Intercellular communication
Distant
Local
General properties of endocrine organs
Endocrine organs (e.g. pituitary, thyroid, parathyroid, adrenal) Endocrine tissue within other organs (pancreas, gonads, kidneys, placenta) Isolated endocrine cells (DNES, APUD) Neuroendocrine cells
Common developmental scheme
invagination of epithelia, losing contact with the original tissue ducts absents
General properties of endocrine organs
• c.t. capsule + septs
• Trabecules of glandular epithelium, follicles or clusters of glandular cells
or
• Neurosecretory cells
• Capillary network
- Fenestrated capillaries
- Sinusoids
• Merocrine secretion
- not only hormones - endocrine gland is sensu lato also liver
General properties of hormones
• steroids - hydrophobic, intracytoplasmic or nuclear receptors (sex hormones, corticoids)
• proteins and polypeptides - hydrophilic, plasma membrane receptors (insulin, pituitary hormones, PTH, ...)
• aminoacids and their derivatives (adrenalin, noradrenalin, thyroxin)
Chemokines, Hormones,
Survival Factors        Transmitters Growth Factors
(e.g., IGF1)        (e.g. interleukins, (e.g. TGFa, EGF)
serotonin, etc.) ,
J-.      r-l-. I
Extracellular Matrix
t
Death factors (e.g. FasL, Tnf)
Pituitary gland (gl. pituitaria)
Pituitary gland (gl. pituitoria)
• sphenoid bone
• sella turcica
• fossa hypophysial
Pituitary gland (gl. pituitaria)
Pituitary gland (gl. pituitaria)
• adenohypophysis {pars distalis, pars tuberalis, pars intermedia)
• neurohypophysis {pars nervosa)
• infundibulum, eminentia mediana
Pituitary gland (gl. pituitaria)
• adenohypophysis - glandotropic hormones, prolactin, GH
• neurohypophysis - hypothalamic hormones - ADH, oxytocin
anatomical and functional association with hypothalamus capillary systems and neuroendocrine secretion .
portal vessel
Neurosecretory
FSH		Growth		Prolactin
and		hormone		(PRL)
LH		<GH)	I	
			1	
Thyroid   Adrenal  Testes or cortex ovaries
Endocrine cells of the anterior pituitary
1
Endorphins!
I
Entire     Mammary Pain body        glands receptors (in mammals) in the brain
Copyright © 2005 Pearson Education. Inc. Publishing as Pearson Benjamin Cummings. All rights reserved.
Hypothalamus
• small region of diencephalon
• complex neuroarchitecture
• core of the limbic system
• complex functions
- regulation of temperature, emotions, eating behavior, circadian rythms
- hormonal regulation controlled by various stimuli (osmoreception, concentration of nutrients, electrolytes, systemic functions - pain)
• hypothalamic nuclei
- n. supraopticus, n. paraventricularis
- magnocelullar neurons - tractus hypothalamo-hypophysialis
- parvocelullar neurons - capillaries in eminentia mediana
Anterior Posterior lobe lobe
Pituitary gland
Hypothalamo-hypophyseal system
Mechanism of neurosecretion
Tractus hypothalamo-hypophysialis
- axons of magnocelullar neurons in nucleus supraopticus and paraventricularis
- terminating on fenestrated capillaries in neurohypophysis
- synthesis of prohormones —> during axonal trasnportion maturation
- capillary plexus from arteria hypophysialis inferior (branch of arteria carotis interna —> sinus cavernosus
Hypophyseal portal system
- parvocellular neurons e.g. in nucleus arcuatus, preopticus, paraventricularis and nuclei tuberales
- axonal transport onto primary capillary plexus in eminentia mediana (from anterior and posterior superior hypophyseal arteries) —» hypophyseal portal veins —> secondary capillary plexus in adenohypophysis —> inferior hypophyseal portal veins —> vv. jugulares internae
Capillary system of hypophysis
ncl. paraventricularis
ncl. supraopticus
Tractus hypothalamo-hypophysialis
secondary plexus of posterior lobe
ö    hypophyseal arteries
anterior lobe
EminentJa mediana
• elevated part of tuber cinereum, ( detachment of infundibulum p. nervosa)
Embryonal development of pituitary gl.
