Extracellular Matrix (Biochemistry) 2024 PDF

Summary

This document provides lecture notes on extracellular matrix biochemistry. It covers topics such as ECM structure and function, including fibrous proteins, adhesive glycoproteins, and proteoglycans. It also details the composition of the ECM. The document was created on November 4th, 2024.

Full Transcript

SBM 101:
«Extracellular Matrix»
Prof. Dr. Gül Güner Akdoğan
November 4th, 2024
 PLAN of TALK
General Composition of Extracellular
Matrix (ECM)
Structure and Function of:
1. Fibrillar Proteins
2. Adhesive Glycoproteins
3. Proteoglycans
At the end of this lecture,
students should be able to:
Describe the composition of the ECM
Define the terms: Fibrillar proteins,
Proteoglycans, and Adhesive
Glycoproteins
Explain Collagen Structure, Function, and
Types
Explain Elastin Structure and Elasticity
Compare and contrast elastin and
collagen
Cite the structure-functions of fibronectin
and laminin (adhesive glycoproteins)
Summarize the types of proteoglycans,
structures, and function
 Extracellular Matrix (EM):
The milieu OUTSIDE the CELL
 TERMINOLOGY
ECM(EM) ( Extracellular Matrix):Hücre Dışı Matris
Tensile strength: Gerilme direnci
(resistance to elongation)
Elasticity: Esneklik (Like a rubber band)
Cell adhesion: Hücre yapışması (cells glue together)
Mediate: Aracı olmak, koordine etmek(coordinate)
Adhesive: Yapıştırıcı (act like a glue)
Latent : Gizli (İnaktif) (hidden)
Helix: Helezon (like a spiral)
Regulate: Düzenlemek (control)
Scaffold :Yapısal iskelet (skeleton)
 EM FUNCTIONS
SEM of a
MYOBLAST Provides structural support
secreting EM and elasticity

Provides molecular scaffold
for cell adhesion and migration

Regulates cell differentiation
and functional activitites of
cells
BASIC COMPONENTS OF ECM

Fibrous proteins
Collagen, Elastin
Provide tensile strength and elasticity
Proteoglycans:
Protein-carbohydrate complexes. Give VOLUME…
Support cell adhesion. Bind a several latent growth factors.
Adhesive Proteins:
Fibronectin, Laminin
Mediate cell adhesion
 FIBROUS PROTEINS
Collagen - Elastin
a-Helix or b- structure
Generally polypeptide chains are
parallel to the single axis
Are mechanically strong and contain
high proportion of cross-links
 Collagen Molecules:
Abundant Amino Acids:
Glycine, proline, hydroxyproline
Triple helix (three fibers
interwined together)
Synthesizdd as «procollagen-
tropocollagen»
 Fibril-forming or fibril-associated collagens are «insoluble».
Degraded fragment of XVII, endostatin, inhibits angiogenesis and
hence tumor growth
 Crosslinking of Collagen Fibrils (Outside the Cell)
Deaminated by the enzyme, «lysyl oxidase», to yield aldehyde
groups, spontaneous covalent bonds between aldehyde groups
(about every 67 nm)
Names of cross-links: Lysinonorleucine, Pyridinium (PyD) and
Deoxypyridinium- (dPyd)
If crosslink is broken, collagen is easy to «tear»
 Elastic Fibers
Found throughout the
body- Most prominent
in skin,
aorta,bronchioles
Composed of fibrillin
fibrils and elastin
High synthesis rate in
fetal and juvenile
(young) fibroblasts
Elastic fibers :
ELASTIN
Imparts (gives) elasticity
to the tissue…
Hydrophobic amino
acids are abundant in its
composition
Insoluble protein..
Synthesized as
“proelastin-tropoelastin”
Cross-linked outside the
cell forming
insoluble “elastin”
Elastin

Polypeptide chains :
Composed of alpha
(α) and also beta β
helix

Forms cross-links
with desmosine (Des)
and isodesmosine
(IsoDes)
polyfunctional amino
acids
 ELASTIC FIBERS
Elastic fibers permit long-range deformability and passive* recoil**.
Elastic modulus is ~0.1 MPa.
This function is crucial for arteries, lung, skin and other dynamic
connective tissues that undergo cycles of extension and recoil.
The major component of elastic fibers is the thread-like protein
elastin
Fibrillins provide an outer structure for amorphous, cross-linked
elastin

