Accumulation of BNP7787 in human renal proximal tubule cells.

BNP7787, an investigational drug undergoing global Phase III development, appears to have potential advantages over other cytoprotective compounds that have been evaluated for preventing and mitigating cisplatin-induced nephrotoxicity. Herein, we characterized the in vitro accumulation of BNP7787 in human renal proximal tubule cells (HK-2) in which cisplatin is known to be taken up and accumulate. HK-2 cells were incubated with pharmacological concentrations of BNP7787 for varying times. Temperature-dependent accumulation of BNP7787 in cells was observed and the BNP7787-derived metabolite, mesna, formed intracellularly was directly monitored. The peak level of BNP7787-derived mesna measured in HK-2 cells was approximately 0.6 nmol/10(6) cells; this is pharmacologically similar to reported platinum concentrations in kidney cells and may be sufficient to afford nephroprotection. Therefore, in addition to previously suggested glomerular filtration, the cellular accumulation of BNP7787 by HK-2 cells is a plausible newly identified mechanism by which BNP7787 may accumulate in renal tubular cells, where it can exert its pharmacological effects to protect against cisplatin-induced nephrotoxicity by direct covalent conjugation of mesna with cisplatin, or by the formation of BNP7787-derived mesna-disulfide heteroconjugates that exert nephroprotective effects by inhibition of the key toxification enzyme targets γ-glutamyltranspeptidase and aminopeptidase N.

Up-regulation of the Pit-2 phosphate transporter/retrovirus receptor by protein kinase C epsilon.

The membrane receptors for the gibbon ape leukemia retrovirus and the amphotropic murine retrovirus serve normal cellular functions as sodium-dependent phosphate transporters (Pit-1 and Pit-2, respectively). Our earlier studies established that activation of protein kinase C (PKC) by treatment of cells with phorbol 12-myristate 13-acetate (PMA) enhanced sodium-dependent phosphate (Na/Pi) uptake. Studies now have been carried out to determine which type of Na/Pi transporter (Pit-1 or Pit-2) is regulated by PKC and which PKC isotypes are involved in the up-regulation of Na/Pi uptake by the Na/Pi transporter/viral receptor. It was found that the activation of short term (2-min) Na/Pi uptake by PMA is abolished when cells are infected with amphotropic murine retrovirus (binds Pit-2 receptor) but not with gibbon ape leukemia retrovirus (binds Pit-1 receptor), indicating that Pit-2 is the form of Na/Pi transporter/viral receptor regulated by PKC. The PKC-mediated activation of Pit-2 was blocked by pretreating cells with the pan-PKC inhibitor bisindolylmaleimide but not with the conventional PKC isotype inhibitor Gö 6976, suggesting that a novel PKC isotype is required to regulate Pit-2. Overexpression of PKCepsilon, but not of PKCalpha, -delta, or -zeta, was found to mimic the activation of Na/Pi uptake. To further establish that PKCepsilon is involved in the regulation of Pit-2, cells were treated with PKCepsilon-selective antisense oligonucleotides. Treatment with PKCepsilon antisense oligonucleotides decreased the PMA-induced activation of Na/Pi uptake. These results indicate that PMA-induced stimulation of Na/Pi uptake by Pit-2 is specifically mediated through activation of PKCepsilon.

Entry of amphotropic murine leukemia virus is influenced by residues in the putative second extracellular domain of its receptor, Pit2.

Human cells express distinct but related receptors for the gibbon ape leukemia virus (GALV) and the amphotropic murine leukemia virus (A-MuLV), termed Pit1 and Pit2, respectively. Pit1 is not able to function as a receptor for A-MuLV infection, while Pit2 does not confer susceptibility to GALV. Previous studies of chimeric receptors constructed by interchanging regions of Pit1 and Pit2 failed to clarify the determinants unique to Pit2 which correlate with A-MuLV receptor function. In order to identify which regions of Pit2 are involved in A-MuLV receptor function, we exchanged the putative second and third extracellular domains of Pit1, either individually or together, with the corresponding regions of Pit2. Our functional characterization of these receptors indicates a role for the putative second extracellular domain (domain II) in A-MuLV infection. We further investigated the influence of domain II with respect to A-MuLV receptor function by performing site-specific mutagenesis within this region of Pit2. Many of the mutations had little or no effect on receptor function. However, the substitution of serine for methionine at position 138 (S138M) in a Pit1 chimera containing domain II of Pit2 resulted in a 1,000-fold reduction in A-MuLV receptor function. Additional mutations made within domain II of the nonfunctional S138M mutant restored receptor function to nearly wild-type efficiency. The high degree of tolerance for mutations as well as the compensatory effect of particular substitutions observed within domain II suggests that an element of secondary structure within this region plays a critical role in the interaction of the receptor with A-MuLV.