Department of Histology
and Embryology,
Faculty of Medicine MU
pvanhara@med.muni.cz
Tissue concept
and classification
Petr Vaňhara, PhD
FOUNDING FATHERS OF HISTOLOGY − DISCOVERY OF CELLS
1665
Robert Hooke
Anthony van Leeuwenhoek
ESSENTIAL TECHNOLOGY
• nálevníci
• orální bakterie (Selenomonády)
• spermatozoa
• krvinky
• svalová vlákna
• histologická barvení
1674-1683
„I see different structures in hunan body. I do not need a
microscope to distinguish 21 types! I will call them tissues.
In a diseased body the tissues have altered, abnormal
structure!
FOUNDING FATHERS OF HISTOLOGY − TISSUES
So different
tissues!
Xavier Bichat, 1799
Theodor Schwann
Cells are the
basic units of
any organism
▪ New cells origin only from other cells
▪ Cells exchange energy (open
thermodynamic system)
▪ Genetic information is inherited in
new generations
▪ Chemical and structural composition of
cells is generally identical
FOUNDING FATHERS OF HISTOLOGY − MODERN CELL TEHORY
Matthias Jacob Schleiden
J.E.P.
Omnis cellula
e cellula!
Rudolf Wirchow Robert Remak
Cells are the
basic units of
any organism
CELL AND TISSUE VARIABILITY IN A MULTICELLULAR BODY
- 6  1013 CELLS of 200 different types
- cells form functional, three-dimensional, organized aggregations of
morphologically similar cells and their products and derivatives - TISSUES
- tissues constitute ORGANS and organ systems
Myocardium
TISSUES AND ORGANS
Parenchyma: functional component of a tissue
(liver, lung, pancreatic, kidney parenchyma)
Stroma: surrounding, essential supportive tissue
Parenchyma
Stroma
Example:
LIVER
Parenchyma:
- Hepatocytes
- Sinusoids and adjacent
structures
Stroma:
- Connective tissue and
adjacent structures
- Vessels
- Nerves
- Bile ducts
TISSUES AND ORGANS
Epithelium
Muscle
Nerve
Connective
Based on morphology and function:
Myofibrils → contraction
Mesoderm – skeletal muscle, myocard, mesenchyme
– smooth muscles
Rarely ectoderm (eg. m. sphincter a m. dilatator pupillae)
Neurons and neuroglia
Reception and transmission of electric signals
Ectoderm, rarely mesoderm (microglia)
Dominant extracellular matrix
Connective tissue, cartilage, bone…
Mesenchyme
Continual, avascular layers of cells with different
function, oriented to open space, with specific
junctions and minimum of ECM and intercellular
space.
Derivates of all three germ layers
CONTEMPORARY TISSUE CLASSIFICATION
▪ classical histological definition is based on microscopic visualization
Functional, three-dimensional, organized aggregation of morphologically
similar cells, their products and derivatives
TISSUE DEFINITION
What is a tissue?
Proliferation
Differentation
Migration
Apoptosis
Tissue patterns
BASIC PRINCIPLES OF HISTOGENESIS
How to build a tissue?
?
Knoblich JA. Asymmetric cell division during animal development. 2001. Nat Rev Mol Cell Biol
Differentiation
Self-renewal
Stem cells are capable of differentiation and self-renewal
Asymmetric division
Proliferation
Formation of functional types
FUNCTIONAL CELL TYPES DIFFERENTIATE FROM STEM CELLS
Stem cells are essential
STEM CELLS DIFFERENTIATION
Totipotent
- Constitute all cells of the body incl. extraembryonic tissues
- Zygote and early stages
Pluripotent
- All cells in the body except for trophoblast
- Blastocyst – Inner cell mass - ICM (embryoblast)
- Embryonic stem cells
Multipotent
- Give rise to various cell types of a particular tissue
- Mesenchymal SC, hematopoietic SC
http://www.embryology.ch/anglais/evorimplantation/furchung01.html
Oligo- a unipotent
- One or several cell types – hematopoietic, tissue precursors for renewal
of intestinal epithelia, etc.
