Facilitated reduction of beta-amyloid peptide precursor by synthetic oligonucleotides in COS-7 cells expressing a hammerhead ribozyme.

Synthetic deoxyoligonucleotides and phosphorothioate-capped oligonucleotides targeted to bases 112-128 of beta-amyloid peptide precursor (beta APP) mRNA were analyzed for their ability to reduce steady-state beta APP in COS-7 cells and in pMEP4-Rz1 cells that express a hammerhead ribozyme targeted to bases beta APP mRNA 133-148. Cells, incubated in the presence of 10 or 25 microM oligonucleotide, remained viable and morphologically identical to untreated control cells for up to 5 days. Antisense deoxyoligonucleotides beta 112C, beta 114C, and beta 116C specifically lowered beta APP in pMEP4-Rz1 cells compared to noncognate and scrambled oligonucleotide controls. The extent of the beta APP reduction did not depend on oligonucleotide length, although it did depend on the presence and proximity of the ribozyme to the oligonucleotides. beta 117N, a phosphorothioate-capped antisense oligonucleotide, also reduced beta APP levels in pMEP4-Rz1 cells; however, in this case the sense control, beta 117S, affected beta APP similarly, indicating that the observed reduction may be nonspecific. These data imply that deoxyoligonucleotides targeted immediately upstream of a ribozyme binding site can work cooperatively in vivo. Localizing the oligonucleotides and ribozyme and substrate targets to the same cellular pools further confirmed this possibility.

Reduction of histone cytotoxicity by the Alzheimer beta-amyloid peptide precursor.

In a search for Alzheimer beta-amyloid peptide precursor ligands, Potempska et al. (Arch. Biochem. Biophys. (1993) 304, 448) found that histones bind with high affinity and specificity to the secreted precursor. Because exogenous histones can be cytotoxic, we compared the effects of histones on the viability of cells which produce little beta-amyloid peptide precursor (U-937) to those on cells that produce twenty times as much precursor (COS-7). Addition of purified histones caused necrosis of U-937 cells (histone H4, LD50 = 1.5 microM). Extracellular A beta precursor in the submicromolar range prevented histone-induced U-937 cell necrosis. Cell-surface precursor also reduced histone toxicity: COS-7 cells were less sensitive to the toxic effects of histone H4 (LD50 = 5.4 microM). COS-7 cells in which the expression of an APP mRNA-directed ribozyme reduced the synthesis of the protein by up to 80% were more sensitive to histone H4 (LD50 = 3.2 microM) than cells that expressed the vector alone. Histone H4 binds to cell-associated A beta precursor. Cells expressing the A beta precursor-directed ribozyme bound less 125I-labeled histone H4 than those expressing the vector alone. In the limited extracellular space of tissues in vivo, both secreted and cell-surface A beta precursor protein may play significant roles in trapping chromatin or histones and removing them from the extracellular milieu.

Switching nucleotide specificity of Ha-Ras p21 by a single amino acid substitution at aspartate 119.

We examined c-Ha-Ras harboring an aspartate to asparagine substitution at position 119 (mutation D119N). The Asp-119 is part of the conserved NKXD motif shared by members of the regulatory GTPase family. This asparagine residue has been proposed to participate in direct bonding to the guanine ring and to determine the guanine-nucleotide binding specificity. The D119N mutation was found to alter nucleotide specificity of Ha-Ras from guanine to xanthine, an observation that directly supports the essential role of hydrogen bonding between the side chain of the aspartic acid residue and the guanine ring in nucleotide binding specificity. Besides nucleotide binding specificity, the D119N mutation has little or no effect on the interaction of Ha-Ras with SDC25C, SOS1, GAP, or Raf. Neither does it affect the hydrolysis of nucleotide triphosphate. Like xanthine-nucleotide-specific EF-Tu, xanthine-nucleotide-specific Ras and related proteins will be useful tools for elucidating cellular systems containing multiple regulatory GTPases.