivo experiments, 106
FACS-sorted WT CD8+
naive T cells (CD45.1+
) were transferred
together with 106
FACS-sorted Arg2–/–
CD8+
naive T cells (CD45.2+
, CD90.2+
), into slightly g-irradiated (3 Gy) WT mice (CD45.2+
,
CD90.1+
). The day after, host mice were immunized subcutaneously (s.c.) with MHC class-I binding peptide SIINFEKL (Chicken Ovalbumin,
OVA, amino acids 257-264, 15 mg/mouse) emulsified in Complete Freund’s Adjuvant, CFA. CFA was prepared by adding
e6 Cell 167, 829–842.e1–e7, October 20, 2016
4 mg/ml of M. tuberculosis H37RA (Difco) to Incomplete Freund’s Adjuvant, IFA (BD Biosciences). SIINFEKL peptide (OVA257-264) was
obtained from Servei de Proteo` mica, Pompeu Fabra University, Barcelona, Spain. On day 15 post immunization, mice were euthanized
and draining lymph nodes were collected and analyzed by flow cytometry. Cells were counted according to the expression
of congenic markers and by gating on live CD44hi
, H-2Kb/OVA257-264 multimer+
, CD8+
cells. The H-2Kb/OVA257-264 multimers
were purchased from TCMetrix.
Mouse Experiments with Dietary L-Arginine
2x105
CD90.1+
CD4+
HA TCR-transgenic T cells, on a BALB/c background, were adoptively transferred in WT CD90.2+
BALB/c mice.
The day after, host mice were immunized s.c. with influenza HA110-119 peptide (purchased from Anaspec) emulsified in CFA. L-Arg
(1.5 g/kg body weight) or PBS, as control, was daily orally administrated, starting 1 day before T cell transfer and until the end of the
experiment. Draining lymph nodes were analyzed on day 15 post immunization for the presence of transferred transgenic memory
CD44hi
CD90.1+
CD4+
T cells. Sera were collected 30 min after oral L-arginine administration to mice and L-arginine and L-threonine
concentrations in sera were measured on a MassTrak (Waters) instrument at the functional genomics center in Zurich. To determine
intracellular L-arginine levels, activated T cells were isolated from draining lymph nodes 60 hr after activation and 30 min after the
daily L-arginine administration. Metabolites were extracted with hot 70% ethanol and analyzed by HILIC LC-MS/MS.
QUANTIFICATION AND STATISTICAL ANALYSIS
Statistical parameters including the exact value of n, the definition of center, dispersion and precision measures (mean ± SEM) and
statistical significance are reported in the Figures and Figure Legends. Data were judged to be statistically significant when p < 0.05
by two-tailed Student’s t test. In figures, asterisks denote statistical significance as calculated by Student’s t test (*, p < 0.05; **, p <
0.01; ***, p < 0.001; ****, p < 0.0001). Survival significance in adoptive cell transfer studies was determined by a Log-rank test. Statistical
analysis was performed in R or GraphPad PRISM 6.
Proteome Data
Data analysis was performed using the Perseus software and the R statistical computing environment. Missing values were imputed
with a normal distribution of 30% in comparison to the SD of measured values and a 1.8 SD down-shift of the mean to simulate the
distribution of low signal values (Hubner et al., 2010). Statistical significance between time points was evaluated by one-way ANOVA
for each proteinGroup using a FDR of 0.1% and S0 of 2 (S0 sets a threshold for minimum fold change), unless otherwise noted (Tusher
et al., 2001). For pairwise comparison, t test statistic was applied with a permutation based FDR of 5% and S0 of 1.
Enrichment Analysis
Univariate test was performed on either all proteins or metabolites by t test with unequal variance (Welch Test). The resulting P-values
were adjusted using the Benjamini-Hochberg procedure. Enrichment analysis was performed as suggested by Subramanian et al.
