Biochemistry Fibrous Proteins PDF
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University of Northern Philippines
Dr. Jandoc
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Summary
This document details fibrous proteins, specifically the structures, biosynthesis, and degradation of collagen and elastin. It covers topics such as the different types of collagen, and their functions in various tissues.
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1A BIOCHEMISTRY FIBROUS PROTEINS DR. JANDOC OUTLINE I. COLLAGEN A. Types of collagen a. Fibril-f...
1A BIOCHEMISTRY FIBROUS PROTEINS DR. JANDOC OUTLINE I. COLLAGEN A. Types of collagen a. Fibril-forming collagens b. Network forming collagen c. Fibril-associated collagens B. Structure of collagen a. Amino acid sequence b. Triple-helical structure c. Hydroxyproline and hydroxylysine A. TYPES OF COLLAGEN d. Glycosylation More than 25 types C. Biosynthesis of collagen 3 polypeptide α-chains held together by hydrogen bonds a. Formation of pro-α chains Type I = 2 α1 and 1 α2 b. Hydroxylation Type II = 3 α1 c. Glycosylation Three groups: based on location and functions in the body d. Assembly and secretion FIBRIL-FORMING COLLAGENS e. Extracellular cleavage of procollagen Types I, II, and III molecules Type I f. Formation of collagen fibrils supporting elements of high tensile strength g. Cross-link formation tendon and cornea D. Degradation of collagen Type II E. Collagen diseases: Collagenopathies Cartilaginous structures a. Ehlers-Danlos syndrome Type III b. Osteogenesis imperfecta II. ELASTIN Distensible tissues such as blood vessels A. Structure of elastin In electron microscope B. Role of α1-antitrypsin in elastin degradation Characteristic banding pattern a. α1-antitrypsin Regular staggered packing of the individual b. Role of α1-AT in the lungs molecules in the fibril c. Emphysema resulting from α1-AT deficiency I. COLLAGEN Most abundant protein in the body Long, rigid structure 3 polypeptides form a helix Dispersed as gel Extracellular matrix, vitreous humor of the eye NETWORK-FORMING COLLAGENS Tight bundle Types IV and VII Tendons Type IV Parallel fibers that provide great strength Major part of basement membrane Stacked Mechanical support for adjacent cells Cornea of the eye Semipermeable filtration barrier (lungs and To transmit light with a minimum scattering kidney) At an angle Form a 3-dimensional mesh rather than fibrils Bone FIBRIL-ASSOCIATED COLLAGENS Resist mechanical shear from any direction Types IX and XII bind to the surface of fibrils Component of the extracellular matrix Trans 1 | Raff 1 of 5 BIOCHEMISTRY GLOBULAR PROTEIN B. STRUCTURE OF COLLAGEN Amino acid sequence Glycosylation Rich in proline and glycine Enzymatic glycosylation of the hydroxyl group of Proline hydroxylysine Facilitate formation of helix = ring kink Most commonly glucose and galactose Glycine Found in every third position of the polypeptide C. BIOSYNTHESIS OF COLLAGEN chain Precursors are performed in the fibroblasts Repeating sequence Osteoblasts of bone - Gly – X – Y - Chondroblasts of cartilage X = proline Formation of pro-α chains Y = hydroxyproline (or hydroxylysine) Prepro-α chains contain specific AA sequence at their N- terminal ends Acts as SIGNAL that targets the polypeptide being synthesized for secretion from the cell Facilitate binding of ribosomes to the rER Direct the passage of the prepro-α chain into the rER lumen Rapidly cleaved in the rER to yield a pro-α chain Triple-helical structure Hydroxylation Fibrous and elongated - Gly – X – Y – AA side chains on its surface Proline and lysine in the Y position can be hydroxylated Bond formation between the R-groups of REQUIREMENTS: neighboring collagen monomers Hydroxylating enzymes Results in aggregation Prolyl hydroxylase Hydroxyproline and Hydroxylysine Lysyl hydroxylase Not present in most proteins Oxygen Hydroxylation of proline and lysine Ferrous form of Iron Posttranslational modification Hydroxyproline Reducing agent (Vitamin C) Important in stabilizing the triple-helical structure Ascorbic acid deficiency (SCURVY) Maximizes interchain hydrogen bond formation Lack of prolyl and lysyl hydroxylation Impaired interchain H-bond formation and formation of a stable helix Collagen fibrils do not crosslink Decrease tensile strength often show bruises subcutaneous extravasation of blood due to capillary fragility Glycosylation Modify hydroxylysine with glucose or glucosyl-galactose RAFF 2 of 5 BIOCHEMISTRY GLOBULAR PROTEIN Assembly and secretion D. DEGRADATION OF COLLAGEN After hydroxylation and glycosylation Normal collagens Pro-α chains form procollagen Highly stable Central region flanked by nonhelical AA and Half-life = as long as several years carboxyterminal extensions called PROPEPTIDES Dynamic and constantly remodelled in response to growth Begins with interchain disulfide bond formation or injury of tissue between C-terminal of the pro-α chain