The detection and quantitation of free desmosine and isodesmosine in human urine and their peptide-bound forms in sputum.

Desmosine (D) and isodesmosine (I), the intramolecular crosslinking amino acids that occur in chains of elastin, have now been found in free form in human urine. Until now, these amino acids (M(r) = 526) were found to occur in urine only as higher molecular weight (M (r) = 1,000-1,500) peptides. Thus, the previously used analytical methods required, as the first step, acid hydrolysis of the urine at elevated temperature to liberate D and I from their peptides. The analytical method described here uses HPLC followed by electrospray ionization MS for the detection and quantitation of free D and I in unhydrolyzed urine. Identities of both D and I were established by their retention times on LC and by their mass ion at 526 atomic mass units, characteristic of each compound. The sensitivity of the method is 0.10 ng. The average values of free D and I in the urine of seven healthy subjects were 1.42 +/- 1.16 and 1.39 +/- 1.04 microg/g of creatinine, respectively. After acid hydrolysis of the urine, the amounts of D and I were 8.67 +/- 3.75 and 6.28+/-2.87 microg/g of creatinine, respectively. The method was also successfully used to measure peptide-bound D and I levels in the sputum of patients with chronic obstructive pulmonary disease.

Age-related alteration of cross-linking amino acids of elastin in human aorta.

It is well known that the elastic property of human aorta decreases gradually with age. Since the cross-linking structures are responsible for this elasticity, age-related changes of cross-linking amino acids in human aorta were studied using a high-performance liquid chromatography (HPLC). Non-atherosclerotic areas of thoracic aorta of 27 autopsy cases which had no particular aortic disease were obtained. After acid hydrolysis, SEP-PAK silica-gel column and Fe3+/activated charcoal column pretreatment were carried out for analysis of desmosine (DES), isodesmosine (ISDES), neodesmosine (NEO), oxodesmosine (OXO) and isooxodesomosine (ISOXO), and for analysis of aldosine (ALD), respectively. These prepared samples were applied to the reversed-phase HPLC column. We also analyzed pyridinoline (PYR), a major cross-linking amino acid of collagen as an index of fibrosis. All cross-linking amino acids of elastin rapidly increased in infancy and then gradually decreased with age. In the middle- and old-age, the amount of OXO showed marked variety. PYR was little detected at 0-year-old, and then gradually increased with age. The crosslinks of elastin were rapidly formed in childhood and then decreased with age. These findings suggest that the relative increase of NEO, OXO or ISOXO to DES and ISDES is associated with age-related weakening and/or damage of elastin, and that the gradual shift from elastin- to collagen-dominant state is a possible cause of the loss of elasticity and the gain of stiffness in the aging aorta.

Isolation and characterization of a pentameric amino acid from elastin.

An unknown amino acid was purified from bovine ligament elastin. The compound was shown by proton NMR to have a pyridinium ring structure similar to isodesmosine, yet containing an olefinic double bond on one additional side chain which was not attached to the pyridinium ring. Mass spectral analysis confirmed the NMR data and indicated a parent compound with a mass of 653. A structure is proposed that is derived from the condensation of five lysine residues. The trivial name of pentasine is proposed for this compound.

Dihydropyridine precursors of elastin crosslinks.

Dihydrodesmosine and dihydroisodemosine are dihydropyridines which are believed to be the immediate biosynthetic precursors of desmosine and isodesmosine, the stable pyridinium ion crosslinks of elastin. It has recently been reported that appreciably amounts of dihydrodesmosine and dihydroisodesmosine accumulate in elastin. In view of the ease with which such dihydropyridines are oxidized to the corresponding pyridinium ions by O2 and other mild oxidants, dihydrodesmosine and dihydroisodesmosine would not be expected to accumulate in elastic tissues. It therefore seemed appropriate to analyse elastin samples for dihydrodesmosine and dihydroisodesmosine using techniques different from these previously employed for this purpose. The results of these investigations indicate that dihydrodesmosine and dihydroisodesmosine do not accumulate to a measurable extent in elastin.