Ectoderm (Rathke's pouch)
Neuroectoderm of ventral wall of diencephalon
-Infundibular process Forebrain Neural ectoderm
Infundibular process
Rathke's pouch Oral ectoderm
Mesoderm'
Rathke's pouch
1. Beginning formation of Rathke's pouch and infundibular process
2. Neck of Rathke's pouch constricted by growth of mesoderm
3. Rathke's pouch "pinched off"
Median eminence
Sphenoid sinus
Pars tubcralis Infundibulum Pars nervosa
Pars intermedia
4. "Pinched off" segment conforms to neural process, forming pars distalis, pars intermedia and pars tuberalis
5. Pars tuberalis encircles infundibular stalk (lateral surface view)
Pars distalis
6. Mature form
A = fossa
B = hypothalamus C,= eminentia mediana D = adenohypophysis
Adenohypophysis (anterior lobe)
Chromophilic cells Acidophils
Nonglandotropic - direct effect on target tissues
Bazophils
Glandotropic - regulation of other endocrine glands
Chromophobic cells
• undifferentiated cells
• degranulated ("empty") chromophils
• stromal cells
Pituitary Gland h&e
Adenohypophysis (anterior lobe)
Adenohypophysis (anterior lobe)
Adrenocorticotf^ic honmne^lK,
TU rplk*3f 3      JKLl^ - Tu /
adrenal       thyroid gonads mammary
• FSH cortex giands
• LH
• ACTH
• TSH
• Prolactin
• Endorphins
• Growth hormone
Pro-opio-melanocortin (POMC)
rough ER —» pre-prohormon produced by various tissues
cleavage to
• ACTH (target: adrenal cortex —» kortisol)
• MSH (target: melanocytes - mostly in paracrine way)
• lipotropin (lipolysis, steroidogenesis)
• endorphins
POMC
11
■ i
■ i 11
ii ■ i
Y-MSH
ACTH
0-lipotropin
ii 11 ■ i ii
11 ■ i
■ i
a-MSH	CLIP	Y-lipotropin	0-endorphin
(3-MSH
Corticotrophs hypofunction
Addison's Disease
lack of negative feedback inhibition
ACTH
increased tropic hormone secretion: increased ACTH levels
CLfSHING'S 5YNOFLOME
Thfamng of acalp hair Emolianal instability Apia
-Moon face
Increased (soialhaif BltHbIj hump
— hypflrbOPhy and hypertension
4 JDISCi1- : DISEASE
PerscfMidy changes
Aríorfinia. nausea,
Hypsr-pigiwiiahon
Cardiao
jnsuifieieney, ftypotensön
Adrenal •mpřiy;-
■ AiHoirmriune - Infection
■ Tumor rneíBEiBBts
Diarrhea, abdommal
pain
Muscle weakness
Adrenal: ■ turnt*
i -.jií.fli oběsily
$lriseoi skin
Easy tagging
Muscle vKSFSt"^-■ WeaKness T-hin exťeTiibeE-
Diabetes
■inillirij::
destruction of adrenal gland íauto I m mune or tu bereu los Is)
Corticotrophs hyperfunction
Hypothalamus		(-)
		
	Corticotropin Releasing Hormone (CRH)	
Anterior Pituitary		(-)
		
	Adrenocorticotropic Hormone (ACTH)	
		
Adrenal Cortex		
Cor	íkdI -	
low Cortisol
FSH (folitropin), LH (lutropin)
• gonadotropic cells of adenohypophysis stimulated by GnRH
• glycoproteins, 30kDa
• heterodimer, two noncovalent bound subunits (a/a - common for - LH, FSH, TSH, hCG, b/ß - specific)
• FSH receptor (testes, ovarium, uterus) G-protein coupled receptor
- glycosylated extracellular domain of 11 leucine rich repeats specific to FSH
- after ligand binding, activation of G-protein and cAMP signaling
- alternative activation of MAPK cascade (ERK)
- complex signaling response (prostaglandins, PLPc, NO)
FSH LH
ovarium follicle development (FSHR in m. granulosa        ovulation, development of
cells) corpus luteum, production of
androgens in thecal cells
testes spermatogenesis, FSHR in Sertoli cells production of testosterone in
Leydig cells (expression of LHR)
extragonadal   FSHR in secretory endometrium of luteal phase  uterus, seminal vesicles,
uterus (endometrial functions, embryo- prostate, skin... unknown
endometrial interactions) function
TSH, thyrotropin