(Subramanian et al., 2005). Both for metabolomics and proteomics data, we applied a permissive filtering with adj. p value less or
equal than 0.1 and absolute log2(fold-change) larger or equal than 0.5. Enrichment P-values were calculated by the Fisher’s exact
test for all incremental subsets of filtered features ranked by the p value. For the 261 pathways defined by KEGG, the lowest P-value
was retained as a reflection of the best possible enrichment given by the data independently of hard cut-offs. Eventually, enrichment
P-values were corrected for multiple testing by the Benjamini-Hochberg method. In general, enrichments with an adjusted P-value <
0.05 were considered significant. Pathway enrichments were calculated independently for proteomics and metabolomics data. For
metabolome-based enrichments, structural isomers in pathway were condensed and counted only once to account for the fact that
the employed technology cannot distinguish between metabolite with identical molecular weight.
DATA AND SOFTWARE AVAILABILITY
The metabolomics and proteomics data are available in Tables S1 and S2. All software is freely or commercially available and is listed
in the STAR Methods.
Cell 167, 829–842.e1–e7, October 20, 2016 e7
Supplemental Figures
Figure S1. Quality Control of the Proteome Dataset, Related to Figure 1
(A) Sorting of human naive CD4+
T cells. Shown are FACS plots of cells after enrichment with anti-CD4 magnetic beads. Cells were sorted as CD4+
CCR7+
CD45RA+
and CD8–
CD25–
.
(B) Expression kinetics of indicated marker proteins. Bars represent the SEM of data from different donors, n = 7 (for resting cells), n = 3 (for 12h, 72h), n = 2 (for
96h, 48h), n = 1 (for 24h). CD25 and CD8 were not identified in resting cells. After activation, expression of CD25 increased whereas CD8 was never detected.
(C) Identified protein groups per condition. Taking all conditions together, a total of 9,718 proteins were identified. Per condition two numbers are indicated; the
higher number indicates the total identifications and the lower number the mean of the single shots. Samples in blue were measured on a different instrument than
samples in black. L-arg refers to 3 mM L-arginine.
(D) Relative protein abundance over time shown as a heat map. Log2 fold changes (FC) are relative to naive resting T cells. The marker for proliferating cells Ki-67
increased abruptly after 48h, when cells started to proliferate. CD40L expression increased immediately after activation and then decreased to initial levels. A
similar expression pattern was observed for CD69, which inhibits egress from lymph nodes (Shiow et al., 2006). The expression of integrins a4 and b7 increased at
later time points.
(E) Copy numbers of individual subunits of well-characterized protein complexes were plotted against each other. As the Sec23 subfamily includes Sec23A and
Sec23B, their copy numbers were added up. The same was done for the subfamily members of Sec24 (A-D).
(F) Copy numbers of components of the nuclear pore complex (NPC). The stoichiometry of subunits measured using targeted quantitative proteomics (Ori et al.,
2013) is indicated on the graph in red. Shown are copy numbers measured in naive resting T cells from seven donors.
(G) Same as in (F) but shown are copy numbers measured from activated cells (72h). n = 3 from three donors. Note that the numbers of Nup107 increased from
11,464 ± 1620 to 53,091 ± 1471. (A and E–G) Error bars represent SEM throughout.
