Changes in the SU can modulate the susceptibility of feline immunodeficiency virus to TM-derived entry inhibitors.

Feline immunodeficiency virus (FIV) provides a valuable animal model by which criteria for the development of HIV-1 inhibitors can be explored. Previous studies had shown that a synthetic 8-mer peptide modeled on the tryptophan-rich motif of the ectodomain of the viral transmembrane glycoprotein (TM) is a potent inhibitor of FIV The observation that inhibition efficiency varied somewhat depending on FV strain prompted the present study in which we investigated whether changes in the surface (SU) glycoprotein can affect virus susceptibility to TM-derived peptide inhibitors. This was done by examining how effectively selected entry inhibitors blocked the infectivity of well characterized variants and molecular clones of the prototype isolate of FIV The results have shown that substitutions in the SU can indeed modulate virus susceptibility to TM-derived entry inhibitors. Interestingly, we also observed a parallelism between reduced susceptibility to entry inhibitors and broad resistance to antibody-mediated neutralization.

Developmental regulation of the concentrative nucleoside transporters CNT1 and CNT2 in rat liver.

BACKGROUND/AIMS: The pattern of nucleoside transporter expression in hepatocytes was studied in the developing rat liver. METHODS: Hepatocytes isolated from fetuses, neonates and adult rats were used for uridine uptake measurements and concentrative nucleoside transporter (CNT) expression. RESULTS: Adult hepatocytes showed the highest Na-dependent uridine uptake, but fetal hepatocytes exhibited a significant NBTI-sensitive component of equilibrative Na+-independent transport, which was either negligible or absent in neonatal and adult rat hepatocytes. Low Na+-dependent uridine uptake was associated with low amounts of CNT1 and CNT2 transporter proteins, both with apparent Km values in the low micromolar range. Hepatocyte primary cultures from 20-day-old fetuses showed very low amounts of CNT2 mRNA, and expressed both carrier proteins. Incubation of fetal hepatocytes with dexamethasone and T3 resulted in a significant increase in Na+-dependent uridine uptake and an accumulation of the CNT2 protein and mRNA. CONCLUSIONS: The expression of concentrative nucleoside carriers in hepatocytes from developing rat liver is developmentally regulated. Addition of endocrine factors known to induce differentiation of fetal hepatocytes results in selective up-regulation of CNT2 expression.

Differential expression and regulation of nucleoside transport systems in rat liver parenchymal and hepatoma cells.

Primary cultures of rat-liver parenchymal cells show carrier-mediated nucleoside uptake by a mechanism that mainly involves concentrative, Na+-dependent transport activity. In contrast, the hepatoma cell line FAO shows high nucleoside transport activity, although it is mostly accounted for by Na+-independent transport processes. This is associated with a low amount of sodium purine nucleoside transporter (SPNT) mRNA. SPNT encodes a purine-preferring transporter expressed in liver parenchymal cells. To analyze whether SPNT expression is modulated during cell proliferation, SPNT mRNA levels were determined in the early phase of liver growth after partial hepatectomy and in synchronized FAO cells that had been induced to proliferate. SPNT mRNA amounts increased as early as 2 hours after partial hepatectomy. FAO cells induced to proliferate after serum refeeding show an increase in SPNT mRNA levels, which is followed by an increase in Na+-dependent nucleoside uptake and occurs before the peak of 3H-thymidine incorporation into DNA. FAO cells also express significant equilibrative nucleoside transport activity, which may be accounted for by the expression of the nitrobenzylthioinosine (NBTI)-sensitive and -insensitive isoforms, rat equilibrative nucleoside transporter 1 (rENT1) and rENT2, respectively. Interestingly, rENT2 mRNA levels follow a similar pattern to that described for SPNT when FAO cells are induced to proliferate, whereas rENT1 appears to be constitutively expressed. Liver parenchymal cells show low and negligible mRNA levels for rENT1 and rENT2 transporters, respectively, although most of the equilibrative transport activity found in hepatocytes is NBTI-resistant. It is concluded that: 1) SPNT expression is regulated both in vivo and in vitro in a way that appears to be dependent on cell cycle progression; 2) SPNT expression may be a feature of differentiated hepatocytes; and 3) equilibrative transporters are differentially regulated, rENT2 expression being cell cycle-dependent. This is consistent with its putative role as a growth factor-induced delayed early response gene.

Nucleoside transporters and liver cell growth.

Liver parenchymal cells show a wide variety of plasma membrane transporters that are tightly regulated by endocrine and nutritional factors. This review summarizes work performed in our laboratory on these transport systems, particularly nucleoside transporters, which are up-regulated in physiological situations associated with liver cell growth. Rat hepatocytes show a Na+-dependent nucleoside transport activity that is stimulated by pancreatic hormones. Indeed, this biological activity appears to be the result of the co-expression of at least two isoforms of nucleoside carriers, CNT1 and CNT2 (also called SPNT). These two transporters are up-regulated during the early phase of liver growth after partial hepatectomy, although to different extents, suggesting differential regulation of the two isoforms. The recent generation of isoform-specific antibodies allowed us to demonstrate that carrier expression may also have complex post-transcriptional regulation on the basis of the lack of correspondence between mRNA and protein levels. The analysis of nucleoside transport systems in hepatoma cells and the comparison with those in hepatocytes has also provided evidence that the differentiation status of liver parenchymal cells may determine the pattern of nucleoside transporters expressed.

