BIOCHEMISTRY TRANS - FIBROUS PROTEIN.pdf

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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

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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

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 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)

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 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

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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

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