Homocysteine enhances the inhibitory effect of extracellular adenosine on the synthesis of proteins in isolated rat hepatocytes

Adenosine kinase regulation of cardiomyocyte hypertrophy

There is evidence that extracellular adenosine can attenuate cardiac hypertrophy, but the mechanism by which this occurs is not clear. Here we investigated the role of adenosine receptors and adenosine metabolism in attenuation of cardiomyocyte hypertrophy. Phenylephrine (PE) caused hypertrophy of neonatal rat cardiomyocytes with increases of cell surface area, protein synthesis, and atrial natriuretic peptide (ANP) expression. These responses were attenuated by 5 μM 2-chloroadenosine (CADO; adenosine deaminase resistant adenosine analog) or 10 μM adenosine. While antagonism of adenosine receptors partially blocked the reduction of ANP expression produced by CADO, it did not restore cell size or protein synthesis. In support of a role for intracellular adenosine metabolism in regulating hypertrophy, the adenosine kinase (AK) inhibitors iodotubercidin and ABT-702 completely reversed the attenuation of cell size, protein synthesis, and expression of ANP by CADO or ADO. Examination of PE-induced phosphosignaling pathways revealed that CADO treatment did not reduce AKT(Ser⁴⁷³) phosphorylation but did attenuate sustained phosphorylation of Raf(Ser³³⁸) (24-48 h), mTOR(Ser²⁴⁴⁸) (24-48 h), p70S6k(Thr³⁸⁹) (2.5-48 h), and ERK(Thr²⁰²/Tyr²⁰⁴) (48 h). Inhibition of AK restored activation of these enzymes in the presence of CADO. Using dominant negative and constitutively active Raf adenoviruses, we found that Raf activation is necessary and sufficient for PE-induced mTORC1 signaling and cardiomyocyte hypertrophy. CADO treatment still blocked p70S6k(Thr³⁸⁹) phosphorylation and hypertrophy downstream of constitutively active Raf, however, despite a high level phosphorylation of ERK(Thr202/Tyr204) and AKT(Ser⁴⁷³). Reduction of Raf-induced p70S6k(Thr³⁸⁹) phosphorylation and hypertrophy by CADO was reversed by inhibiting AK. Together, these results identify AK as an important mediator of adenosine attenuation of cardiomyocyte hypertrophy, which acts, at least in part, through inhibition of Raf signaling to mTOR/p70S6k.

Determination of S-Adenosylmethionine and S-Adenosylhomocysteine by LC-MS/MS and evaluation of their stability in mice tissues

S-Adenosylmethionine (SAM) serves as a methyl donor in biological transmethylation reactions. S-Adenosylhomocysteine (SAH) is the product as well as the inhibitor of transmethylations and the ratio SAM/SAH is regarded as the measure of methylating capacity (“methylation index”). We present a rapid and sensitive LC–MS/MS method for SAM and SAH determination in mice tissues. The method is based on chromatographic separation on a Hypercarb column (30 mm × 2.1 mm, 3 μm particle size) filled with porous graphitic carbon stationary phase. Sufficient retention of SAM and SAH on the chromatographic packing allows simple sample preparation protocol avoiding solid phase extraction step. No significant matrix effects were observed by analysing the tissue extracts on LC–MS/MS. The intra-assay precision was less than 9%, the inter-assay precision was less than 13% and the accuracy was in the range 98–105% for both compounds. Stability of both metabolites during sample preparation and storage of tissue samples was studied: the SAM/SAH ratio in liver samples dropped by 34% and 48% after incubation of the tissues at 4 °C for 5 min and at 25 °C for 2 min, respectively. Storage of liver tissues at −80 °C for 2 months resulted in decrease of SAM/SAH ratio by 40%. These results demonstrate that preanalytical steps are critical for obtaining valid data of SAM and SAH in tissues.

Hyperhomocysteinemia and high-density lipoprotein metabolism in cardiovascular disease

