Mouse hepatitis virus nucleocapsid protein as a translational effector of viral mRNAs.

The mouse hepatitis virus (MHV) nucleocapsid protein stimulated translation of a chimeric reporter mRNA containing an intact MHV 5'-untranslated region and the chloramphenicol acetyltransferase (CAT) coding region. The nucleocapsid protein binds specifically the tandemly repeated-UCYAA- of the MHV leader. This RNA sequence is the same as the intergenic motif found in the genome RNA. Preferential translation of viral mRNA in MHV infected cells is stimulated in part by this interaction and represents a specific, positive translational control mechanism employed by coronaviruses.

Restoration of wild-type p53 activity in p53-null HL-60 cells confers multidrug sensitivity.

HL-60 cells that stably express transfected wild-type (wt) p53 were used to determine whether restoration of wt p53 increased the chemosensitivity of cells that normally lack p53 activity. The wt p53 HL-60 transfectants (SN3 cells) were more sensitive than the parental (S) cells to a number of common anticancer drugs representing various mechanisms of action, whereas HL-60 cells transfected with p53 genes mutated at codons 248 and 143 were not sensitized. The sensitization ratio due to the transfected wt p53 varied from about 2-fold for cisplatin to over 50-fold for thymidine. Cells treated with the thymidylate synthase inhibitor 5-fluoro-2'-deoxyuridine (FdUrd) were used to study changes in various p53-associated gene expressions. A higher percentage of apoptotic cells among the SN3 cells was observed than among the S cells at each concentration of FdUrd. The S cells had undetectable levels of bax and high levels of bcl-2, whereas the SN3 cells had undetectable levels of bcl-2 levels and appreciable basal levels of bax. After FdUrd treatment of SN3 cells, both p53 and bax levels increased, but the induction of bax was faster than that of p53 and paralleled the appearance of apoptotic DNA laddering. FdUrd treatment induced p21 expression and increased the G1 fraction of the SN3 cells but did not induce p21 or change the phase distribution in the S cells. FdUrd treatment also induced the expression and phosphorylation of cyclin D1 in the SN3 cells but not in the S cells. These results show that transfected wt p53 confers multidrug sensitivity to HL-60 cells by re-adjustment of the expressions of apoptosis genes and displays other properties characteristic of endogenously originated wt p53.

Transfection of wild-type but not mutant p53 induces early monocytic differentiation in HL60 cells and increases their sensitivity to stress.

HL60 cells, which lack the p53 gene due to a deletion, were used as an in vitro model system to study the effect of wild-type p53 gene expression on hematopoietic differentiation. We transfected HL60 cells with wild-type p53 and two mutant p53 cDNAs encoding the Val to Ala mutation at codon 143 and the Arg to Trp mutation at codon 248. Flow cytometry, growth, and cytochemical analysis for alpha-napthyl butyrate esterase activity and nitroblue tetrazolium reduction indicated that wild-type p53 but not mutant p53 induced early monocytic differentiation in the transfected HL60 cells without terminal growth arrest. The wild-type p53 transfectants did not differentiate along the granulocytic pathway, even when induced with 1.25% DMSO for 6 days; rather, these cells resembled monocytic cells, confirming that wild-type p53 transfection caused these cells to become committed to differentiate along the monocytic pathway. HL60 cells transfected with wild-type p53 were more sensitive to stress, such as growth in serum-depleted medium and exposure to a chemotherapeutic agent, etoposide.

Incorporation of 5-fluorouracil into U2 and U6 snRNA inhibits mRNA precursor splicing.

The splicing activities of 5-fluorouracil (FUra)-substituted U2 and U6 small nuclear RNAs (snRNAs) were examined in an in vitro splicing system. Yeast splicing extracts were specifically depleted of endogenous U2 and U6 snRNAs by antisense oligonucleotide-directed RNase H hydrolysis. Splicing activity was recovered when the extracts were reconstituted with synthetic U2 and U6 snRNAs. However, U2 snRNA with all uracils substituted with FUra (FU2) did not restore any splicing activity. Nondenaturing gel electrophoresis showed that FU2 failed to promote the assembly of spliceosome complexes. The ability of U2 snRNA to restore splicing in U2-depleted extracts increased as FUra content decreased but was still only 60% of control activity at 25% substitution of uracils with FUra. Addition of FU2 to nondepleted extracts caused strong inhibition of splicing accompanied by increased degradation of the pre-mRNA, suggesting that FU2 forms an inactive complex with a protein splicing factor that normally binds to the pre-mRNA. FU6 restored full splicing activity to U6-depleted extracts, but at a 5-fold higher concentration than U6 snRNA. These results demonstrate that the incorporation of FUra can impair the functions of catalytic RNA molecules.