L-Ornithine
L-Citrulline
5-(3'-Carboxy-3'-oxopropyl)-4,6-dihydroxypicolinate
Aminoimidazoleribotide
Serotonin
1-(5-Phospho-D-ribosyl)-5-amino-4-imidazolecarboxylate
5'-Phosphoribosyl-N-formylglycinamide
Linoleate
Oxalate
Campestanol
dTDP-4-dehydro-6-deoxy-L-mannose
2-C-Methyl-D-erythritol4-phosphate
Pyridoxine
N-Acetyl-L-phenylalanine
2-Deoxy-scyllo-inosamine
Phenethylamine
Dopamine
5,6-DHET
Glutathionylspermine
Toluene
Cyanuricacid
Phenylacetaldehyde
GMP
dADP
Glutathionedisulfide
UMP
CMP
Taurine
AMP
Citrate
L-Aspartate
L-Glutamine
4-Aminobutanoate
L-Glutamate
O-Phospho-L-serine
UDP-glucose
UTP
UDP
CDP
Phosphodimethylethanolamine
Glycine
D-Glucose
5-Aminolevulinate
L-Alanine
Maleamate
L-Proline
GTP
L-Threonine
Orthophosphate
L-Leucine
L-Tyrosine
L-Phenylalanine
L-Methionine
L-Valine
5-Amino-6-(5'-phosphoribosylamino)uracil
Thiodiaceticacid
Mercaptopyruvate
Fumarate
5-Phospho-alpha-D-ribose1-diphosphate
D-Fructose1,6-bisphosphate
Luteolin
5-L-Glutamyl-taurine
dCDP
Toluene-4-sulfonate
UDP-glucuronate
D-Ribose5-phosphate
Cystathionine
S-(Indolylmethylthiohydroximoyl)-L-cysteine
UDP-D-xylose
Cytidine
sn-glycero-3-Phosphoethanolamine
Glutathione
ATP
ADP-ribose
UDP-N-acetyl-D-glucosamine
ADP
GDP
GDP-L-fucose
CyclicADP-ribose
GDP-mannose
NADH
(S)-Malate
Carbonicacid
Propan-2-ol
L-Arginine
na
12h
24h
48h
72h
96h
120h
3h
na
12h
24h
48h
72h
96h
120h
3h
L-CitL-Arg
0 2-2
Resting cells Activated 12 h Activated 24 h
Activated 48 h Activated 72 h Activated 96 h
Nitric oxideNitric oxideNitric oxide
Nitric oxideNitric oxideNitric oxide
Ctrl
L-Arg
A
B
Log2 fold change
Figure S2. Impact of L-citrulline on Metabolism, Related to Figure 3
(A) Human naive CD4+
T cells were activated in normal medium or in L-Arg medium. Nitric oxide formation was measured using DAF-FM diacetate at different time
points.
(B) T cells were activated in control medium (Ctrl, containing 1mM L-arginine), or in medium supplemented with 3mM L-arginine (L-Arg) or 3mM L-citrulline (L-Cit)
and harvested at different time points. The heat map shows the difference in the abundance of metabolites in T cells cultured in L-Arg- or L-Cit-medium compared
to controls. Shown are only metabolites with a log2 fold change > 1 and an adjusted p value of < 0.05. n = 6 from one donor.
48 72 96 120
6
8
10
12
L-Arg
Ctrl
B
CTV(MFIx10-3)
Time [h]
A
Ctrl
L-Arg +
L-Lys
L-Arg
48h 72h
Intensity
C
trl
L-Arg
L-Lys
0
2
4
6
3H-L-Arguptake[cpmx10-3]
D
-Arg
Ctrl
D-Arg
L-Arg
48h 72h
Intensity
CTV CTV CTV CTV
C
Figure S3. L-Arginine Delays the Onset of Proliferation, Related to Figure 4
(A) Kinetics of T cell proliferation. Human naive CD4+
T cells were labeled with CellTraceViolet (CTV) and activated in Ctrl medium or in L-Arg medium or in medium
supplemented with 3 mM D-arginine or 3 mM L-arginine together with 3 mM L-lysine. Cell divisions were monitored at 48h and 72h by flow cytometry.
(B) CTV-labeled CD4+
T cells were activated in normal medium or L-Arg medium and the dilution of CTV was measured over time by flow cytometry. n = 5 from two
donors.
(C) 3
H-L-arginine uptake by 3 day-activated CD4+
T cells during a 15 min pulse. Where indicated, 3 mM L-arginine, D-arginine or L-lysine was added to the culture
medium as a competitive uptake inhibitor. n = 7 for control, n = 9 for L-Arg, n = 5 for D-Arg, and n = 9 for L-Lys. Error bars represent SEM throughout.
Figure S4. L-Arginine Increases the Survival of Activated T Cells Independent of mTOR Signaling, Related to Figure 4
(A) Human naive CD4+
T cells were activated for 4 days, lysed and the phosphorylation levels of S6K1 (pThr389) and 4E-BP (pThr37/46) were analyzed by western
blot. Rapamycin inhibited the phosphorylation of the mTOR targets, while DMSO or supplementation of the culture medium with 3 mM L-arginine had no effect.