Hyperhomocysteinemia (HHcy) is a significant and independent risk factor for cardiovascular disease (CVD) and the underlying mechanism is unclear. We and others have reported that homocysteine (Hcy) is inversely correlated with plasma high-density lipoprotein cholesterol (HDL-C) and apolipoprotein AI (apoA-I) in patients with coronary heart disease (CHD). We confirmed this negative correlation in mice with targeted deletions of the genes for apolipoprotein E (apoE) and cystathionine beta-synthase (CBS). Severe HHcy (plasma Hcy 210 micromol/L) accelerates spontaneous arthrosclerosis in the CBS(-/-)/apoE(-/-) mice, reduces the concentration of circulating HDL, apoA-I, and large HDL particles, inhibits HDL function, and enhances HDL-C clearance. We have demonstrated further that Hcy (0.5-2 mmol/L) reduces apoA-I protein synthesis and secretion, but not RNA transcription in mouse primary hepatocytes. A different mechanism was proposed based on studies using the HepG2 cells showing that Hcy (5-10 mmol/L) inhibits apoA-I transcription via peroxisome proliferator-activated receptor-alpha (PPARalpha)-inhibition-dependent and -independent mechanisms. These studies suggest that Hcy-induced HDL-C and apoA-I inhibition represent a novel mechanism by which Hcy induces atherosclerotic CVD.

Molecular Analysis of Homocysteic Acid-Induced Neuronal Stress

Hyperhomocysteinemia is a risk factor for vascular and neuronal lesions often observed with concomitant high levels of homocysteic acid. In contrast to homocysteine, homocysteic acid induces calcium influx into neurons, with characteristics of an excitotoxic glutamatergic agonist at elevated concentrations. On the molecular level this is correlated to fast modifications of proteins (phosphorylation and proteolysis). Within the homocysteic acid induced molecular signature we focused in more detail on phosphorylation of two proteins implicated as risk factors in schizophrenia and neurodegeneration: Dihydropyrimidinase related protein and 14-3-3 protein isoforms. Among the identified proteins there are known chaperones and oxidative metabolism enzymes, but a few are new in context of neuronal stress: Lasp-1, a vitamin D associated factor and an expressed sequence with features of a Rho GDP dissociation inhibitor. Moreover, we detect a specific proteolytic processing of heat shock protein 70 and proteindisulfide isomerase, which is abolished by vitamins (folic acid, vitamin B12, and vitamin B6), which also decrease elevated intracellular calcium levels induced by homocysteic acid.

Characterization of glycerophosphocholine phosphodiesterase activity and phosphatidylcholine biosynthesis in cultured retinal microcapillary pericytes. Effect of adenosine and endothelin-1

In pericytes from bovine retina, the enzyme glycerophosphocholine phosphodiesterase, catalyzing the hydrolysis of sn-glycero-3-phosphocholine to glycero-3-phosphate and choline, has been characterized with respect to pH optimum, metal ion dependence, Km, inhibitors, and subcellular localization. In these cells, the natural substrate sn-glycero-3-phosphocholine was present at relatively high concentration (6.4 +/- 1.2 nmol/mg protein), and the EDTA-sensitive phosphodiesterase activity was also found to be markedly high (9.80 +/- 1.5 nmol/min/mg protein) compared to that estimated in liver and brain (1-3 nmol/min/mg protein) or in renal epithelial cell culture (0.27 nmol/min/mg protein). The reaction conditions were in general agreement with those found earlier in brain and other tissues. The majority of the enzyme specific activity was located in the plasma membrane, whereas a minor part was present in the microsomal fraction. The physiological significance of the high catabolic phosphodiesterase activity in these cells may be related to the transfer, followed by deacylation, of lysophosphatidylcholine from the bloodstream to nervous tissue. In addition, capillary pericytes in culture were able to incorporate 3H-choline rapidly into choline-containing soluble phosphorylated intermediates and into phosphatidylcholine. To find a positive and negative effector on phosphatidylcholine formation, adenosine, an important intercellular mediator in the retina in response to alterations in oxygen delivery, and endothelin-1, a potent paracrine mediator present at the blood-brain and blood-retina barrier, were tested. The cells cultured for 1 or 24 h in a medium containing adenosine at concentrations of 10(-6) and 10(-4) M showed significant reduction in 3H-choline incorporation compared to control cultures, whereas endothelin-1, at a concentration of 10 and 100 nM, caused stimulation of phosphatidylcholine biosynthesis. These findings provide evidence that both agonists may modulate phosphatidylcholine metabolism in pericytes.

Intracellular, nonreceptor-mediated signaling by adenosine: induction and prevention of neuronal apoptosis

Inhibitory effect of adenosine on the isolated heart muscle and vascular system were first described in 1929. Since then, numerous reviews have been published on the diverse actions of this nucleoside on a wide variety of cell types. Essentially all effects of adenosine in neurons and non-neuronal cells are mediated by activation of nucleoside membrane receptors coupled to specific intracellular second messenger pathways. This brief review describes two novel actions of adenosine in peripheral sympathetic neurons, which are not mediated by adenosine receptors. First is described how adenosine and related nucleosides are able to induce apoptosis during the initial stages of neuronal growth and development in vitro and in vivo. Second is discussed how adenosine is able to prevent or delay apoptosis in more mature sympathetic neurons subjected to nerve growth factor deprivation in culture. Both the induction and prevention of apoptosis are independent of receptor activation, and totally dependent on the intracellular accumulation and subsequent phosphorylation of adenosine. The physiological significance and mechanisms by which adenosine can induce apoptosis in one situation, and rescue from apoptosis in another, are described in this article.

