Molecular mechanism of sequence-specific termination of lentiviral replication.

The central termination sequence (CTS) terminates (+) strand DNA synthesis in certain lentiviruses. The molecular mechanism underlying this event, catalyzed by equine infectious anemia virus reverse transcriptase (EIAV RT), was evaluated by pre-steady-state kinetic techniques. Time courses in nucleotide incorporation using several DNA substrates were biphasic, consistent with release of enzyme from extended DNA being the rate-limiting step for turnover. While the burst amplitude reflecting the amount of functional RT-DNA complex was sequence-dependent, rate constants for initial product formation were not. Filter binding assays indicate the K(d) for CTS-containing substrate is only 2-fold higher than a random DNA and cannot account entirely for the large diminution in burst amplitudes. Measurements of processive DNA replication on a millisecond time scale indicate that the rate of polymerization is unaffected by the T(6)-tract within the CTS. However, termination products accumulate due to a substantial increase in the rate of nonproductive enzyme-nucleic acid complex formation after incorporation of four to five adenosines of a T(6)-tract within the CTS. During strand displacement synthesis through the CTS, products accumulate after incorporation of three to four adenosines. The rate of polymerization during strand displacement synthesis decreases 2-fold while the rate of nonproductive enzyme-nucleic acid complex formation is identical in the absence or presence of the displacement strand. These results have allowed us to develop a model for CTS-induced termination of (+) strand synthesis.

HIV-1 reverse transcriptase specifically interacts with the anticodon domain of its cognate primer tRNA.

The virion cores of the replication competent type 1 human immunodeficiency virus (HIV-1), a retrovirus, contain and RNA genome associated with nucleocapsid (NC) and reverse transcriptase (RT p66/p51) molecules. In vitro reconstructions of these complexes with purified components show that NC is required for efficient annealing of the primer tRNALys,3. In the absence of NC, HIV-1 RT is unable to retrotranscribe the viral RNA template from the tRNA primer. We demonstrate that the HIV-1 RT p66/p51 specifically binds to its cognate primer tRNALys,3 even in the presence of a 100-fold molar excess of other tRNAs. Cross-linking analysis of this interaction locates the contact site to a region within the heavily modified anti-codon domain of tRNALys,3.

Enhancement of bacterial gene expression by insertion elements or by mutation in a CAP-cAMP binding site.

The regulatory region (bglR) of the cryptic bgl operon was characterized by DNA sequence analysis and transcription mapping. Bgl(-)-specific transcription was found to occur in both the wild-type Bgl- and mutant Bgl+ cells. However, the steady-state level of bgl RNA was much higher in the Bgl+ mutant than in the wild-type. Activation of the bgl operon by insertion sequence-mediated bglR mutations or point mutations in bglR is therefore the result of increased transcription. The ethylmethane sulfonate-induced point mutations in bglR are alterations in a single base in the cAMP binding protein (CAP) binding site, leading to a stronger binding of the CAP-cAMP complex. The IS1 and IS5-mediated bglR mutations analyzed show that the insertion sequences can activate the bgl operon by integration 78 to 125 base-pairs upstream from the transcription initiation site. The role of the insertion sequences in activation of the bgl operon is discussed.

Chloramphenicol acetyltransferase gene of staphylococcal plasmid pC221. Nucleotide sequence analysis and expression studies.

The nucleotide sequence of the inducible chloramphenicol acetyltransferase gene (cat) of Staphylococcus aureus plasmid pC221 has been determined. The deduced primary structure for the 215 residue polypeptide (25.9 kDa) is in agreement with partial amino acid sequence data on the purified protein, previously designated as the type C variant of CAT. In common with the inducible cat elements of pC194 and B. pumilus, the 5' non-coding region of the cat of pC221 contains an inverted complementary repeat ('stem-loop' or 'hairpin') which may sequester the predicted ribosome bonding site of the mRNA. The likely transcription initiation site has been determined in vitro using purified B. subtilis RNA polymerase. Recombinant plasmids carrying the cat of pC221 on a 1156 bp TaqI fragment are expressed inefficiently in Escherichia coli, wherein induction is both poor and orientation-specific.

Nucleotide sequences that signal the initiation of transcription and translation in Bacillus subtilis.

We have determined the nucleotide sequence of two Bacillus subtilis promoters (veg and tms) that are utilized by the principal form of B. subtilis RNA polymerase found in vegetative cells (sigma 55-RNA polymerase) and have compared our sequences to those of several previously reported Bacillus promoters. Hexanucleotide sequences centered approximately 35 (the "--35" region) and 10 (the "--10" region) base pairs upstream from the veg and tms transcription starting points (and separated by 17 base pairs) corresponded closely to the consensus hexanucleotides (TTGACA and TATAAT) attributed to Escherichia coli promoters. Conformity to the preferred --35 and --10 sequences may not be sufficient to promote efficient utilization by B. subtilis RNA polymerase, however, since three promoters (veg, tms and E. coli tac) that conform to these sequences and that are utilized efficiently by E. coli RNA polymerase were used with highly varied efficiencies by B. subtilis RNA polymerase. We have also analyzed mRNA sequences in DNA located downstream from eight B. subtilis chromosomal and phage promoters for nucleotide sequences that might signal the initiation of translation. In accordance with the rules of McLaughlin, Murray and Rabinowitz (1981), we observe mRNA nucleotide sequences with extensive complementarity to the 3' terminal region of B. subtilis 16S rRNA, followed by an initiation codon and an open reading frame.