thyrotropic cells of adenohypophysis stimulated by TRH production of T4 (thyroxin) a T3 (triiodothyronin) by thyroid gland glycoprotein, 28,5 kDa, heterodimer, two noncovalent bound subunits (a, b) TSH receptor on thyroid follicular cells G-protein signaling —» adenylylcyklase —> cAMP
cAMP —» iodide channels (pendrin), transcription of thyreoglobulin, endo- and exocytic pathway
cross-reactivity with hCG —> in pregnancy - alterations in synthesis of thyroid hormones (gestational hyperthyroidism)
GH, somatotropin, growth hormone
somatotropic cells of adenohypophysis stimulated by GHRH (somatocrinin) several molecular isoforms (alternative splicing), ~20-24 kDa broad spectrum of target cell types and physiological circuits transcription of DNA, translation of RNA, proteosynthesis lipid use (fatty acid mobilization, conversion to acetyl-CoA) inhibition of direct use of glucose, stimulation of glukoneogenesis transmembrane transport of aminoacids
proteosynthesis in chondrocytes and osteoblasts, proliferation, osteogenesis GHR in various tissues RTK, JAK-STAT
Pituitary gland
somatomedins
small proteins (MW 7,5 kDa), IGF-like produced by liver
various pathologies associated with GH
Muscle
Bone growth
Growth hormone (GH)
GHRH (GH-releasing hormone) stimulates the release of GH.
GHIN (GH-inhibiting hormone) inhibits the release of GH.
Adipocytes break down triglycerides.
The liver breaks down glycogen.
Insulin-like growth factors (IGFs) stimulate amino acid uptake by target cells, promoting protein synthesis.
Table 2. Nor classical Anterior Pituitary Substances and Cell(s) of Origin	
Substances	Cell Types
PEPTIDES	
ACTIVIN B, INHIBIN, FOLLISTATIN	F,G
ALDOSTERONE STIMULATING FACTOR	UN
ANGIOTENSIN II (ANGIOTENSINOGEN, ANGIOTENSIN 1	
CONVERTING ENZYME, CATHEPSIN B, RENIN)	C,G,L,S
ATRIAL NATU RET IC PEPTIDE	G
CORTICOTROPIN-RELEASING HORMONE-BINDING PROTEIN	C
DYNORPHIN	G
GALANIN	L.S.T
GAWK (CHROMOGRANIN B)	G
GROWTH HORMONE RELEASING HORMONE	UN
HISTIDYL PROLINE DIKETOPIPERAZINE	UN
MOTILIN	S
NEUROMEDIN B	T
NEUROMEDIN U	C
NEUROPEPTIDE Y	T
NEUROTENSIN	UN
PROTEIN 7B2	G.T
SOMATOSTATIN 28	UN
SUBSTANCE P (SUBSTANCE K)	G.L.T
THYROTROPIN RELEASING HORMONE	G. L.S.T
VASOACTIVE INTESTINAL POLTPEPTIDE	G,L,T
GROWTH FACTORS	
BASIC FIBROBLAST GROWTH FACTOR	C,F
CHONDROCYTE GROWTH FACTOR	UN
EPIDERMAL GROWTH FACTOR	G.T
INSULIN-LIKE GROWTH FACTOR 1	S,F
NERVE GROWTH FACTOR	UN
PITUITARY CYTOTROPIC FACTOR	UN
TRANSFORMING GROWTH FACTOR ALPHA	L,S,G
VASCULAR ENDOTHELIAL GROWTH FACTOR	F
CYTOKINES	
INTERLEUKIN-1 BETA	T
INTERLEUKIN-6	F
LEUKEMIA INHIBITORY FACTOR	C.F
NEUROTRANSMITTERS	
ACETYLCHOLINE	OL
NITRIC OXIDE	F
C = corticotropin, F = folliculostellate cell, G = gonadotroph, L = lactotroph, S = somatotroph, T = thyrotroph, UN = unknown
Clinical links
Hypophyseal tumors
• compression of surrounding structures (optic chiasma)
• hyperfunction of endocrine component
- prolactinoma - galactorrhea
- hypogonadism (alterations of GnRH)
- gigantism - acromegaly
- nanism
Afferent nerves to hypothalamus
Hypothalamic neuron to posterior lohe
I'araventrk ular nu< leus
Hypothalamic neurons for releasing and inhibitory factors to anterior lobe
Suprao|)tic nucleus
Primary capillary plexus receives neurosecretions from hypothalamus
Hypophyseal portal veins carry neurosecretions to anterior lobe Specific glandular cells of anterior lobe
Anterior lobe
Skin (melanocytes)
Diabetogenic "actor
tissue
Thyroid hormones hormone
\drenocortical   1 Estrogen
Bone, muscle. Cgppancreas     % N
organs (growthi Oy * '
0
's Testosterone Progesterone
Posterior hypophysis (neurohypohysis)
Monocellular neuron
nonmyelinated nerve fibers
- axons of neurosecretory cells (c.a 100 000) of hypothalamic nuclei (n. supraopticus and paraventricularis)