STEM CELLS
Tissue (adult) stem cells
- regeneration and renewal of tissue
- GIT, CNS, mesenchymal tissues
- regenerative medicine, cancer biology
Embryonic stem cells (ESCs)
- derived from embryoblast (ICM) of preimplantation
blastocyst
- pluripotent
- model of early embryogenesis and histogenesis,
regenerative medicine
STEM CELLS IN ORGANISM
H. Clevers
J. Thompson
Induced pluripotent stem cells (iPSc)
- adult differentiated cell (fibroblast) is reprogrammed into pluripotent state
- differentiation into desired cell type
- regenerative medicine, cell and gene therapy
Nobel prize 2012
Disease modelling
Drug testing
Tissue replacement
…
STEM CELLS AS RESEARCH TOOLS
hESCs
hiPSCs
iPSCs SHARE FUNDAMENTAL PROPERTIES WITH hESCs
Age-related macular degeneration
neovascularisation
Clinical trial
hiPSCs Retinal pigment epithelium
STEM CELLS AS THERAPY
Cancer stem cells
- solid tumor is always heterogeneous
- small population of cells with stem cell character can
repopulate tumor tissue after cytotoxic therapy
Tissue stem cells
Renewal
Low frequency
(<1%)
Quiescence
Multipotency
Long life
Resistence
Tumorigenicity
Proliferation
capacity
Cancer stem cells
STEM CELLS AS FOES
• Induction of differentiation
• Terminal differentiation
• Determination and commitment
-blast
-cyte
eg. myeloblast
e.g. granulocyte
CELL DIFFERENTIATION
Essential terminology
doi:10.1038/nrg3209
DIFFERENTIATION IS DRIVEN BY GENE TRANSCRIPTION
Essential mechanisms 1
doi:10.1038/nature10523
TISSUE DIFFER IN THEIR GENETIC AND EPIGENETIC PROFILES
Adhesion
molecules
Growth factors
ECM components
Cell interactions
Metabolites
Immunity
Inflammation
CELLS CAN CREATE UNIQUE MICROENVIRONMENT
Essential mechanisms 2
• Embryonic development
• Intercellular interaction
• Space organization (dimensionality)
• Gradient of morphogenes
• Epigenetic profile
• Gene expression dynamics
• Partial pressure of gases
• ECM composition
• Mechanical stimulation
• Perfusion and interstitial flows
• Local immunity response
• Metabolites
Huge number of biological and physically-chemical parameters
MICROENVIRONMENT REGULATES TISSUE FUNCTION
STEM CELL NICHE
HEMATOPOIETIC NICHE
Apoptóza
Regenerace
Senescence
Patologická
změna
MICROENVIRONMENT IS NECESSARY FOR TISSUE HOMEOSTASIS
Apoptosis
Regeneration
Senescence
Transformation
MICROENVIRONMENT IS NECESSARY FOR TISSUE HOMEOSTASIS
MICROENVIRONMENT MIGHT BE CLINICALLY IMPORTANT
MICROENVIRONMENT IS IMPORTANT FOR PATHOGENESIS
https://www.pathologyoutlines.com/topic/livercirrhosis.html
Fibrotic
Infections
Metabolic disorders
Autoimmune disorders
Cholestasis
Alcohol
Genetics
Abnormal tissue microenvironemnt
Healthy
Normal tissue microenvironment
Example: liver
Stroma Parenchyma
Stroma
Parenchyma
Loss of functional parenchyma
Deposition of ECM
Activation of (myo)fibroblasts)
Dysplasia
Inflammation
GENERAL TISSUE COMPOSITION
ECM Signaling moleculesCells+ +
Tissue =
MOLECULAR PRINCIPLES OF HISTOGENESIS
Essential mechanisms 3
LEWIS WOLPERT’S FRENCH FLAG MODEL
Expression patterns of gap and pairrule
genes in Drosophila embryos.
DOI: 10.1007/s10577-006-1068-z
Eric Francis Wieschaus is an American evolutionary
developmental biologist and 1995 Nobel Prize-winner.
Three short lectures on embryonic patterning
DROSOPHILA Eric Wieschaus
WHY DO TIGERS HAVE STRIPES?