T cells hardly proliferated upon activation in culture medium containing no or 20 mM L-lysine and therefore phosphorylation of the target proteins could not be
assessed.
(B) T cell survival experiment. Human naive CD4+
T cells were activated in Ctrl medium or in medium containing 100 nM rapamycin. On day 5, cells were washed to
withdraw IL-2 and cell survival was measured at different time points.
(C) Same as in (B) but cell survival was only measured 5 days after IL-2 withdrawal. n = 7 from seven donors. Boxplot. Same as in Figures 2A and 2B.
(D) Metabolic profiling of CD4+
T cells activated in medium containing 100 nM rapamycin. The heat map shows the difference of metabolite abundances between
rapamycin-treated cells and controls. n = 10 from two donors.
3
3.5
4
4.5
5
5.5
Arginine(a.u.)
CD4+ CD8+
W
tArg2-/-
W
tArg2-/-
0
200
400
600
800
1000
L-arginine[μM]
0
200
400
600
800
1000
L-Threonine[μM]
PBS-fedL-Arg-fed
PBS-fedL-Arg-fed
A B C
0.0
0.5
1.0
1.5
2.0
PBS-fed
L-Arg-fed
Arginine(a.u.)
******* n.s. ** *
Figure S5. Oral Administration of L-Arginine Increases L-Arginine Levels in Mouse Sera and T Cells, Related to Figure 5
(A) BALB/c mice were administered L-arginine (1.5 mg/g body weight) and sera were collected after 30 min. L-arginine and, as a control, L-threonine concentrations
were analyzed on a MassTrak amino acid analyzer. n = 4.
(B) BALB/c mice were immunized with ovalbumin in CFA. Sixty hours later, activated T cells from draining lymph nodes were enriched using magnetic beads
coated with antibodies to CD44. Metabolites were extracted using hot 70% ethanol and L-arginine and L-glutamine levels (as an internal standard) were
measured using LC-MS/MS. Shown is the ratio between L-arginine and L-glutamine intensities. n = 14.
(C) Intracellular L-arginine levels of wild-type and Arg2–/–
CD4+
and CD8+
T cells 4 days after activation. n = 3. For statistical tests, a two-tailed unpaired Student’s
t test was used throughout, n.s. non significant; *p < 0.05; **p < 0.005; ***p < 0.0005; ****p < 0.0001. Error bars represent SEM throughout.
C
trlL-Arg
Ex-527
L-Arg
+
Ex-527
B
-20
-10
0
10
20
30
n.s.A
48
72
96
0
1
2
3
Sirtuin-1copies(x10-4)
Hours after activation
L-Arg
Ctrl
n.s.
* **
-20
0
20
40
60
n.s.
Cas9
Ctrl
Sirt1 KO
C
Ctrl
C
as9
C
trl
sgR
N
A1C
as9
C
trl
sgR
N
A2
SIRT1
*
Diff.oflivingCD4+Tcells[%]
Diff.oflivingCD4+Tcells[%]
Figure S6. L-arginine Upregulates Sirtuin-1, Related to Figure 6
(A) Copy numbers of Sirtuin-1 (SIRT1) as determined by quantitative MS in human naive CD4+
T cells activated in normal medium or L-Arg-medium. n = 3 from
three donors.
(B) T cell survival experiment. The Sirtuin-1 inhibitor Ex-527 was added at the time point of activation at a concentration of 5 mM. n = 16 from four donors.
(C) T cell survival experiments with clones expressing Cas9 only, or clones devoid of Sirtuin-1. n = 16 from 6 clones. Right panel: western blot of two different
Sirtuin-1 knockout clones generated with different sgRNAs. * unspecific band. For statistical tests, a two-tailed unpaired Student’s t test was used throughout,
n.s. non significant; *p < 0.05; **p < 0.005; ***p < 0.0005; ****p < 0.0001. (B and C) Error bars represent SEM throughout.