Faculty Bibliography

In Escherichia coli, the workhorse of molecular biology, a single operon is involved in the replication, transcription and translation of genetic information. This operon is controlled in a complex manner involving multiple cis-acting regulatory sequences and trans-acting regulatory proteins. It interacts with global regulatory networks by mechanisms which are presently being dissected

The Escherichia coli rpsU-dnaG-rpoD operon contains an internal transcription terminator T1 located in the intergenic region between the rpsU and dnaG genes (Smiley et al. 1982). By cloning T1 as a small 127 bp fragment into the terminator probe plasmid pDR720 between the trp operator promoter and the assayable galK gene, it was shown that T1 acts as a strong transcription terminator, comparable in strength to the 3' operon terminator T2. However, an operon sequence that occurs 5' to T1 within the coding region of the rpsU gene and which has homology with the lambda nut site, (Lupski et al. 1983) when placed 5' to T1 in the pDR720 plasmid construct, modifies transcription through T1 allowing expression of the galK gene. This sequence, called the dnaG nut site also modifies the termination activity of the external operon terminator T2. It is proposed that the dnaG nut site is a cis-acting element of an antitermination system in E. coli

Bal31 exonuclease deletion analysis and transposon Tn5 mutagenesis of the 5' regulatory region of the rpsU-dnaG-rpoD macromolecular synthesis operon fused to the chloramphenicol acetyltransferase gene (pGLR301) demonstrated that sequences 5' to the operon promoters were not involved in operon transcriptional regulation and that the three tandem promoters P1, P2, and P3 were functionally independent. P2 was the strongest promoter, and P3 was the weakest. P1, P2, and P3 acting in combination appeared to be stronger than the individual promoters

Phage G4 origin of complementary DNA strand synthesis (oric) consists of three stable stem-loop structures (I, II, and III). Mutant oric sequences with alterations in the structure of stem-loop II, stem-loop III, and the stem-loop II-III spacer region have been constructed and cloned into the filamentous phage vectors to assay their functional activity. Changes in the lowermost GC base pair in the stem of stem-loop III, in the 9-bp spacer region between the stems of stem-loops II and III, and in the loop of stem-loop II, impair or abolish in vivo oric function. The results suggest that recognition sequences for dnaG primase must be present in the loop of stem-loop II, and in the spacer region between the stems of stem-loops II and III

To investigate the mechanisms regulating the stage specific expression of the Plasmodium knowlesi circumsporozoite (CS) antigen gene, the sporozoite genomic DNA copy of the CS gene has been isolated and compared with the blood stage genomic DNA and the sporozoite cDNA copies. The genomic DNA sequences of the two developmental stages are identical across 4 kilobase pairs of the chromosome containing the entire CS gene transcriptional unit. From restriction enzyme mapping no DNA rearrangements over 15 kilobase pairs of the chromosome containing the CS gene appear to be involved in its stage-specific expression and its regulation appears to be at the level of transcription or RNA stability. S1 nuclease and primer extension transcript mapping studies suggest that the CS mRNA has multiple start sites, that the leader sequence is devoid of introns, and is approximately 270 bases long. Consensus eukaryotic TATA and CAAT box sequences and potential regulatory elements, including sequences highly homologous to the reiterated and core enhancer sequences of SV40 precede the gene.

Phage G4 origin of complementary DNA strand synthesis (oric) consists of three stable secondary loop structures. In a cloned 274-bp DNA fragment that is active as an ori in the filamentous phage cloning vector R199, insertion mutants have been constructed by introducing EcoRI and HindIII linkers at the base of loop III. The in vivo activity of these oric mutants (conversion of single-strand form to replicative form in the presence of rifampicin) was significantly reduced (50-70%) but not completely abolished. Nucleotide sequences and/or potential secondary structure of loop III centered at the AvaII site are therefore an important functional part of oric

The complete nucleotide sequence of 5-kb DNA fragment immediately 5' to the rpsU-dnaG-rpoD macromolecular-synthesis operon in Escherichia coli has been determined. It encodes for six open reading frames. Transcriptional and translational analysis have shown that three of them (orfx, orfz1 and orfz2) are expressed in exponentially growing E. coli cells. The orfx, directly 5' to the rpsU gene but transcribed in the opposite direction, may be part of the rpsU-dnaG-rpoD macromolecular-synthesis operon

In the process of randomly mutagenizing a recombinant pBR322 clone with transposon Tn5, a high copy number plasmid mutant, pLO88, has been isolated. The copy number phenotype of pLO88 is observed only at elevated temperatures, greater than or equal to 37 degrees C, and is due to the precise position of a Tn5 insertion. Nucleotide sequence of the Tn5-pBR322 junction reveals that Tn5-88 has inserted into an open reading frame that codes for a 63 amino acid protein previously shown to negatively regulate pBR322 plasmid copy number. By deleting portions of the Tn5 it is shown that the copy number phenotype is due not only to the insertion of Tn5 in pBR322 but also to the requirement that some Tn5 sequences remain intact. It appears that an outwardly directed Tn5 promoter initiates the synthesis of a transcript (RNA X) that interferes with the normal repressor RNA (RNA I)-primer RNA (RNA II) interaction at elevated temperatures

The circumsporozoite (CS) protein of the Nuri strain of the simian malarial parasite Plasmodium knowlesi was expressed as a fusion protein in E. coli. This fusion protein cross-reacted with the polyclonal monkey sera raised against irradiated sporozoites of another strain (H strain) of P. knowlesi. The antibody against the repeat units of the H strain CS protein was affinity purified from the polyclonal sera by using synthetic repeat peptides. The affinity-purified antibody did not cross-react with the Nuri CS fusion protein. The immunogenicity of different regions of the CS protein was additionally studied by using several synthetic peptides. All but the most COOH-terminal peptide showed cross-reactivity with the polyclonal sera. Because the repeat regions of the CS protein of the two strains are diverse, whereas the non-repetitive regions are immunogenic and conserved, the latter may be better suited for a potential vaccine

The Escherichia coli cca gene which encodes the enzyme tRNA nucleotidyltransferase has been cloned by taking advantage of its proximity to the previously cloned dnaG locus. A series of recombinant bacteriophages, spanning the chromosomal region between the dnaG and cca genes at 66 min on the E. coli linkage map, were isolated from a lambda Charon 28 partial Sau3A E. coli DNA library using recombinant plasmids containing regions between dnaG and cca as probes. Two of the recombinant phage isolates, lambda c1 and lambda c4, contained the cca gene. A BamHI fragment from lambda c1 was subcloned into pBR328, and cells containing this recombinant plasmid, pRH9, expressed tRNA nucleotidyltransferase activity at about 10-fold higher level than the wild type control. The cca gene was further localized to a 1.4-kilobase stretch of DNA by Bal31 deletion analysis. The nucleotide sequence of the cca gene was determined by the dideoxy method, and revealed an open reading frame extending for a total of 412 codons from an initiator GTG codon that would encode a protein of about 47,000 daltons. Southern analysis using genomic blots demonstrated that the cca gene is present as a single copy on the E. coli chromosome and that there is no homology on the DNA level between the E. coli cca gene, and the corresponding gene in the Bacillus subtilis, Saccharomyces cerevisiae, Petunia hybrida, or Homo sapiens genomes. Homology was found only with DNA from the closely related species, Salmonella typhimurium. These studies have also allowed exact placement of the cca gene on the E. coli genetic map, and have shown that it is transcribed in a clockwise direction