pituicytes (neuroglia)
- astrocyte-like (intermediate fialmets, GFAP)
- local control of secretion from neuroscretory termini
- Herring bodies - neurosecretory endings - dilatation close to capillaries
Hormones
- oxytocin (OT)
- antidiuretic hormone (ADH, vasopresin)
N^urösecrerar-jr
cells
Hypophyseal portal □ neu lad on
Anterior pituitary hormones and prolactin
Hypothalamus
Pituitary gland
Pöitfiriör piTuirary hormones öyjrEödn and tfaiopressin
Site of hormone exocytosis
Efferent vein
Paraventricular nucleus
Supraoptic nucleus
▼ Neurosecretory Ending (posterior pituitary).
Pituicyte processes
Axon
Capillary rnrlolhelium
Neurosecretory vesicles
Arterial supply to hypothalamus
Hypothalamohypophyseal tract
Herring bodies Anterior lobe
Basal lamina
▼ Origin of ADH.
^r—~- Hyp°,halamic
Unmyelinated axon
Posterior lobe
Fenestrated capillary
Inferior hypophyseal artery
Hormone          Principal Action	Principal Nucleus of Origin	
Oxytocin (OXY) Uterine contraction, milk ejection		Paraventricular
Anti-diuretic      Water excretion in kid hormone (ADH) arteriolar constriction	ney,	Supraoptic
Oxytocin
nonapeptide
magno-cellular supraoptic and paraventricular nuclei of the hypothalamus
OR - G-coupled receptor Lcu .. ^
• nonapeptide
• retention of water
• effective in collecting duct and distal convoluted tubule (aquaporine translocations)
• blood pressure regulation by affecting t. media
• diabetes insipidus, hypernatremia, polyuremia
lactation reflex uterine contraction social behavior
Gl/      0 H
Vasopressin
Anatomy			Microscopic anatomy			Hormones and target tissues		
			trabecular epithelium in cords and clusters, reticular fibers					
sis)		superior hypophyseal arteries —> primary capillary plexus	chromophobes	undifferentiated cells degranulated chromophilic cells stromal cells		lack hormonal activity		
hypophy	pars distalis	—> hypophyseal portal veins + inferior hypophyseal		ilic tropic	mammotropic cells	small polypeptides	dopamin (PIH) 1 (PRF —> prolactin	mammary gland in gravidity and lactations
lobe (adeno		arteries -> secondary capillary plexus —> hypophyseal portal veins —>	i/i IE	acidoph nonglandoi	somatotropic cells		somatostatin (GHIH) 1 GHRH —> somatotropin (STH)	directly liver and growth plates other tissues via somatomedins
Anterior			Q. O					adrenal cortex —> Cortisol melanocytes
	pars tuberalis	vv. jugulares internae	chromí	<j	corticotropic cells	to	CRH -> ACTH, MSH	
				»ophilic dotropi	thyrotropic cells	Dproteir	TRH TSH	thyroid —> thyroxin, T3
	pars intermedia	Rathke's cysts		X! IS on	gonadotropic cells	glycc	GnRH     FSH (ICSH), LH	gonads —> androgens, estrogens, progesterone
o ■£	eminentia mediana —> infundibulum	anterior and posterior superior hypophyseal arteries —> primary capillary plexus, fenestrated capillaries		nonmyelinated axons		to <u	ADH	tubulus reuniens, ductus colligens t.media of vessels
— Q. i- O			of hypothalamic neurons n. supraopticus,			"O		myometrium of uterus during gravidity myoepithelium of lactating mammary gland
Posterio (neurohyp	pars nervosa			n. paraventricularis (tractus lypothalamohypophysialis), pituicytes		small pep	oxytocin	
BREAK
To study the effects of the hypothalamo-pituitary-adrenal axis, groups of mice were injected with different hormones. Group A mice were injected with Cortisol to mimic effects of Cushing's syndrome. Group B mice were injected with hormone X. Group C mice were injected with a saline solution. Blood samples were later taken from the various groups and average hormone levels were measured and recorded in Table 1.
