Anticancer peptide PNC-27 adopts an HDM-2-binding conformation and kills cancer cells by binding to HDM-2 in their membranes

The anticancer peptide PNC-27, which contains an HDM-2-binding domain corresponding to residues 12-26 of p53 and a transmembrane-penetrating domain, has been found to kill cancer cells (but not normal cells) by inducing membranolysis. We find that our previously determined 3D structure of the p53 residues of PNC-27 is directly superimposable on the structure for the same residues bound to HDM-2, suggesting that the peptide may target HDM-2 in the membranes of cancer cells. We now find significant levels of HDM-2 in the membranes of a variety of cancer cells but not in the membranes of several untransformed cell lines. In colocalization experiments, we find that PNC-27 binds to cell membrane-bound HDM-2. We further transfected a plasmid expressing full-length HDM-2 with a membrane-localization signal into untransformed MCF-10-2A cells not susceptible to PNC-27 and found that these cells expressing full-length HDM-2 on their cell surface became susceptible to PNC-27. We conclude that PNC-27 targets HDM-2 in the membranes of cancer cells, allowing it to induce membranolysis of these cells selectively.

Biotin-Dependent Carboxylase Activities in Different CNS and Skin-Derived Cells, and their Sensitivity to Biotin-Depletion

The validity of various transformed and untransformed CNS and skin-derived cell cultures as a model for studying effects of biotin deficiency was tested. In biotin-sufficient conditions (0.1–10 mumol/L) all cell types showed considerable activities of the four biotin-dependent carboxylases. Notably, pyruvate carboxylase activity was also present in the different neuronal cells. One passage in low-biotin medium (6 –130 pmol/L) lowered mitochondrial carboxylase activities in all cell types, but to varying degrees. Sensitivity to biotin depletion was greatest in three neuronal cell types, Roc-1 oligodendroglia, and three keratinocyte cell types (carboxylase activities decreased to 2–11% of maximal); intermediate in primary astrocytes and C6 glioma (decreased to 12–28%), and least in SAOS2 sarcoma and skin fibroblasts (decreased to 32–85%). Transformed and untransformed cell lines of the same cell type showed similar sensitivity. We conclude that cultures of different transformed CNS and keratinocyte cell types allow the study of effects of biotin deprivation. Carboxylase activities of neurons, oligodendroglia, and keratinocytes were much more sensitive to biotin depletion than fibroblasts. This may be an important factor in the pathogenesis of neurological and cutaneous abnormalities in congenital biotinidase deficiency where recycling of biotin is deficient.

Elevated recombination in immortal human cells is mediated by HsRAD51 recombinase.

Normal diploid cells have a limited replicative potential in culture, with progressively increasing interdivision time. Rarely, cell lines arise which can divide indefinitely; like tumor cells, such "immortal" lines display frequent chromosomal aberrations which may reflect high rates of recombination. Recombination frequencies within a plasmid substrate were 3.5-fold higher in nine immortal human cell lines than in six untransformed cell strains. Expression of HsRAD51, a human homolog of the yeast RAD51 and Escherichia coli recA recombinase genes, was 4.5-fold higher in immortal cell lines than in mortal cells. Stable transformation of human fibroblasts with simian virus 40 large T antigen prior to cell immortalization increased both chromosomal recombination and the level of HsRAD51 transcripts by two- to fivefold. T-antigen induction of recombination was efficiently blocked by introduction of HsRAD51 antisense (but not control) oligonucleotides spanning the initiation codon, implying that HsRAD51 expression mediates augmented recombination. Since p53 binds and inactivates HsRAD51, T-antigen-p53 association may block such inactivation and liberate HsRAD51. Upregulation of HsRAD51 transcripts in T-antigen-transformed and other immortal cells suggests that recombinase activation can also occur at the RNA level and may facilitate cell transformation to immortality.

Both acidic-type and neutral-type asparaginyl-oligosaccharides of host-cell glycoproteins are altered in Rous-sarcoma-virus-transformed chick-embryo fibroblasts

In comparisons of [3H]mannose-labelled glycopeptides from chick-embryo fibroblasts infected and transformed with non-defective Prague C Rous-sarcoma virus and from untransformed fibroblasts infected with a transformation-defective derivative of Prague C Rous-sarcoma virus, we have detected transformation-dependent alterations in both the acidic-type and the neutral-type asparagine-linked oligosaccharides of cellular glycoproteins. Pronase-digested glycopeptides were analysed by the combined techniques of gel filtration, exo- and endo-glycosidase digestion and concanavalin A-agarose affinity chromatography. The transformed cell glycoproteins contained more sialic acid and were enriched for more highly branched (versus biantennary) acidic-type structures compared with the untransformed cell glycoproteins, similarly to previously reported transformation-dependent alterations. In addition, the glycopeptides from the virus-transformed cells contained several neutral-type structures that were apparently absent from the untransformed cells: small neutral-type oligosaccharides (Man3GlcNAc2) that were sensitive to endo-beta-N-acetylglucosaminidase D but resistant to endo-beta-N-acetylglucosaminidase H, and oligosaccharides with the property of ‘truncated’ precursor oligosaccharides (endoglycosidase-resistant, alpha-mannosidase-sensitive). Endoglycosidase-released oligosaccharides with the properties of hybrid-type structures were derived from the glycoproteins of both transformed and untransformed cells.

The role of negative charge in spontaneous aggregation of transformed and untransformed cell lines

No correlation between net negative surface charge as determined by electrophoretic light-scattering techniques and the rates of spontaneous aggregation of 3T3MIT and SVPy 3T3MIT cells has been found. Neuraminidase treatment of both 3T3MIT cells and SVPy 3T3MIT cells causes a significant decrease in electrophoretic mobility but only the 3T3MIT cells show an increase in spontaneous aggregation. An increase in spontaneous aggregation of 3T3MIT cells is seen after growth in 200 mM urea for 18 h but no change in net surface charge occurs. The distribution of anionic sites on the membranes of cells was determined using the ultrastructural marker polycationized ferritin. The distribution of polycationized ferritin-binding sites was essentially identical for both cell lines under all conditions when they were labelled at 4 degrees C. When the cells were labelled with polycationized ferritin at 37 degrees C it was found that cells which have a high net rate of spontaneous aggregation also show rearrangement of anionic sites on their surface membrane. Clustering and rearrangement of anionic sites at 37 degrees C correlate with high rates of spontaneous aggregation.