* Not requiring energy
** Take the original coiled (bobin) shape
Elastin’s Insolubility and Cross-links Allow:

Elasticity of arteries,
lungs, and other
dynamic connective
tissues

With aging, elastin
is degraded and
becomes inflexible
 STOP AND THINK!
Compare and Contrast Collagen and Elastin
FIBROUS PROTEINS
PROTEOGLYCANS
ADHESIVE GLYCOPROTEINS
Proteoglycans are proteins attached to GAGs

GAG’s: Glycosaminoglycans
Modification of the tetrasaccharide
occurs in the ER
 Proteoglycans / GAG’s
Very diverse
Different type of core protein (aggrecan, syndecan)
Different composition of GAGs (chondroitin sulfate,
heparin, heparan sulfate)
Different lengths
GAG’s are posttranslational modifications of a
core protein
Extracellular matrix
proteoglycans
 Hyaluronan is a polysaccharide
25,000 subunits
Made directly outside the cell
Most common
No SO3
Joint fluid, wound healing, development
Source of cell migration
Degraded by hyaluronidase
 Hyaluronates: Chondroitin sulfates: Dermatan sulfate:
composed of D-glucuronate + GlcNAc composed of D-glucuronate composed of D-glucuronic acid
+ GalNAc-6 (or 4)-sulfate (GlcA) or L-iduronate (IdoA) +
GalNAc-sulfate Hetereogenity in
dermatan sulfate results from
varying degrees of O-sulfatation
and from the presene of the two
No need to memorize!!! uronic acids.

Keratan sulfates:
Heparin and Heparan sulfates: composed of galactose + galactose-
composed of D-glucuronate-2-sulfate + N-sulfo-D- 6-sulfate + GlcNAc-6-sulfate
glucosamine-6-sulfate (heparans have less sulfate than
heparins)
Structure of Cartilage Proteoglycan Aggregate
 STOP AND THINK!
Summarize «proteoglycans’ properties»
FIBROUS PROTEINS
PROTEOGLYCANS
ADHESIVE GLYCOPROTEINS
 ADHESIVE GLYCOPROTEINS

Long flexible molecules with domains for binding
Bind ECM to the cells
Bind to:
collagen, proteoglycans, trans-membrane receptors,
cell surface molecules, signaling molecules

Selected Examples: Fibronectin, Laminin
FIBRONECTIN:
a dimer
 Structure of Laminin
(a large heterotrimeric multiadhesive matrix protein found in all basal laminae)
 LAMININ
Co-localisation with Type IV
Collagen, Nidogen, and Perlecan
Binds to basal membrane receptors
Provides binding sites for Type IV
collagen, heparan/heparane sulfate
Model of the «Basal Lamina»
 CONCLUSIONS
ECM, is an outstanding example of “structure-
function relationship” in biology
ECM is NOT an inert file or packing material-it
is a vital, dynamic,regulatory terrain of the body
 SUMMARY OF KEY
CONCEPTS
Extracellular matrix (EM) structure-function
relationshps
Collagen (Col)
Elastin
Proteoglycans
Glycoproteins (Ex: Fibronectin, Laminin)
Basal Lamina- Basement membrane
 REFERENCES
PISCINGER,A. The Extracellular Matrix and Ground Regulation. North
Atlantic Books, Berkeley, California,2004
AHMED N, DAWSON M, SMITH C & WOOD, E. Biology of
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NAGASE, H, VISSE R & MURPHY G. Structure and function of matrix
metalloproteinases and TIMPs. Cardiovascular Research 2006; 69: 562-
573.
STAMENKOVIC I. Extracellular matrix remodelling: the role of matrix
metalloproteinases. Journal of Pathology 2003;200:448-464.
CHIRCO R, LIU XW, JUNG K-K & CHOI KIM HR. Novel functions of
TIMPs in cell signaling. Cancer Metastasis Rev 2006; 25:99-113.
JIANG Y, GOLDBERG ID & SHI YE. Complex roles of tissue inhibitors of
metalloproteinases in cancer. Oncogene 2002; 21: 2245-2252.
ROYCE PM, STEINMANN B (Eds). Connective Tissue and its Heritable
Disorders:Molecular, Genetic, and Medical Aspects. Wiley-Liss,New-York,
1993.
STREULI CH, GRANT ME (Ed). Extracellular Matrix Protocols, Humana
Press,Totowa, New Jersey, 2000
Thank-you……