Nucleoside uptake in rat liver parenchymal cells.

Rat liver parenchymal cells express Na(+)-dependent and Na(+)- independent nucleoside transport activity. The Na(+)-dependent component shows kinetic properties and substrate specificity similar to those reported for plasma membrane vesicles [Ruiz-Montasell, Casado, Felipe and Pastor-Anglada (1992) J. Membr. Biol. 128, 227-233]. This transport activity shows apparent K(m) values for uridine in the range 8-13 microM and a Vmax of 246 pmol of uridine per 3 min per 10(5) cells. Most nucleosides, including the analogue formycin B, cis-inhibit Na(+)-dependent uridine transport, although thymidine and cytidine are poor inhibitors. Inosine and adenosine inhibit Na(+)-dependent uridine uptake in a dose-dependent manner, reaching total inhibition. Guanosine also inhibits Na(+)-dependent uridine uptake, although there is some residual transport activity (35% of the control values) that is resistant to high concentrations of guanosine but may be inhibited by low concentrations of adenosine. The transport activity that is inhibited by high concentrations of thymidine is similar to the guanosine-resistant fraction. These observations are consistent with the presence of at least two Na(+)-dependent transport systems. Na(+)-dependent uridine uptake is sensitive to N-ethylmaleimide treatment, but Na(+)-independent transport is not. Nitrobenzylthioinosine (NBTI) stimulates Na(+)-dependent uridine uptake. The NBTI effect involves a change in Vmax, it is rapid, dose-dependent, does not need preincubation and can be abolished by depleting the Na+ transmembrane electrochemical gradient. Na(+)-independent uridine transport seems to be insensitive to NBTI. Under the same experimental conditions, NBTI effectively blocks most of the Na(+)-independent uridine uptake in hepatoma cells. Thus the stimulatory effect of NBTI on the concentrative nucleoside transporter of liver parenchymal cells cannot be explained by inhibition of nucleoside efflux.

Hormonal regulation of concentrative nucleoside transport in liver parenchymal cells.

Na(+)-dependent uridine uptake is stimulated in isolated rat liver parenchymal cells by glucagon. This effect is transient, reaches maximum levels of stimulation 10 min after hormone addition, and is dose-dependent. Glucagon action can be mimicked by agents that are able to hyperpolarize the plasma membrane (e.g. monensin) and by dibutyryl cyclic AMP. The effects triggered by glucagon, monensin and dibutyryl cyclic AMP are not additive, suggesting a common mechanism of action. 8-(4-Chloro-phenylthio)adenosine 3':5'-cyclic monophosphate (PCT), a cyclic AMP analogue but also a nucleoside analogue, markedly stimulates Na(+)-dependent uridine uptake in an additive manner to that triggered by monensin, similarly to the effect described for nitrobenzylthioinosine. Considering the roles reported for nucleosides in liver metabolism, the use of PCT as a cyclic AMP analogue should be precluded. Insulin is also about to up-regulate Na(+)-dependent uridine uptake by a mechanism which involves a stable induction of this transport activity at the plasma-membrane level. This is consistent with a mechanism involving synthesis and insertion of more carriers into the plasma membrane. It is concluded that the recently characterized hepatic concentrative nucleoside transporter is under short-term hormonal regulation by glucagon, through mechanisms which involve membrane hyperpolarization, and under long-term control by insulin. This is the first report showing hormonal modulation of the hepatic concentrative nucleoside transporter.

Lipopolysaccharide (LPS) increases the in vivo oxidation of branched-chain amino acids in the rat: a cytokine-mediated effect.

Septic rats (as induced by cecal puncture and ligation) showed an increased rate of in vivo leucine oxidation as measured from the formation of 14CO2 from an intravenously injected [1-14C]leucine tracer dose. Acute lipopolysaccharide (LPS) administration (1 mg/kg) to rats caused a similar effect on the rate of in vivo leucine oxidation. Additionally, both tumour necrosis factor-alpha (TNF) and interleukin-1-alpha (IL-1), in an acute dose of 100 micrograms/kg, also increased the rate of the oxidation of the amino acid, although only IL-1 caused a similar increase to that observed following LPS. The observed increased leucine oxidation was related to lower leucine concentrations both in LPS- and cytokine-treated rats. Important decreases were also observed in the other branched-chain amino acids (valine and isoleucine) in the LPS- and IL-1-treated animals. Isolated incubated muscles from TNF- and IL-1-treated rats did not show any changes in the rate of leucine utilization, thus suggesting that the mechanism by which the cytokines stimulate whole-body leucine oxidation is not based on an increase in the activity of the enzymatic machinery responsible for leucine oxidation. Additionally, glucocorticoids do not seem to mediate the enhanced in vivo oxidation of the amino acid since, although they are increased by both LPS and cytokines, treatment of the animals with RU486 (a glucocorticoid antagonist) was not able to suppress the effects of the cytokine on in vivo leucine oxidation.