Table 1. Levels of hormones (in nmol/L) found in blood sample taken from experimental mice groups.
Hypothalamus
(-)
Corticotropin Relets ng hornore-
(ľkh;
Anterior Pituitary
	CRH	ACTH	Cortisol
Group A	20	150	900
Group B	45	430	760
Group C	30	230	400
According to the results of the experiment, which is the
most likely identity of hormone X?
Please choose from one of the following options.
•CRH, because Group C's concentration of ACTH and Cortisol is lower
than that of the control group.
•ACTH, because Group B's concentration of ACTH and Cortisol is higher than that of the control group.
•ACTH, because Group C's concentration of ACTH and Cortisol is lower than that of the control group._
CRH, because Group B's concentration of ACTH and Cortisol is higher than that of the control group._
Which of the following would exacerbate the symptoms of Cushing's disease?
Please choose from one of the following options. •Somatic cells not responding to Cortisol. •Taking a glucocorticoid receptor antagonist.
Radiation therapy to treat a pituitary adenoma._
■Taking glucocorticoids to treat asthma.
(-)
Aďůn^-crlicc.růr-ic Húfnoiŕ i'ACTH)
Adrenal Cortex
Why does a pituitary adenoma cause a patient to have an excess level of Cortisol?
Please choose from one of the following options.
•It increased the size of the hypothalamus.
•Its cells did not respond to CRH._
•Its cells did not respond normally to Cortisol.
•It decreased the level of ACTH circulating in the body.
Which of the following can result in a chronic increase in a patient's ACTH and CRH levels?
•Pituitary tumor. [•Destruction of the adrenal glands.
•Taking medicinal glucocorticoids, such as prednisone. •Hypersecretion of Cortisol from the hypothalamus.
Epiphysis (c. pineale)
Pineal Gland H&E
Pineal Gland
epithalamus
c.t. capsule continuous to pia mater thin c.t. septa
nonmyelinated nerve fibers
pinealocytes (95%, large, pale, round nuclei)
interstitial neuroglia (astrocytes, dark,
elongated nuclei)
acervulus cerebri
melatonin
Epiphysis, (HE)t objektiv 5*
ti Ě
' \>.v
trámce pinealocytů
a   .'V*^ acervulus cerebri
r;j5Q_Hiiri,.;-
Epiphysis (c. pineale)
pinealocytes
star-like, modified neurons in trabecules association with fenestrated capillaries neurosecretory dilatations nonvisual photoreception
(Mel)
MT2
AC   | PLC
I I
PKA  -   cAMP i   DAG t
:
AC PLC
I
P-CREB
1
PKC f
GC
1 I
cGMP,   cAMPJ    DAG t
I i
PKA J    PKC t
1
P-CREB
Blood
'HCC0OH ^TRYPTOPHAN
TRIPTOPHAN HYDROXYLASE ITPH)
HH_.
<H-C™u   5-HYDROS TRIPTOPHAN "CH (S-HTP)
a r      ati c-l- amino- acid DECARBOXiLASE
Mi
5 EROT ONIM n- acetyl TRANSFERASE Or A a-NAT
HYDROXYINDOLE O- M ETHV LT HA N F ERASE (HlOMT)
h ■ k 11h     5-HYDftOXfTftVPT AMINE 15-HT., SEROTONIN)
CH.Cryirl.NH-COCrli
N-ACETYL-
SEFlOTOhilN
<NA$>
CHJ*
jlCHjCH.r|H,NH<flCH,
'J MELATONIN
p I
N
E A L 0
c
Y T
E
Rciease in Blood
Embryonic development epiphysis (c. pineale)
of
thickening of caudal part of ependyma that does not contribute to development of choroid plexus at the roof of diencephalon
neuroectoderm
Prosencephalon
Mesencephalon
Cerebral hemisphi
Pineal evagination
Metencephalon
Myelencephlon
WEEK 4
4 mm (After Hochstetter)
Lamina terminals hypothalami
WEEK 6
(9 mm)
Epithalamus
Corpus callosum
Septum
fhalamus
pcllucidum
Anterior commissure
Hippocampal fissure
Epithalamus
Anterior
commissure \S
Optic chiasma*
Hypothalamus
Infundihulum
Habcnular commissure Pineal
Lamina terminate g hypothalam
Posterior commissure
Optic chiasma
Infundibulum
Pineal body Thalamus
Hypothalamic sulcus Hypothalamus
gr- Mamillary bod;
WEEK 11
65 mm
WEEK 8
25 mm
Thyroid gland (gl. thyroidea)
• Follicular cells —> thyroid hormones (T3, T4)
• C cells —> calcitonin
C.t. capsule, septs Lobes —» lobuli - follicles
5t,usrt£ir
.k. i.-ri::v
Laryni
Follicles (50 u,m -1 mm)
- separated by interstitial loose collagen c.t.