Reaction–diffusion system
TISSUE PATTERNS ARE DRIVEN BY GRADIENTS OF MORPHOGENES
Belousov-Zabotinsky
doi:10.1038/sj.hdy.6800872
Hox genes
Highly conserved family of transcription
regulators that determine body polarity,
orientation and axis
Tissue differentiation along anterioposterior
axis
Human (39 genes)
Cluster Chromosome # Hox genes
HoxA 7 11
HoxB 17 10
HoxC 12 9
HoxD 2 9
HOX COMPLEX
TEMPORO-SPATIAL EXPRESSSION OF MORPHOGENES DRIVES FINAL
LOCALIZATION, ORIENTATION AND MORPHOLOGY OF TISSUES AND ORGANS
MANIPULATING AER ALTERS INSTRUCTIONS FOR LIMB DEVELOPMENT
MORPHOGENES FROM AER AND ZPA DEFINES LIMB FORMATION
http://courses.biology.utah.edu/bastiani/3230/DB%20Lecture/Lectures/b14Limb.html
HOX PATTERN DRIVES TRANSCRIPTIONAL RESPONSE
HOX
Vascularisation
Fgf
Shh
…
Proliferation
Thalidomid
STORY OF THALIDOMID
Thalidomid embryopathy
• phocomelia
• amelia
• anophtalmia/microphtalmia
• abnormal kidneys, heart, GIT, genitalia
Frances Oldham Kelsey,
FDA USA
Ectoderm
MesodermEndoderm
Trilaminar germ disc
(3rd week)
HISTOGENESIS AND ORGANOGENESIS
▪ Connective tissue of head
▪ Cranium, dentin
▪ Skeletal muscle of trunk and limbs
except cranium
▪ Dermis of skin
▪ Muscles of head
▪ Urogenital system + ducts, glands
and gonads
▪ Visceral muscle and connective
tissue
▪ Serous membranes of pleura,
peritoneum and pericardium
▪ Blood cells, leukocytes
▪ Cardiovascular and lymphatic system
▪ Spleen
▪ Adrenal cortex
▪ GIT epithelium except oral cavity and
part of anal canal
▪ Extramural glands of GIT
▪ Epithelium of bladder
▪ Epithelium of respiratory system
▪ Thyroid gland, parathyroid glands,
thymus
▪ Tonsils
▪ Epithelium of cavum tympani and
Eustachian tube
▪ Epidermis, hair nails, cutaneous and
mammary glands
▪ Corneal epithelium and lens of eye
▪ Enamel of teeth
▪ Internal ear
▪ Anterior pituitary gland
▪ Epithelium of oral cavity and part of anal
canal
▪ Neural tube and derivatives
- CNS
- Retina
- Posterior pituitary gland
- Pineal body
▪ Neural crest and derivatives:
- Cranial and sensory ganglia and nerves
- Schwann cells
- adrenal medulla
- Enteroendocrinne cells
- Melanocytes
- Head mesenchyme and connective tissue
- Odontoblasts
SurfaceectodermNeuroectoderm
headParaxialIntermediateLateral
EndodermEctoderm Mesoderm
EMBRYONIC DEVELOPMENT
CONNECTIVE TISSUE
Not just a tissue glue…
Mechanical and biological properties
→ surrounds other tissues, allows compartmentalization, provides support, defines physicochemical
environment, brings immunological support, provides storage of energy, ...
CONNECTIVE TISSUE
Extracellular matrix
• Fibrous component
‒ collagen fibers (prototypically col. I, II)
‒ reticular
‒ elastic
• Amorphous component (amorphous ground substance)
Complex matrix consisting of
‒ glycosaminoglycans
‒ glycoproteins
‒ proteoglycans
Specific composition dependens on a tissue type (connective  ligament  cartilage  bone)
Cells
• Connective tissue – permanent and transient cell populations (e.g.
fibroblasts/myofibroblasts, immune cells, adipocytes, adult stem cells)
• Cartilage – chondroblasts/chondrocytes
• Bone – osteoblasts/osteocytes/osteoclasts
GENERAL COMPOSITION OF CONNECTIVE TISSUE
CLASSSIFICATION OF CONNECTIVE TISSUE
Collagen Structure Function and distribution
Loose collagen CT
Abundant ground substance, few collagen
fibers with random arrangement
Microvascularisation
Innervation
Irregular dense collagen CT
Few ground substance, few cells, many
collagen fibers, random arrangement
Mechanically resistant organ capsules
Regular dense collagen CT
Tightly arranged collagen fibers with
fibroblasts intercalated between them
Part of musculoskeletal system.
Tendons, ligaments
Embryonic
Mesenchyme
Undifferentiated cells uniformly dispersed in
ground substance, few collagen fibers
Undifferentiated progenitors
Wharton’s jelly
Viscous amorphous matrix with collagen
fibers. ECM-producing stromal cells with MSC
properties.
