Functional activity of the two promoters of the myosin alkali light chain gene in primary muscle cell cultures: comparison with other muscle gene promoters and other culture systems.

Proximal upstream flanking sequences of the mouse myosin alkali light chain gene encoding MLC1F and MLC3F, the mouse alpha-cardiac actin gene and the chicken gene for the alpha-subunit of the acetylcholine receptor were linked to the bacterial chloramphenicol acetyl transferase (CAT) gene and transfected into primary cultures derived from mouse skeletal muscle or into myogenic cell lines. We demonstrate that the mouse MLC1F/MLC3F gene has two functional promoters. In primary muscle cultures, a 1200 bp sequence flanking exon 1 (MLC1F) and a 438 bp sequence flanking exon 2 (MLC3F) direct CAT activity in myotubes, but not in myoblasts or in non myogenic 3T6 and CV1 cells. Developmentally regulated expression is also seen with the alpha-cardiac actin (320 bp) and acetylcholine receptor alpha-subunit (850 bp) upstream sequences in the primary culture system. Transfection experiments with myogenic cell lines show different results with a given promoter construct, reflecting possible differences in the levels of regulatory factors between lines. Different muscle gene promoters behave differently in a given cell line, suggesting different regulatory factor requirements between these promoters.     

Bacteriophage T4 early promoter regions. Consensus sequences of promoters and ribosome-binding sites

Twenty-nine early promoters from bacteriophage T4 and 14 early promoters from bacteriophage T6 were isolated using vector M13HDL17, a promoterless derivative of M13mp8 carrying a linker sequence, the bacteriophage lambda-terminator tR1, and the lacZ' gene including part of its ribosome-binding site. The consensus sequence for the T4 promoters is: (sequence; see text). Ribosome-binding sites of T4 share the sequence: 5'...g.GGAga..aA.ATGAa.a...3' The consensus sequence of the T4 early promoter regions is significantly different in sequence and length from that of Escherichia coli promoters. Only one of the promoters detected with vector M13HDL17 resembled a typical bacterial promoter. The high information content raises the possibility that additional proteins recognize and contact nucleotides within the promoter region. All T4 early promoters also carry DNA sequences that could support DNA curving, a structural feature that might contribute to promoter recognition.     

DNA sequence heterogeneity in the genes of T-even type Escherichia coli phages encoding the receptor recognizing protein of the long tail fibers

Summary Genes (g) 36 and 37 code for the proteins of the distal half of the long tail fibers of phage T4, gene product (gp) 35 links the distal half to the proximal half of this fiber. The receptor, lipopolysaccharide, most likely is recognized by gp37. Using as probe a restriction fragment consisting of most of g36 and g37 of phage T4 the genes corresponding to g35, g36, and g37 of phages T2 and K3 (using the E. coli outer membrane proteins OmpF and OmpA, respectively, as receptors) have been cloned into plasmid pUC8. Partial DNA sequences of g37 of phage K3 have been determined. One area, corresponding to residues 157 to 210 of the 1026 residue gp37 of phage T4, codes for an identical sequence in phage K3. Another area corresponds to residues 767 to 832 of the phage T4 sequence. Amino acid residues 767 to 832 of the phage T4 sequence are almost identical in both phage proteins while the remainder is rather different. DNAs of T2, T4, T6, another T-even type phage using protein Tsx as a receptor, and 10 different T-even type phages using the OmpA protein as a receptor have been hybridized with restriction fragments covering various parts of the g37 area of phage K3. With probably only one exception all of the 13 phages tested possess unique genes 37 and within the majority of these, sequences highly homologous to parts of g37 of K3 are present in a mosaic type fashion. Other regions of these genes 37 did not show any homology with the K3 probes; in case of the OmpA specific phage M1 absence of homology was evident in most of its g37 even including the area that should serve for recognition of the cellular receptor. In sharp contrast to this situation it was found that a major part of the gene (g23) coding for the major capsid protein is rather highly conserved in all phages studied. The extreme variability in sequences existing in genes 37 might be a consequence of phages during evolution being able to more or less drastically change their receptor specifities.     

Bacteriophage T4 encodes an RNase H which removes RNA primers made by the T4 DNA replication system in vitro.

RNase H activity increases markedly after bacteriophage T4 infection of Escherichia coli MIC2003, an RNase H-deficient host. We have extensively purified the RNase H from these T4-infected cells and have shown that the RNase H activity copurifies with a 5' to 3' DNA exonuclease activity. The N-terminal sequence of a 35-kDa protein copurifying with the RNase H activity matches the terminus of the predicted product of an open reading frame (designated ORF A or 33.2) upstream of T4 gene 33, identified previously by Hahn and co-workers (Hahn, S., Kruse, U., and Rüger, W. (1986) Nucleic Acids Res. 14, 9311-9327). Plasmids containing ORF A under the control of the T7 promoter express RNase H and 5' to 3' DNA exonuclease activities as well as a protein that comigrates on sodium dodecyl sulfate-polyacrylamide gels with the 35-kDa protein present in the RNase H purified from T4-infected cells. T4 RNase H removes the pentamer RNA primers from DNA chains initiated by the T4 primase-helicase (gene products 61 and 41). Addition of T4 RNase H and T4 DNA ligase leads to extensive joining of discontinuous lagging strand fragments in the T4 DNA replication system in vitro.     

Complete genomic sequence of the virulent Salmonella bacteriophage SP6

We report the complete genome sequence of enterobacteriophage SP6, which infects Salmonella enterica serovar Typhimurium. The genome contains 43,769 bp, including a 174-bp direct terminal repeat. The gene content and organization clearly place SP6 in the coliphage T7 group of phages, but there is approximately 5 kb at the right end of the genome that is not present in other members of the group, and the homologues of T7 genes 1.3 through 3 appear to have undergone an unusual reorganization. Sequence analysis identified 10 putative promoters for the SP6-encoded RNA polymerase and seven putative rho-independent terminators. The terminator following the gene encoding the major capsid subunit has a termination efficiency of about 50% with the SP6-encoded RNA polymerase. Phylogenetic analysis of phages related to SP6 provided clear evidence for horizontal exchange of sequences in the ancestry of these phages and clearly demarcated exchange boundaries; one of the recombination joints lies within the coding region for a phage exonuclease. Bioinformatic analysis of the SP6 sequence strongly suggested that DNA replication occurs in large part through a bidirectional mechanism, possibly with circular intermediates.     

Role of precursor sequences in the ordered maturation of E. coli 23S ribosomal RNA

The maturation of ribosomal RNAs (rRNAs) is an important but incompletely understood process required for rRNAs to become functional. In order to determine the enzymes responsible for initiating 3' end maturation of 23S rRNA in Escherichia coli, we analyzed a number of strains lacking different combinations of 3' to 5' exo-RNases. Through these analyses, we identified RNase PH as a key effector of 3' end maturation. Further analysis of the processing reaction revealed that the 23S rRNA precursor contains a CC dinucleotide sequence that prevents maturation from being performed by RNase T instead. Mutation of this dinucleotide resulted in a growth defect, suggesting a strategic significance for this RNase T stalling sequence to prevent premature processing by RNase T. To further explore the roles of RNase PH and RNase T in RNA processing, we identified a subset of transfer RNAs (tRNAs) that contain an RNase T stall sequence, and showed that RNase PH activity is particularly important to process these tRNAs. Overall, the results obtained point to a key role of RNase PH in 23S rRNA processing and to an interplay between this enzyme and RNase T in the processing of different species of RNA molecules in the cell.