Collagen hydroxylysine

FIGURE 6.20 A disaccharide of galactose and glucose is covalently linked to the 5-hydroxyl group of hydroxylysines in collagen by the combined action of the enzymes galactosyl transferase and glucosyl transferase. 

Results of amino acid analysis performed on resilin from the locust Schistorcerca gregaria, compared with values for collagen, elastin, and silk fibroin. Reproduced from [145] with permission from Elsevier, copyright Elsevier 1961 Includes 106 hydroxyproline and 7 hydroxylysine... 

Elastin confers extensibihty and elastic recoil on tissues. Elastin lacks hydroxylysine, Gly-X-Y sequences, triple hehcal stmcture, and sugars but contains desmosine and isodesmosine cross-links not found in collagen. 

The many (possibly more than 30) types of collagens found in human connective tissues have substantially the same chemical structure consisting mainly of glycine with smaller amounts of proline and some lysine and alanine. In addition, there are two unusual amino acids, hydroxyproline and hydroxylysine, neither of which has a corresponding base-triplet or codon within the genetic code. There is therefore, extensive post-translational modification of the protein by hydroxylation and also by glycosylation reactions. 

Although the exact amino acid sequence differs between the various collagens, the primary structure usually conforms to a repeating tripeptide Gly-X-Y where X and Y are, proline, lysine, or hydroxyproline, hydroxylysine respectively. A single unit of collagen is a triple helix composed of three a chains. This conformation differs from the common a helix found in proteins in two important ways ... 

Table 4 summarizes the contents of galactosyl- and glycosylgalactosyl hydroxylysine residues in several types of collagen. 

Collagen cross-links. Besides amide bonds between amino acids in the same a chain, bonds between amino acid side chains of different a chains can form "cross-links". These bonds originate from enzymatically-oxidized side chains of lysine and hydroxylysine residues. The oxidized residues react with other lysine and hydroxylysine residues, forming difunctional products. Reactions of such products with oxidized lysine or hydroxylysine yield trifunctional cross-links (Reiser et al., 1992). 

V-1 from acid and alkaline hydrolyzates, SCX-HPLC of amino acids, a mixture of purified crosslinks and hydroxylysine b purified cross-link V-2 c amino acids from an acid hydrolyzate (6 M HCl) of reduced bovine dentin retained on a phenylboronate agarose column after purification as high molecular weight fractions by repeated size exclusion chromatography d as c, alkaline hydrolyzate (2 M KOH). Injections (c, d) resulted from 18 and 52 mg collagen originally hydrolyzed, respectively. 1 = 111 (HP) 2 = V-2 3 = IV 4 = V-1-1 (DHLNL) 5 = HLNL (bovine tendon) 6 = VI (histidinoalanine ) 7 = hydroxylysine 8 = VI (lysinoalanine). 

Vitamin C is essential for the formation of collagen, the principal structural protein in skin, bone, tendons, and ligaments, being a cofactor in the hydroxylation of the amino acids proline to 4-hydroxyproline, and of lysine to 5-hydroxylysine. These hydroxyamino acids account for up to 25% of the collagen structure. Vitamin C is also associated with some other hydroxylation reactions, e.g. the hydroxylation of tyrosine to dopa (dihydroxyphenylalanine) in the pathway to catecholamines (see Box 15.3). Deficiency leads to scurvy, a condition characterized by muscular pain, skin lesions, fragile blood vessels, bleeding gums, and tooth loss. Vitamin C also has valuable antioxidant properties (see Box 9.2), and these are exploited commercially in the food industries. 

The triplet Cly-X-Y is constantly repeated in the sequence of the triple-helical regions— i. e., every third amino acid in such sequences is aglycine. Proline (Pro) is frequently found in positions X or Y the Y position is often occupied by 4-hydroxyproline (4Hyp), although 3-hydroxyproline (3Hyp) and 5-hydroxylysine (5Hyl) also occur. These hydroxylated amino acids are characteristic components of collagen. They are only produced after protein biosynthesis by hydroxylation of the amino acids in the peptide chain (see p. 62). 

Ascorbic acid or vitamin C is found in fruits, especially citrus fruits, and in fresh vegetables. Man is one of the few mammals unable to manufacture vitamin C in the liver. It is essential for the formation of collagen as it is a cofactor for the conversion of proline and lysine residues to hydroxyproline and hydroxylysine. It is also a cofactor for carnitine synthesis, for the conversion of folic acid to folinic acid and for the hydroxylation of dopamine to form norepinephrine. Being a lactone with two hydroxyl groups which can be oxidized to two keto groups forming dehydroascorbic acid, ascorbic acid is also an anti-oxidant. By reducing ferric iron to the ferrous state in the stomach, ascorbic acid promotes iron absorption. 

In addition to the 20 common amino acids, proteins may contain residues created by modification of common residues already incorporated into a polypeptide (Fig. 3-8a). Among these uncommon amino acids are 4-hydroxyproline, a derivative of proline, and 5-hydroxylysine, derived from lysine. The former is found in plant cell wall proteins, and both are found in collagen, a fibrous protein of connective tissues. 6-N-Methyllysine is a constituent of myosin, a contractile protein of muscle. Another important uncommon amino acid is y-carboxyglutamate, found in the bloodclotting protein prothrombin and in certain other proteins that bind Ca2+ as part of their biological function. More complex is desmosine, a derivative of four Lys residues, which is found in the fibrous protein elastin. 

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