M.A. Grillo

Advanced glycation end-products (AGEs): involvement in aging and in neurodegenerative diseases

Summary.Advanced glycation end-products (AGEs) are formed from the so-called Amadori products by rearrangement followed by other reactions giving rise to compounds bound irreversibly. The structure of some of them is shown and the mechanism of formation is described. Several AGE binding molecules (Receptors for AGE, RAGE) are known and it is thought that many of the effects caused by AGEs are mediated by RAGE. Some of these were shown to be toxic, and called TAGE. The mechanism of detoxification of glyoxal and methylglyoxal by the glyoxalase system is described and also the possibility to eliminate glycated proteins by deglycation enzymes. Compounds able to inhibit AGEs formation are also taken into consideration.

S-adenosylmethionine and its products

Summary.S-adenosylmethionine is involved in many processes, mainly methylation, polyamine synthesis and radical-based catalysis. It is synthesised through the catalysis of differently regulated enzyme forms. When it is used, the compounds formed are reutilized in different ways: in case of methylation, its end product is homocysteine, which can be remethylated to methionine, give rise to cysteine in the so-called transsulphuration pathway, or be released; in the case of polyamine synthesis, the methylthioadenosine formed is cleaved and gives rise to compounds which can be reutilized; during radical-based catalysis, 5-deoxyadenosine is formed and this, too, is cleaved and reutilized.

Transport of amino acids through the placenta and their role.

Amino acids are transported across the human placenta mediated by transporter proteins that differ in structure, mechanism and substrate specificity. Some of them are Na+-dependent systems, whereas others are Na+-independent. Among these there are transporters composed of a heavy chain, a glycoprotein, and a light chain. Moreover, they can be differently distributed in the two membranes forming the syncytiotrophoblast. The transport mechanisms involved and their regulation are only partially known. In the placenta itself, part of the amino acids is metabolized to form other compounds important for the fetus. This occurs for instance for arginine, which gives rise to polyamines and to NO. Interconversion occurs among few other amino acids Transport is altered in pregnancy complications, such as restricted fetal growth.

Metabolism and function in animal tissues of agmatine, a biogenic amine formed from arginine.

Summary.Recently agmatine, decarboxylated arginine, has been shown to be an important biological compound in several animal tissues. This paper summarizes the known information regarding the transport of arginine, its decarboxylation and the effects of the agmatine formed mainly on NO and polyamine synthesis.

S-Adenosylmethionine and protein methylation

Summary.The enzymes responsible for protein methylation by S-adenosylmethionine, both at the carboxyl groups and at the nitrogen groups, are reviewed. The possibility that the reactions involved may be reversible is also considered.

Cobalt induces oxidative stress in isolated liver mitochondria responsible for permeability transition and intrinsic apoptosis in hepatocyte primary cultures

It is well established that cobalt mediates the occurrence of oxidative stress which contributes to cell toxicity and death. However, the mechanisms of these effects are not fully understood. This investigation aimed at establishing if cobalt acts as an inducer of mitochondrial-mediated apoptosis and at clarifying the mechanism of this process. Cobalt, in the ionized species Co(2+), is able to induce the phenomenon of mitochondrial permeability transition (MPT) in rat liver mitochondria (RLM) with the opening of the transition pore. In fact, Co(2+) induces mitochondrial swelling, which is prevented by cyclosporin A and other typical MPT inhibitors such as Ca(2+) transport inhibitors and bongkrekic acid, as well as anti-oxidant agents. In parallel with mitochondrial swelling, Co(2+) also induces the collapse of electrical membrane potential. However in this case, cyclosporine A and the other MPT inhibitors (except ruthenium red and EGTA) only partially prevent DeltaPsi drop, suggesting that Co(2+) also has a proton leakage effect on the inner mitochondrial membrane. MPT induction is due to oxidative stress, as a result of generation by Co(2+) of the highly damaging hydroxyl radical, with the oxidation of sulfhydryl groups, glutathione and pyridine nucleotides. Co(2+) also induces the release of the pro-apoptotic factors, cytochrome c and AIF. Incubation of rat hepatocyte primary cultures with Co(2+) results in apoptosis induction with caspase activation and increased level of expression of HIF-1alpha. All these observations allow us to state that, in the presence of calcium, Co(2+) is an inducer of apoptosis triggered by mitochondrial oxidative stress.

