Molecular basis for the actions of Hsp90 inhibitors and cancer therapy.

Heat-shock protein 90 (Hsp90) inhibitor downregulates c-Myc expression and upregulates the expression of tumor repressor proteins such as p53 and pRB, inhibiting the G1/S transition and causing G2/M arrest during cell cycle progression. The cycle progression is extensively controlled by the pRB/E2F signaling pathway. E2F is released from the pRB/E2F complex with the phosphorylation of pRB by cyclin-cyclin-dependent kinase (CDK) complexes. The released E2F promotes the transcription of target genes involved in cell cycle progression. The pRB/E2F signaling pathway is controlled by DNA methyltransferase-1 (Dnmt-1). The elevated expression of Dnmt-1 has been reported in carcinomas of the colon, lung and prostate. A defect of pRB expression in Rb -/- cancer cells is caused by the aberrant methylation of CpG in the Rb promoter. The Hsp90 inhibitor disrupts the Dnmt-1/Hsp90 association and upregulates pRB expression. In this review, the Hsp90 inhibitors that show promise for cancer therapy are summarized.

Inhibition of septation in Bacillus subtilis by a peptide antibiotic, edeine B(1).

A peptide antibiotic, edeine B(1), exerts a lethal action in Bacillus subtilis causing filamentous morphology. This antibiotic assumes to inhibit cell division by interacting with FtsZ and inhibiting FtsZ polymerization. The temperature-sensitive mutant ftsZ ts1 was shown to be hypersensitive to the antibiotic as compared to the parent 168 with respect to its lethal action and the sensitivity to the antibiotic of the revertant of ftsZ ts1 was shown to be intermediate between those of the parent 168 and the ftsZ ts1. Alteration of FtsZ sequence may be responsible for sensitivity to edeine B(1). The residues at 240, 278, 345 and 346 in the FtsZ sequence of the parent 168 were A240, A278, D345 and A346. Those of ftsZ ts1 were V240, V278, E345 and P346. Those of the revertant of ftsZ ts1 were A240, A278, E345 and P346. The difference in sensitivity to edeine B(1) among these strains is presumably due to the difference in the residues at 240, 278, 345 and 346 in the FtsZ sequence. The sequential events of the inhibition of FtsZ assembly and the inhibition of protein biosynthesis by edeine B(1) may progress synergistically, resulting in cell death.

Genetic analysis of hepatitis C virus with defective genome and its infectivity in vitro.

Replication and infectivity of hepatitis C virus (HCV) with a defective genome is ambiguous. We molecularly cloned 38 HCV isolates with defective genomes from 18 patient sera. The structural regions were widely deleted, with the 5' untranslated, core, and NS3-NS5B regions preserved. All of the deletions were in frame, indicating that they are translatable to the authentic terminus. Phylogenetic analyses showed self-replication of the defective genomes independent of full genomes. We generated a defective genome of chimeric HCV to mimic the defective isolate in the serum. By using this, we demonstrated for the first time that the defective genome, as it is circulating in the blood, can be encapsidated as an infectious particle by trans complementation of the structural proteins.

Gerbils of a seizure-sensitive strain have a mitochondrial inner membrane protein with different isoelectric points from those of a seizure-resistant strain.

The distribution of proteins in the cerebral cortex of a seizure-sensitive (SS) strain of gerbil and its seizure-resistant (SR) counterpart was profiled using two-dimensional gel electrophoresis. A series of proteins of similar molecular weight (around 83 kDa) showed small but consistent differences in their isoelectric point (pI) with indistinguishable profiles of distribution between the two strains. Amino acid sequences of peptides produced by limited proteolysis of each protein in the spots from the strains were identical or highly homologous to those of mitofilin, a mitochondrial inner membrane protein (IMMT) in humans. Analysis of cDNA sequences revealed the proteins of these spots to be gerbil mitofilin-like proteins (gIMMT), with a few base substitutions between SS and SR strains, in particular within a region near a putative transmembrane domain that is highly conserved in humans and gerbils. The amino acid at the site was acidic, Glu in humans and Asp in the strain SR of gerbil and a neutral, Asn in strain SS. In addition to these base substitutions, production of multiple species of mRNA for gIMMT by alternative splicing was observed.