Pintar - ECM Flashcards
Stroma
Group of strands that make up the ECM
3 regions of the basement membrane
- lamina rara, lucida, or interna - top layer made up of laminin 5 and type XVII collagen - made by epithelium
- lamina densa - more dense middle layer made up of laminin 1 and type IV collagen - made by epithelium
- lamina reticularis - bottom layer made up of fibroblasts and type III collagen - made by underlying connective tissue cells such as fibroblasts
Collagen
Very abundant protein in the body. Often three helixes are wrapped around each other to make a triple helix rope. The structure of each helix is generally Gly-X-Y. This is good because Gly just has a H atom as it’s R group so it can be shoved between the two other groups. Often the X and Y are proline and lysine, which can be hydroxylated - help for H bond formation (strong structure but very sensitive to mutations).
types of 1)fibril forming
I-bones, skin, tendons, ligaments
II-cartlidge, invertebral disc
III-skin, blood vessels, internal organs, can bind silver only due to increased carbohydrate
V
Biosynthesis of fibril forming collagens
Collagen ends up outside the cell. Therefore they will begin their synthesis in the cytoplasm. N-terminus will bind SRP. It will be delivered to the ER and be delivered to the cell. 1) There are extension peptides that are part of the primary structure of collagen. They don’t allow for self-assembly into a higher order structure within the ER and golgi. 2) The actual parts of the chains (non-extension part) then get hydroxylated using Vitamin C as a cofactor (that is why sailors got scurvy). Deficiencies of Vitamin C does not allow for collagen to be turned over so you lack strong collagen and teeth fall out. 3) Then the hydroxyl groups are glycosylated. 4) Then the triple helix forms still with the extension peptides and it is excreted from the cell as “procollagen.” 5) The extension peptides will then be cleaved and our new molecule is “tropocollagen” which is a fibril.
2) fibril associated
these collagens decorate the outside of fibril fibers. An example is Type IX collagen which decorates the outside of Type II collagen. In type II collagen, the extension peptides are usually retained and the helix is a little less rigid. If mutated can lead to epiphyseal dysplasia, which leads to arthritis.
3) Network forming collagen
Major collagen of the basal lamina. Extension peptides are not cleaved. Because the N termini will go above and below the plane, it will create some sort of meshwork that looks like a “chicken-wire” array.
Type VII and Type XVII
- Type VII is another network forming collagen. They are made up of monomers. The monomers from the Type VII collagen interact to make a dimer. The dimers interact between the stroma and the lamina densa and they basically keep the stroma stuck to the lamina densa. If a mutation in this, both the lamina densa and the epithelial cells will be pealed away.
- Type XVII helps bind the lamina densa to the epithelial cells. Mutation in this will cause a blistering disease where the epithelium will peel away but the basement membrane will stay intact.
elastin
cross-links with each other. Assembles extra-cellularly. Stretches much like a rubber band. Tissues that require a lot of elasticity are generally high in elastin fiber content. Can be interspersed with collagen fibers.
Marfan Syndrome
Mutation in the fibrillin gene. Causes an overgrowth and lengthening in the limbs. Often have long appendages. Aorta tends to be distended and has a possibility of rupturing. Abe Lincoln was though to have this.
Glycosaminoglycans
- 3 types
Made up of sugar molecules. Repeating dissacharrides of uronic acid and an amino sugar. At physiological pH the carboxyl group is negatively charged. Because of this the sugar molecules spread out as far as they can so they are generally long fibers. They attract water. A major component of synovial fluid and vitreous humor in the eye.
- Hyaluronic acid - not sulfated, not attached to protein
- Chondroitin sulfate and Heparan sulfate - both sulfated and attached to proteins
Aggrecan
A complex proteoglycan made up of Type II and Type IX collagen. It is an example of a sulfated glycosaminoglycan that is attached to protein. It is found in the cartilage. It is attached, non-covalently to a molecule of hyalouronic acid. Provides mechanical support.
Syndecans
Has transmembrane domain. Has heparan sulfate (glycosaminosulfate) attached to the core protein. A mechanism in which the outside of the cell can communicate with the inside of the cell using the sugar chains. Can also bind growth factors and present to receptor.
Adhesive glycoproteins
Laminin and Fibronectin
Basically have modular binding domains on their chains so that parts of the ECM can bind.
Mediate attachment between cells to their outside environment
perlecan
proteoglycan found with type IV collagen and laminin in the basementt membrane.