Oxygen regulation of rat hepatocyte iNOS gene expression.

BACKGROUND/AIMS The human iNOS promoter contains a consensus sequence for binding the hypoxia inducible factor. The aim of this study was to see whether iNOS gene expression is triggered by oxygen tension in rat hepatocytes exposed in vivo to high (periportal) and low (perivenous) oxygen tension. METHODS Hepatocytes transfected or not with a plasmid containing rat iNOS promoter linked to chloramphenicol acetyltransferase were cultured at 21% and 5% oxygen tension. In normal hepatocytes, iNOS protein, mRNA and activity were detected. In transfected cells, chloramphenicol acetyltransferase activity was measured. RESULTS In cells cultured in a hypoxic environment, both iNOS protein and mRNA increased, whereas the nitrite level in the medium decreased. However, electron paramagnetic resonance analysis and in vitro iNOS activity indicated that iNOS was active. Transfection experiments showed that the expression of chloramphenicol acetyltransferase driven by iNOS promoter was increased in cells maintained at low oxygen tension. CONCLUSIONS Our experiments show that in rat hepatocytes: 1) iNOS is induced by low oxygen tension; 2) the modification occurs at the transcriptional level; 3) the enzyme at 5% oxygen is able to catalyze the synthesis of NO, although no nitrites are accumulated in the medium. These findings could have physiopathological relevance, e.g. in determining the resistance of perivenous hepatocytes to ischemia injury.

Agmatine induces apoptosis in rat hepatocyte cultures

BACKGROUND/AIMS Agmatine, the compound formed by decarboxylation of arginine, is believed to be an endogenous neurotransmitter through interaction with the imidazoline receptors. However, it also appears to regulate rat hepatocyte polyamines by modifying both their synthesis and their catabolism. As the decrease in polyamine content has been correlated with apoptosis, we examined the possibility that agmatine has an effect on this phenomenon. METHODS Apoptotic cells were detected by visualizing nuclear shrinkage/fragmentation in hepatocytes cultured at 21 and 5% oxygen tension. Caspase-3 activity, cleavage of PARP, release of cytochrome c and mitochondrial swelling were therefore measured in the two conditions and in the presence or not of agmatine. RESULTS In rat hepatocytes agmatine promoted apoptosis, procaspase 3 processing and increase of caspase-3 like activity. This occurred through mitochondria swelling and release of cytochrome c. Cyclosporin A and catalase blocked the swelling. CONCLUSIONS Our experiments show that agmatine, besides all the known biological effects, has also part, at least in hepatocytes, in the modulation of programmed cell death.

Transport and metabolism of polyamines in human lymphocytes.

1. Polyamines are taken up by human peripheral lymphocytes in a concentration, time and pH dependent manner, with an energy-dependent transport system. 2. Each polyamine inhibits the uptake of the others, with the exception of putrescine. Spermine appears to have the highest affinity for the transporter/s. 3. Inhibition by ouabain, amiloride and vanadate suggests that the transport is dependent on Na+. 4. Polyamine content inside the cells increases by ca 6 and 3 times respectively during incubation with spermidine or spermine. 5. The incorporated polyamines are partially transformed into each other.

Arginine revisited: Minireview article

Summary.Arginine is a precursor of proteins and employed in urea synthesis. It is also the precursor of many other compounds, such as creatine, nitric oxide, polyamines, agmatine, proline. In this review, its transport and that of other basic amino acids are examined, along with its transformation into nitric oxide, agmatine and proline, and the mutual regulation of the individual pathways.