Proteolytic enzymes (COLLAGENASES) Move to Golgi complex, packaged in secretory Breakdown of collagen vesicles, fuse with cell membrane releasing it to the Metalloproteinase family extracellular space Type I collagen Extracellular cleavage of procollagen molecules Breakage point is specific Procollagen molecules are cleaved by N- and C- ¾ + ¼ length fragments procollagen peptidases Further degraded into AA by Remove terminal propeptidases, releasing triple- PROTEINASES helical tropocollagen molecules E. COLLAGEN DISEASES: Collagenopathies Formation of collagen fibrils Ehlers-Danlos syndrome Tropocollagen associate to form fibrils Generalized CT disorder Ordered, overlapping, parallel array Result from inheritable defects in the metabolism of Adjacent molecules in staggered pattern fibrillar collagen molecules Overlapping to approximately ¾ of a another Deficiency of collagen-processing enzymes molecule Lysyl hydroxylase, procollagen peptidase Cross-link formation Mutation in the AA sequence of Types I, III, or V Lysyl oxidase Type I = skin Act on fibrillar array of collagen Fragile, stretchy akin and loose joints Oxidatively deaminate the lysyl or hydroxylysyl Type III = most clinically important (in blood vessels) residues in neighboring collagen to form Either degraded of accumulated to high levels in covalent cross-links intracellular compartments Cu 2+ containing enzyme Potentially lethal vascular problems Cytochrome oxidase Osteogenesis Imperfecta Dopamine hydroxylase Brittle Bone syndrome Superoxide dismutase Retarded wound healing X-linked (Menkes disease) – Cu Humped-back (kyphotic) appearance deficiency Rotated and twisted spine Wilson Disease – Cu overload TYPE I Osteogenesis imperfect tarda Decreased α1 and α2 chain production Present early in infancy Fractures secondary to minor trauma Suspected if prenatal ultrasound detects bowing or fractures of long bones TYPE II Osteogenesis imperfect congenital Most severe Die of pulmonary hypoplasia in utero or during neonatal period Mutation in pro-α1 and pro-α2 chains of type I collagen Replacement of Gly by AA with bulky side chains Prevent formation of the required triple-helix II. ELASTIN Rubber-like properties Elastic fibers with elastin and glycoprotein microfibrils Lungs, walls of large arteries, elastic ligaments Stretchable recoil to original shape A. STRUCTURE OF ELASTIN Insoluble protein polymer Synthesized from tropoelastin = linear polypeptide (700 AA) RAFF 3 of 5 BIOCHEMISTRY GLOBULAR PROTEIN Small and nonpolar (glycine, alanine, valine) Role of α1-AT in the lungs Also rich in proline and lysine but little hydroxylysine and Normal hydroxyproline Alveoli is exposed to low levels of elastase (from TROPOELASTIN activated and degenerating neutrophils) Secreted by the cell into the extracellular space Destroy Elastin in alveoli if unopposed by α1-AT Interacts with glycoprotein microfibrils Emphysema FIBRILLIN Lung tissue cannot regenerate Act as scaffold where tropoelastin is deposited Destruction of CT of alveolar walls Allysine residue Emphysema resulting from α1-AT deficiency Oxidative deamination of lysyl side chain by α1-antitrypsin mutation lysyl oxidase single purine base mutation (GAG AAG) ELASTIN position 342 = Glutamate Lysine 3 allysine side chain + 1 unaltered lysyl side chain from undergo polymerization in hepatocyte ER same or neighboring polypeptides form a desmosine cross- decreased α1-AT secretion link INHERITANCE Extensively interconnected, rubbery network Heterozygote Give tissue its elasticity Sufficient protection of alveoli from damage Homozygote Promote emphysema α1-antitrypsin methionine required for the binding of the inhibitor to target the protease inactivation via inhalational trauma Smoking Causes oxidation methionine residue inactivation no neutralization of elastase Elevated rate of lung destruction poorer survival rate Treatment Augmentation therapy Weekly intravenous α1-AT administration Mutation in fibrillin-1 protein Marfan syndrome CT disorder impaired structural integrity of skeleton, eye and cardiovascular system abnormal fibrillin incorporated into microfibrils BLUE SCLERA Due to tissue thinning Patients with OI, EDS or Marfan B. ROLE OF α1-ANTITRYPSIN IN ELASTIN DEGRADATION α1-antitrypsin A1AT, α1-antiproteinase Inhibit proteolytic enzymes that hydrolyze and destroy proteins Inhibits activity of the trypsin Synthesized as trypsinogen in the pancreas 90% of the α1-globulin Synthesized by the liver, some in tissues including monocytes and alveolar macrophages Physiologic role of inhibiting neutrophil elastase Degrade elastin of alveolar walls, as well as other structural protein Prevent local tissue injury RAFF 4 of 5 BIOCHEMISTRY GLOBULAR PROTEIN II. ALPHA-KERATINS Proteins that form TOUGH FIBERS Hair, nail, outer epidermal layer Constituent of intermediate filament Rich in cysteine Provide disulfide bond Insoluble and resistant to stretching RAFF 5 of 5