Matrix of umbilical cord
Special
Reticular CT Network of collagen III fibers and reticular cells
Support of hematopoietic and lymphatic
cells
Elastic Rich in elastic fibers
Lig. flava, lig. vocale. Lung interstitium,
flexible support to elastic arteries and
aorta
Adipose Adipocytes
Energy storage (white fat), heat
production (brown fat)
Cartilage Chondroblasts, chondrocytes Mechanical support
Bone Osteoblasts, ostecoytes, osteoclasts
Mechanical support, calcium and
phospate metabolism
Blood See lecture on blood & hematopoiesis this semester
- Fibroblasts/fibrocytes/myofibroblasts
- Heparinocytes
- Macrophages of CT = histiocytes
- Plasma cells
- Lymphocytes
- Adipocytes
- Adult stem cells
Extracelular matrix
- Fibrous
- Amorphous ground substance
Cells
• Permanent
• Migratory
- CT Macrophages = histiocytes
- Plasma cells
- Lymphocytes, granulocytes
- Heparinocytes
- …
GENERAL COMPOSITION OF CONNECTIVE TISSUE PROPER
+
• Mesenchymal stem cells differentiate to many cells of CT
GENERAL COMPOSITION OF CONNECTIVE TISSUE PROPER
• Mesenchymal stem cells are important for tissue engineering
GENERAL COMPOSITION OF CONNECTIVE TISSUE PROPER
FIBROBLAST
https://www.sciencephoto.com/media/1232046/view/fibroblast-tem
ECM
ECM of connective tissue is produced by fibroblasts (chondrocytes, osteoblasts).
However, specific ECM can be produced by any cell of our body (eg. epithelial and muscle cells producing
basal lamina).
ECM composition determines tissue properties
Collagen fibers
- family of fibrous proteins encoded by >35 genes (2013)
- polymer – subunit = tropocollagen; triple helix
- different structural and mechanical properties (strength, elasticity, pliability…)
- most abundant protein in human body ( 30% dry weight)
EXTRACELLULAR MATRIX – FIBROUS COMPONENT
• Polyribosomes bind to RER and synthetise peptide chains 1 a 2 (~250 AA, 28kDa)
• In RER peptide chains are modified (hydroxylation of proline and lysine – co-factor vitamin C)
Chains assemble into triple helix - procollagen
• In GA, procollagen is further modified and secreted from cells
COLLAGEN
COLLAGEN
further study: https://www.ncbi.nlm.nih.gov/books/NBK507709/
Procollagen is then modified to tropocollagen (by procollagenpeptidase)
Tropocollagen is organized to higher fibrillar structures in ECM (fibrils, fibers)
Individual collagen molecules are connected (lysyloxidases)
COLLAGEN
Type Localization Structure Main function
I
Bone, tendons, meniscus, dentin, dermis,
capsules of organs, loose CT 90% of type I
Fibrils (75nm) – fibers
(1-20m)
Resilience in pull
II
Hyaline and elastic cartilage Fibrils (20nm) Resilience in pressure
III
Skin, veins, smooth muscles, uterus, liver,
spleen, kidney, lung
Like I, high content of
proteoglycans and
glycoprotiens, reticular
network
Shape formation
IV
Basal lamina of epithelium and endtohelium,
basal membranes
No fibrils or fibers Mechanical support
V
Lamina of muscle cells and adipocytes, fetal
membranes
Like IV
VI
Interstitial tissue, chondrocytes – adhesion Connecting dermis and
epidermis
VII Basal membrane of epithelium
VIII Some endothelia (Cornea)
IX, X
Growth plate, hypertrophic and mineralized
cartilage
Growth of bones,
mineralization
COLLAGEN
AZAN
HES
HE
COLLAGEN IN LIGHT MICROSCOPE
Julian Voss-Andreae
"Unraveling Collagen"
2005
Orange Memorial Park
Sculpture Garden, City of
South San Francisco, CA
COLLAGEN IN ART
• less abundant than collagen
• polymer – tropoelastin
• minimal tensile resistance, loss of elasticity if overstretched
• reduction of hysteresis = allow return back to original state after mechanic change
ELASTIC FIBERS
ELASTIC FIBERS
Elastic fibers
Elastin Collagen
ELASTIC FIBERS
Elastic fibers
• Similarly to collagen, elastin precursors are secreted and polymerize
• Deposition of elastin aggregate along fibers of protein fibrillin