Hypoxia increases the association of 4E-binding protein 1 with the initiation factor 4E in isolated rat hepatocytes

Incubation of hepatocytes under hypoxia increases binding of translation initiation factor eIF-4E to its inhibitory regulator 4E-BP1, and this correlates with dephosphorylation of 4E-BP1. Rapamycin induced the same effect in aerobic cells but no additive effect was observed when hypoxic cells were treated with rapamycin. This enhanced association of 4E-BP1 with eIF-4E might be mediated by mTOR. Nevertheless, only hypoxia produces a rapid inhibition of protein synthesis. Although hypoxia might be signalling via the rapamycin-sensitive pathway by changing eIF-4E availability, such a pathway is unlikely to be responsible for the depression in overall protein synthesis under hypoxia.

Adenosine induces apoptosis by inhibiting mRNA and protein synthesis in chick embryonic sympathetic neurons

Our previous work has established that adenosine is toxic to chick embryonic sympathetic neurons and kills freshly plated neurons by a process of apoptosis. Although the exact mechanism remains unknown, we found that phosphorylation of adenosine was essential to the toxicity. Using markers for RNA ([3H]uridine) and protein ([35S]methionine) synthesis we demonstrate here that in freshly plated sympathetic neurons adenosine inhibits RNA and protein synthesis by about 50%. The inhibitory effects of adenosine on RNA and protein synthesis, and increased ATP synthesis were blocked by adenosine kinase inhibitor, suggesting that phosphorylated products are responsible for inhibition of RNA and protein synthesis and cell death. Adenosine-induced inhibition of RNA and protein synthesis in neuronal cells provides a new role for adenosine in the regulation of cell function.

Purines and their roles in apoptosis

Purines are ubiquitous endogenous metabolites, and their roles as signalling molecules, especially in the case of adenosine and ATP, are well documented. The release of purines is increased when cells are highly activated, stressed or damaged, and this is known to have profound effects on various organ systems. Recently, purines like adenosine and ATP have been shown to be cytotoxic. Current evidence suggests that adenosine induces cell death by apoptosis, whereas ATP appears to cause both necrosis and apoptosis. Apoptosis is an important physiological process during normal tissue turnover and in the maturation of the immune system, embryogenesis, metamorphosis, endocrine-dependent tissue atrophy, etc. Recently, many of the key components of the apoptotic cell death cascade have become unravelled. In particular, proteases belonging to the interleukin-1 beta-converting (ICE) enzyme family, also known as caspases, have been shown to act as an intracellular convergence point that orchestrates the morphological and biochemical features of apoptosis. However, little is known about the signalling or the biochemical mechanisms of purine-mediated cell death. Adenosine appears to act through P1 purinoceptors, although the subtype involved remains controversial, whereas ATP may involve both P2X1 and P2X7 purinoceptors. More recent evidence suggests that the intracellular levels of purines, in addition to the cell surface receptor-mediated responses, may also play a critical role by modulating other apoptotic cell death signals. Here, we review our current understanding about purines in mediating cell death and raise a number of questions as to the possible mechanisms involved.

Protective effect of fructose on survival and metabolic capacities of hepatocytes kept overnight under cold hypoxia before normothermic reoxygenation

The protective effect of fructose with regard to hypoxia-induced cell injury in overnight cold preserved hepatocytes (20 hr at 4 degrees C) was investigated. The addition of fructose (at 10 and 20 mM) resulted in an improved survival of hepatocytes during their normothermic (37 degrees C) reoxygenation, irrespective of the time of fructose addition before the onset of hypoxia (i.e. 10, 20 or 30 min). Such a protective effect was even higher than that observed when hepatocytes were incubated in the University of Wisconsin solution (UW). Moreover, neither Desferal (an iron chelator) nor adenosine (an ATP precursor), nor other carbohydrates (glucose, galactose and the antioxidant mannitol) were able to protect cells against such an hypoxia-mediated injury. The intracellular ATP content was lower in both adenosine- and fructose-treated hepatocytes than in control untreated cells. However, the cellular metabolic capacities such as protein synthesis and gluconeogenesis from lactate recovered faster during reoxygenation of previously hypoxic fructose-treated cells compared with both control and adenosine-treated cells.