- simple epithelium (flat to cubic, according to p#p$-$$p$ secretory activity)
colloid
Capillary network from thyroid arteries
Thyroid gland - follicles
Thyroid gland - follicles
Follicular cells and C-cells (parafollicular)
Synthesis of T3 and T4
T4 synthesis in thyroid
• sodium-iodide symporter transports two Na+ and one I- across the basement
• I" is moved across the apical membrane into the colloid of the follicle.
• thyroperoxidase oxidises 2 1"—» l2.
• thyroperoxidase iodinates the tyrosyl residues of thyroglobulin
• (TSH) stimulates the endocytosis of the colloidal content
• endocytic vesicles + lysosomes, lysosomal enzymes cleave T4 from the iodinated thyroglobulin
• exocytosis
T3 synthesis from T4
• T4 half-life in blood 6.5 days, T3 2.5 (T4 is a reservoir for T3)
• deiodination by tissue specific deiodinase enzymes generates T3
thyreoglobulin tríiodothyronin T3 tetraiodothyronin (thyroxin) T4
Alternative T3 pathway
C cells of thyroid
Neuroendocrine cells
- pale staining
- epithelial basis, under basal lamina no contact with colloid
- derived from neural crest
- associate with ultimobranchial body, (derivative of the
4th pharyngeal pouch)
Calcitonin
- inhibition of osteoclasts
DEVELOPMENT OF PHARYNGEAL ARCHES
ECTODERM
MESODERM
ENDODERM
Pharyngeal Arch
Pharyngeal cleft: invagination of ectoderm between adjacent arches
Pharyngeal pnuch: invagination of endoderm between adjacent arches
1st cleft forms external auditory meatus
2nd arch extends over 2nd, 3rd and 4th clefts
Remnant of 2nd, 3rd pr4th cleft may persist as a lateral cervical cyst
1st pouch forms Eustachian tube
2nd pouch forms palatine tonsil
3rd pouch forms thymus and inferior parathyroids
4th pouch forms
superior parathyroids
[5th pouch / ultimobranchial body
forms C-cells of the thyroid gland)
© anatomymcqs.com
Thyroid development
p*nihyratd
endodermal proliferation of pharyngeal floor hypobranchial eminence and foramen caecum bilobed civerticulum ductus thyreoglossus
paratryrotrj
■il iTürrjjm
Tl-iyip0cf**lcyil
\**7 ttvymfc
Pyrirnifjat
I'.,iti-1
' / eorfd
ihymtt ttuut
Thymus
Cime«        E«*-pj*>?r    Dwxu***!*!*        *t* E**t*
Parathyroid gland (gl. parathyreoidea)
6 mm, 130 mg
c.t. capsule and septs
Capillary network
Cords and clusters of glandular cells
- Chief
- Oxyphilic
- Adipose
Capsula fibrosa
hlavní buňky oxyfilní buňky tukové buňky
Thyroid gland
Parathyroid glands
Back view
Glandula parathyreoidea - přehled I, (HE), objektiv 2,5*
Parathyroid gland (gl. parathyreoidea)
Chief
- most abundant
- small cells (7-lOu.m, big nucleus
- mildly acidophilic
- PTH - calcium metabolism
Parathyroid Gla
Oxyphylic
- large, polyhedral,
- strongly acidophilic
- round nucleus
- glycogen
Parathyroid gland (gl. parathyreoidea)
Parathyroid hormone (PTH, parathormone, parathyrin)
84 aminoacids
stimulates resorption by osteoclasts
enhances resorption of calcium and magnesium in distal tubules and thick ascending limb
enhances absorption in the intestine (via vD3)
• Jrc/ú.uoi iMUW JomwfcOfl
crdMEyMMM
PTH vs. calcitonin
Calcitonin
Q If calcium level rises above set point
O Blood calcium level rises
© Thyroid gland releases calcitonin
High_
Homeostasis: Blood calcium Level
Low
PTH
0 Parathyroid glands release parathyroid hormone (PTH)
0 Blood calcium level falls
