Biochemical and ultrastructural study of the effects of proline analogues on collagen synthesis in 3T6 fibroblasts

Infrared Multiple Photon Dissociation Spectroscopy of Cationized Canavanine: Side-Chain Substitution Influences Gas-Phase Zwitterion Formation†

Infrared multiple photon dissociation spectroscopy was performed on protonated and cationized canavanine (Cav), a non-protein amino acid oxy-analog of arginine. Infrared spectra in the XH stretching region (3000 - 4000 cm^-1) were obtained at the Centre Laser Infrarouge d'Orsay (CLIO) facility. Comparison of the experimental infrared spectra with scaled harmonic frequencies at the B3LYP/6-31+G(d,p) level of theory indicates that canavanine is in a canonical neutral form in CavH⁺, CavLi⁺, and CavNa⁺; therefore, these cations are charge-solvated structures. The infrared spectrum of CavK⁺ is consistent with a mixture of Cav in canonical and zwitterionic forms leading to both charge-solvated and salt-bridged cationic structures. The Cav moiety in CavCs⁺ is shown to be zwitterionic, forming a salt-bridged structure for the cation. Infrared spectra in the fingerprint region (1000 - 2000 cm^-1) obtained at the FELIX Laboratory in Nijmegen, Netherlands support these assignments. These results show that that a single oxygen atom substitution in the side chain reduces the stability of the zwitterion compared to that of the protein amino acid arginine (Arg), which has been shown previously to adopt a zwitterionic structure in ArgNa⁺ and ArgK⁺. This difference can be explained in part due to the decreased basicity of Cav (PA = 1001 kJ/mol) as compared to arginine (PA = 1051 kJ/mol), but not entirely, as lysine, which has nearly the same proton affinity as Cav, (~993 kJ/mol) forms only canonical structures with Na⁺, K⁺, and Cs⁺. A major difference between the zwitterionic forms of ArgM⁺ and CavM⁺ is that the protonation site is on the side chain for Arg and on the N-terminus for Cav. This results in systematically weaker salt bridges in the Cav zwitterions. In addition, the presence of another hydrogen-bonding acceptor atom in the side chain contributes to the stability of the canonical structures for the smaller alkali cations.

Investigating β-N-Methylamino-l-alanine Misincorporation in Human Cell Cultures: A Comparative Study with Known Amino Acid Analogues

Misincorporation of β-N-methylamino-l-alanine (BMAA) into proteins has been proposed to be a mechanism of toxicity to explain the role of BMAA in neurodegenerative disease development. However, studies have shown that all detectable BMAA can be removed from proteins by SDS-PAGE purification and that the toxicity of l-canavanine cannot be reproduced in prokaryotes or in a rat pheochromocytoma cell line, strongly indicating that the misincorporation hypothesis of BMAA should be re-investigated. The aim of this study was therefore to determine if BMAA misincorporates into proteins in cells of human origin with subsequent misincorporation-type toxicity. Almost complete loss of viability in response to exposure to l-4-fluorophenylalanine and l-m-tyrosine was observed in all of the cell lines, corresponding to a concentration-dependent increase of the analogues in protein extracts from exposed cells. In contrast, BMAA exposure resulted in slight toxicity in one of the cell lines but the observed toxicity was not the result of misincorporation of BMAA into proteins, as no BMAA was detected in any of the SDS-PAGE purified protein extracts that were obtained from the cells following BMAA exposure. The results show that BMAA is not misincorporated into human proteins and that misincorporation is not a valid mechanism of toxicity.

The proton affinity of proline analogs using the kinetic method with full entropy analysis

The proton affinity of proline analogs, L-azetidine-2-carboxylic acid (Aze), L-proline (Pro), and L-pipecolic acid (Pip), have been measured using the Armentrout modification of the extended kinetic method in a quadrupole ion trap instrument. Experimental values of 223.0 +/- 1.5, 224.9 +/- 1.6, and 225.6 +/- 1.6 kcal/mol have been determined for the 298K proton affinities of Aze, Pro, and Pip respectively. High level theoretical calculations using both MP2 and B3LYP methods at a variety of basis sets were carried out in order to give theoretical predictions for the 298 K proton affinity and gas phase basicity of all three analogs. Recommended values for the gas phase basicity and proton affinity for proline based on our work and other recent determinations are 216 +/- 2 and 224 +/- 2 kcal/mol.