Adenosine-mediated inhibition of glutathione synthesis in rat isolated hepatocytes

The modulatory effect of adenosine on hepatic glutathione (GSH) synthesis has been investigated in an experimental model in which GSH synthesis from methionine was monitored in rat isolated hepatocytes previously depleted of GSH. Adenosine inhibited GSH synthesis in this system, with complete inhibition occurring at 1 mM. Studies with adenosine receptor agonists and antagonists and adenosine analogues devoid of agonist activity have indicated that this effect of adenosine is not receptor-mediated nor is it mediated through changes in ATP level or redox balance. Rather, the data are consistent with an inhibitory effect of adenosine on the methionine-->cysteine transsulphuration pathway, probably at the level of the enzyme S-adenosylhomocysteine hydrolase. Submaximal inhibitory concentrations of adenosine produced an effect on GSH synthesis additive to that obtained with a maximal inhibitory concentration of adrenaline, which inhibits GSH synthesis at the level of gamma-glutamylcysteinyl synthetase. Furthermore, exposure of hepatocytes to adenosine subsequent to brief treatment with the toxicant menadione precipitated cytotoxicity. These results suggest that adenosine-mediated inhibition of hepatic GSH synthesis may have a role in various pathological or toxicological states.

Adenosine stimulates calcium influx in isolated rat hepatocytes

The mechanism of stimulation of Ca2+ entry into hepatocytes by adenosine was investigated. When Fura-2-loaded hepatocytes were suspended in a nominally Ca(2+)-free buffer, adenosine produced only a small transient increase in the cytosolic free Ca2+ concentration ([Ca2+)i). However, on restoration of an extracellular Ca2+ concentration of 1.3 mM, a rapid increase in [Ca2+]i occurred, which indicates activation of a Ca(2+)-influx pathway. Adenosine augmented the rate of Ca2+ influx triggered by maximally effective concentrations of thapsigargin or cAMP, but was without effect on the rate of Ca2+ entry that resulted from phospholipase-C-linked-receptor activation by maximally effective concentrations of vasopressin or ATP. However, in contrast to vasopression and ATP, adenosine did not stimulate Mn2+ entry. The rate of Mn2+ influx after stimulation of the hepatocytes with vasopressin was not increased by adenosine treatment. The stimulation of hepatocytes with adenosine did not result in significant accumulation of inositol phosphates or cAMP. Furthermore, the rate of adenosine-induced Ca2+ entry in hepatocytes was only slightly reduced in the presence of the P1 purinoceptor antagonist 8-phenyltheophylline. In contrast, the receptor-mediated-Ca(2+)-entry antagonist SK&F 96365 nearly completely blocked the Ca(2+)-entry response without any effect on internal-Ca(2+)-pool mobilisation by adenosine. It is concluded that adenosine activates the internal-pool-regulated pathway of Ca2+ entry and an additional pathway that appears comparable to the previously reported receptor-dependent pathway, except that Mn2+ entry is not stimulated.

Inhibition of protein synthesis induced by adenine nucleotides requires their metabolism into adenosine

Adenine nucleotides and adenosine inhibit the incorporation of radiolabelled leucine into proteins of isolated hepatocytes. Impairment occurred with nucleotides which can be converted into 9-beta-D-ribofuranosyladenine (adenosine) but was not observed after treatment with adenine or AMPCPP (the alpha, beta-methylene analogue of ATP). Metabolism into adenosine was further suggested by the increase in cellular ATP levels following treatment of hepatocytes with ATP, adenosine or AMPPCP (the beta, gamma-methylene ATP analogue) while AMPCPP was without any significant effect. The inhibition of protein synthesis caused by adenosine was not due to a lytic effect nor to a general disturbance in hepatic functions and was reversed when the cells were washed and transferred to a nucleoside-free medium. This impairment, however, was not coupled to the activation of adenylate cyclase, as preincubation of hepatocytes with P1 purinoceptor antagonists failed to prevent protein synthesis inhibition. In contrast, L-homocysteine enhanced the inhibitory effect of adenosine on the incorporation of radiolabelled leucine into proteins. Our results thus suggest that the inhibition of protein synthesis caused by adenine nucleotides requires their conversion into adenosine. They also indicate that the inhibitory effect of adenosine does not involve a receptor-mediated effect but may be related to an increase in S-adenosylhomocysteine content and a subsequent low level of macromolecule methylation.