If calcium
level falls below set point
Embryonic development of parathyroid gland
• glandulae parathyroideae superiores from endoderm of 4th pharyngeal pouch
• glandulae parathyroideae inferiores from dorsal process of 3th pharyngeal pouch - together with thymus descend to lower poles of thyroid
• ectopic PTH gland in thymus or mediastinum
Embryonic development of parathyroid gland
DEVELOPMENT OF PHARYNGEAL ARCHES
ECTODERM MESODERM
DODERM
Pharyngeal Arch
1st deft forms external auditory meatus
2nd arch extends rjver2nd, 3rd and 4th clefts
Pharyngeal cleft: invagination of ectoderm between adjacent arches
Pharyngeal pouch: invagination of endoderm between adjacent arches
Remnant of 2nd, 3rd or 4th cleft may persist as a lateral cervical cyst
1st pouch forms Eustachian tube
2nd pouch forms pa latine tonsil
3rd pouch forms thymus and inferior parathyroids
— 4th pouch forms superior parathyroids [5th pouch / ultimo branchial tody '"" forms C-cells of the thyroid gland)
© anatomymcqs.com
Adrenal gland (corpus suprarenale)
capillary plexus
Adrenal development
cortex
- mesoderm
- mesothelium, coelomic epithelium
medulla
- neural crest
Adrenal cortex
Adrenal cortex
• Zona glomerulosa (1/10)
- thin layer under capsule
- relatively small cells in coiled glom
- not abundand lipid droplets
- mineralocorticoids
• Zona fasciculata (6/10)
- radially arranged trabecules
- lipid droplets in cytoplasm
- glucocorticoids
• Zona reticularis (3/10)
- branched trabecules
- small, acidophilic cells
- lipofuscin
- androgen precursors
Adrenal cortex hormones
• Steroids produced incortex = CORTICOSTEROIDS
• Steroidogenic cells
- SER, lipid droplets, mitochondria
- mineralocorticoids
- glucocorticoids
• Aldosteron - zona glomerulosa
• KortisoI -zonafasciculata
• Androgens, estrogens, progesteron - zona reticularis
Adrenal medulla
Clusters of glandular cells in reticular c.t.
- chromaffin cells - modified postganglionic neurons
- ganglionic cells
- capillaries, venules, nerve fibers
- adrenaline and noradrenaline
Neural crest origin
Adrenal vascularisation
capsular
arteriole capsular venule
arteriae suprarenales (3) —> arterial plexus in cortex under c.t. capsule —» radially oriented fenestrated sinusoid capillaries continuous with medullar capillaries —> medullar veins —> v. suprarenalis
three arterial regions
1) c.t. capsule and superior parts of cortex
2) radial capillaries of cortex continuing to medulla
3) medullar capillaries from aa. perforantes
cortical arteriole
c.t. capsule     QJt—I
z. glomerulosa
z. fasciculata
z. reticularis
medulla
medullar artery
capillaries of z. glomerulosa
arteria perforans
capillaries of z. rasciculata
capillaries of z. reticularis
venules of z. reticularis
I  I i i <-t f
Stress
Hypothalamus
Autonomic nerve system
Adrenal medulla Adrenalin*
- blood pressure, vasoconstriction, heart rate...
Pituitary gland
ACTH
Adrenal cortex
rtisol
glycogen lysis
stabilization of glucose levels suppression of immune system
Fight or Flight
Adaptation, regeneration
Langerhans islet of pancreas
Langerhans islets of pancreas
	
V	
	
	
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V  7        Ir) •	
♦	
B-cells producing insulin
Ab-anti insulin-Alexa Fluor
A-cells producing glucagon
Ab-anti glukagon -Texas Red
nkyou for attention