Stimulation of collagen biosynthesis by the umbilical cord serum of newborns delivered by mothers with EPH-gestosis (preeclampsia)

Edema, proteinuria, hypertension (EPH)-gestosis, known also as preeclampsia, is the most common, pregnancy-associated pathological syndrome. It is accompanied by a significant increase in collagen content in the umbilical cord arteries and premature replacement of hyaluronic acid by sulfated glycosaminoglycans both in these arteries and in Wharton's jelly. This remodelling of the umbilical cord tissues is accompanied by a distinct increase in insulin-like growth factor-I (IGF-I) concentration in the umbilical cord serum. Such a serum introduced into the culture medium of fibroblasts growing in vitro strongly stimulated the incorporation of radioactive proline into collagen (hydroxyproline-containing and collagenase-sensitive protein). Biosynthesis of noncollagenous proteins was not stimulated. Since IGF-I is known as a stimulator of collagen and sulfated glycosaminoglycan biosynthesis, the high concentration of this growth factor in the umbilical cord plasma may be an agent responsible for preeclampsia-associated remodelling of the umbilical cord, which results in dysfunction in fetal circulation.

Biologic effects of and clinical disorders caused by nonprotein amino acids

Despite the fact that nonprotein amino acids are present in many commonly eaten foods, the biologic and clinical significance of this class of molecules has been largely overlooked. This is owing in part to their relatively low concentrations and their negligible nutritive value. Many of these compounds have the ability to interfere with a wide range of fundamental biochemical processes and cause disease. It is likely that the clinical effects of the ingestion of some nonprotein amino acids are yet to be described. Serious disorders in humans have followed the ingestion of these compounds as the result of food faddism, prodded by the commercial promotion of inadequately tested products. In view of the current popularity of herbal remedies and alternative medicine, these facts serve as another reminder to health care providers and the public at large about the need for critical analysis of the alleged benefits and the risks of exotic remedies and nutritional supplements. Beyond the public health issues they raise, non-protein amino acids take on significance because their misincorporation into proteins can trigger vigorous autoimmune attacks. To what extent this mechanism is responsible for highly prevalent diseases of autoimmunity remains to be determined.

Liver collagen of rats submitted to chronic intoxication with acetaldehyde

It was found that chronic intoxication of rats with acetaldehyde results in a distinct, progressive increase of 5-3H-proline incorporation into collagen synthesized by liver. At the same time biosynthesis of other proline-containing (noncollagenous) proteins does not change significantly. On the other hand the collagen content in the rat liver did not increase in the early stage of acetaldehyde administration, but increased when acetaldehyde feeding was continued for 6 months. About 40% increase of total collagen content was found in livers of the intoxicated animals. All the investigated collagen types (I, III, IV and V) grew in the same degree. No changes in proportional relationships between collagens of different types were found.

Chronic intoxication with acetaldehyde stimulates collagen biosynthesis in rat liver

It was found that chronic intoxication of rats with acetaldehyde results in a distinct, progressive increase of 5(3)H-proline incorporation into collagen synthesized by liver. At the same time, biosynthesis of other proline-containing (noncollagenous) proteins does not change significantly. The effects are similar to those induced by chronic intoxication of rats with ethanol. Since acetaldehyde is an intermediary metabolite formed during ethanol oxidation in liver, it may be concluded that acetaldehyde is a factor responsible for alcohol-induced liver fibrosis.

An increase of collagen biosynthesis in livers of rats submitted to chronic intoxication with ethanol

It was found that chronic intoxication of rats with ethanol results in a distinct, progressive increase of 5(3)H-proline incorporation into collagen synthesized by liver. At the same time biosynthesis of other proline-containing proteins in rat liver slightly decreases. These effects precede the morphological symptoms of liver damage induced by ethanol.

An increase of collagen biosynthesis precedes other symptoms of ethanol-induced liver damage in rats

Treatment of rats with 10% ethanol for 6 months induced a 3-4-fold increase of [3H]proline incorporation into liver collagen and enhanced the level of prolyl hydroxylase activity in liver and serum of intoxicated rats. Several diagnostic tests used to assess liver disease failed to demonstrate any symptom of liver damage. Therefore, increased collagen biosynthesis appears to precede other symptoms of liver damage induced by ethanol.

Postnatal development of rat lung following retarded fetal lung growth

Postnatal lung development was examined in rats born with smaller than normal lungs after either prenatal exposure to glucocorticoid or to an inhibitor of collagen synthesis. At birth, treated animals had lower than normal lung weights, lung to body weight ratios, hydroxyproline (HYP) levels, total DNA; and rates of DNA synthesis. Rats exposed to steroid showed a rapid recovery in growth during the normal postnatal cell proliferative phase from 4 to 11 days, though collagen levels did not return to normal until 3 weeks of age. Rats exposed to a prenatal proline analog showed a much slower rise in lung weight and total DNA, and these levels were still much below normal at 2-3 weeks when the cell proliferation phase was completed. Levels of disaturated phosphatidylcholine were significantly below normal up to 11 days, whereas total HYP was significantly reduced and less fibrillar collagen was seen in the lung throughout the study. The results indicate that the smaller but mature lungs at birth after antenatal steroid show a growth rebound and quickly become structurally normal. In contrast, inhibition of fibroblast growth and collagen deposition produces small lungs at birth, which continue to show inhibited growth and development at least up to 3 weeks of age, when the cell division phase is over.