• Amount of fibrillin (nonelastic) and elastin (elastic) determines elasticity of CT
Fibrillin
Elastin
Elastin
• collagen 3D meshwork
• bone marrow, spleen, lymphatic nodules
• microenvironment for e.g. hematopoietic stem cells and progenitors
RETICULAR FIBERS
RETICULAR CONNECTIVE TISSUE
Amorphous extracellular matrix
Colorless, transparent, homogenous substance consisting of glycosaminglycans,
proteoglycans and structural glycoproteins
EXTRACELLULAR MATRIX – GROUND SUBSTANCE
linear polysaccharides composed of two disaccharide subunits
– uronic acid and hexosamine
glucosamin or galactosamin
glucuronic or iduronic acid
polysaccharides rich in hexosamines = acid mukopolysaccharides
GLYCOSAMINOGLYCANS
• lineární polysacharidy tvořené disacharidovými podjednotkami - kyselinou
uronovou a hexosaminem
GYLCOSAMINOGLYCANS
https://doi.org/10.3390/cancers15010266
Glycosaminoglycan Localization
Hyaluronic acid Umbilical cord, synovial fluid, fluid of corpus vitreum,
cartilage
Chondroitinsulphate Cartilage, bone, cornea, skin, notochord, aorta
Dermatansulphate Skin, ligaments, adventitia of aorta
Heparansulphate Aorta, lungs, liver, basal membranes
Keratansulphate Iris, cartilage, nucleus pulposus, anulus fibrosus
They bind to protein structures (except for hyaluronic acid)
GLYCOSAMINOGLYCANS
— protein + dominant linear saccharide
component
— proteoglycan aggregates
— water-binding, volume dependent of
hydratation
— aggrecan (cartilage)
— syndecan
— fibroglycan
PROTEOGLYCANS
• dominant protein + branched saccharide component
• interaction between cells and ECM
― fibronectin – connects collagen fibers and
glykosaminoglycans, cell adhesion and
migration
― laminin – basal lamina – epithelial integrity
― chondronectin – cartilage – adhesion of
chondrocytes to collagen
(J. Nutr. 136:2123-2126, 2006)
STRUCTURAL GLYCOPROTEINS
Glycoproteins vs. proteoglycans
STRUCTURAL GLYCOPROTEINS
COMPOSITION OF ECM
ECM – SUMMARY
- Embryonic mesenchyme and Wharton’s jelly of umbilical cord
- Areolar (loose collagen, interstitial) CT
- Dense collagen regular/irregular CT
- Elastic CT
- Reticular CT
HISTOLOGICAL CLASSIFICATION OF CT PROPER
Embryonic mesenchyme Wharton’s jelly
LOOSE COLLAGEN CT
• Permanent fibroblasts, macrophages (histiocytes),
occasionally adipocytes
• Other transient cell types (leukocytes)
• Collagen and elastic fibers
• Amorphous ground substance is dominant
• Most abundant type of CT
• Rich vascularization and innervation
• Walls of hollow organs, interstitium, mucosal and
submucosal CT
http://medsci.indiana.edu/a215/virtualscope/docs/chap2_1.htm
DENSE COLLAGEN CT
• Adipocytes, fibroblasts, reticular, collagen and elastic fibers, capillaries
• White and brown adipose tissue
ADIPOSE TISSUE
• adipocytes are actively formed until 2nd year of life
• no innervations, but rich vascularisation
• adipocytes with only one lipid droplet
• leptin (adipokinins)
WHITE ADIPOSE TISSUE
• fetus and children up to 1st year of life
• fast source of energy
• typical localization – between shoulder
blades, axilla, mediastinum, around
kidneys, pancreas, small intestine
• small cells with numerous fat droplets
BROWN ADIPOSE TISSUE
• Mesenchyme = loose tissue between germ layers
• Complex network of star- or spindle-shaped cells
• Jelly-like amorphous ground substance
http://www.mun.ca/biology/desmid/brian/BIOL3530/DB_Ch02/DBNModel.html
DAY 12 of embryonic development
EMBRYONIC ORIGIN OF CONNECTIVE TISSUE
Connective BoneCartilage
Mesenchyme
DERIVATIVES OF MESENCHYME
DERIVATIVES OF MESENCHYME
MESENCHYMAL STEM CELLS
DOI: 10.3389/fsurg.2015.00001
APPLICATIONS OF MESENCHYMAL STEM CELLS
https://doi.org/10.3389/fbioe.2020.00043
FURTHER STUDY
http://www.histology.med.muni.cz
Thank you for attention
pvanhara@med.muni.cz