Organization, expression, and function of Caulobacter crescentus genes needed for assembly and function of the flagellar hook.

This paper reports on the organization, expression, and function of the divergently transcribed flbG and flaN operons in the hook gene cluster of Caulobacter crescentus. The transcription initiation site of flbG was determined previously, and in this work the transcription map was completed by locating the 3' end of the mRNA using nuclease S1 protection assays. A previous genetic study had suggested that the flbG operon is comprised of four genes; however, the nucleotide sequence revealed three tandemly arranged ORFs that correspond to 5'-flbG, flbH, and flgE. FlbG is similar to FliK proteins which are required for termination of hook synthesis, FlbH is similar to FlgD proteins which are essential scaffolding proteins that cap the hook during its assembly, and FlgE corresponds to the hook structural protein. The divergently transcribed flaN gene codes for a hook associated protein I homolog based on its inferred amino acid sequence similarity to FlgK proteins. Based on the amino acid sequence similarities and phenotypes of mutants, flbG, flbH, and flaN have been renamed fliK, flgD, and flgK, FlgD, FlgE, and FlgK proteins, with apparent molecular masses of 23, 68, and 41 kDa, respectively, were expressed from plasmids in a cell-free coupled transcription-translation system, and a protein corresponding to FliK was identified as part of a 190-kDa FliK-LacZ fusion protein. We present evidence showing that, in addition to its role in termination of hook synthesis, FliK is also required for initiation of hook assembly.

Detection of exogenous and endogenous avian leukosis virus in commercial chicken eggs using reverse transcription and polymerase chain reaction assay.

Avian leukosis retroviruses (ALV) cause lymphomas and other cancers in chickens. Previous studies have used enzyme-linked immunosorbent assays (ELISA) and indirect immunofluorescence assays (IFA) to detect ALV p27 group-specific antigens (GSA) in commercial chicken eggs. In the poultry industry eradication programme against exogenous ALV, ELISA assays are used to identify chickens infected with the virus. The inability of ELISA and IFA assays to discriminate between ALV GSA of endogenous or exogenous origin, and actual virus, have limited rigorous assessments of viral transmission dynamics. Here, we report the use of a newly developed reverse transcriptase-polymerase chain reaction (RT-PCR) assay, with direct sequencing of the RT-PCR product, to show endogenous and exogenous ALV in albumen from unfertilized chicken eggs. We found that 95% of 20 eggs from ALV-exposed commercial chickens and 14.2% of 240 egg samples from 20 randomly chosen New Orleans retail stores were ALV-positive by RT-PCR. In comparison, only 2.5% of the same egg samples from the retail stores were positive by ELISA. Corresponding direct sequencing of randomly chosen RT-PCR products showed that four of six egg samples contained endogenous ALV, while two of the six samples were positive for exogenous subgroup A ALV. The finding of endogenous subgroup E ALV in unfertilized chicken eggs emphasizes that the transmission of endogenous ALV is common and should be considered in the implementation of ALV eradication programmes by the poultry industry.

Inhaled benzene increases the frequency and length of lacI deletion mutations in lung tissues of mice.

This study investigated the frequency and pattern of mutations that arose in lacI transgenes in lung tissues of mice exposed to 300 p.p.m. of benzene for 6 h/day x 5 days/week for 12 weeks. The nucleotide sequence changes in 86 lacI- transgenes from lung tissues of eight benzene-exposed mice (BEM) and 78 spontaneous lacI- transgenes from lung tissues of eight unexposed control mice (UCM) were identified and compared. A total of 31% (27/86) of the lacI mutations in BEM are deletions compared with 9% (7/78) deletions in UCM. In BEM, 44% (12/27) of the deletions were longer than 10 bp, whereas only 14% (1/7) of the deletions in UCM exceeded 10 bp in length. Statistical tests supported the hypothesis that benzene exposure resulted in significant increases in both the frequency and length of deletions. Based on the lacI mutant frequency and fraction of unique mutations, lung tissues of BEM were estimated to have a 1.8-fold increase in lacI mutation frequency compared with lung tissues of UCM. The results presented in this paper demonstrate that inhaled benzene is a gene mutagen in lung tissues of mice.

Genetic organization and transposition properties of IS511.

IS511 is an endogenous insertion sequence (IS) of the bacterium Caulobacter crescentus strain CB15 and it is the first Caulobacter IS to be characterized at the molecular level. We determined the 1266-bp nucleotide sequence of IS511 and investigated its genetic organization, relationship to other ISs, and transposition properties. IS511 belongs to a distinct branch of the IS3 family that includes ISR1, IS476, and IS1222, based on nucleotide sequence similarity. The nucleotide sequence of IS511 encodes open reading frames (orfs) designated here as orfA and orfB, and their relative organization and amino acid sequences of the predicted protein products are very similar to those of orfAs and orfBs of other IS3 family members. Nuclease S1 protection assays identified an IS511 RNA, and its 5' end maps approximately 16 nucleotides upstream of orfA and about six nucleotides downstream of a sequence that is similar to the consensus sequence of C. crescentus housekeeping promoters. Evidence is presented that IS511 is capable of precise excision from the chromosome, and transposition from the chromosome to a plasmid. Transpositional insertions of IS511 occurred within sequences with a relatively high G + C content, and they were usually, but not always, flanked by a 4-bp direct repeat that matches a sequence at the site of insertion. We also determined the nucleotide sequence flanking the four endogenous IS511 elements that reside in the chromosome of C. crescentus. Our findings demonstrate that IS511 is a transposable IS that belongs to a branch of the IS3 family.

Inhalation of benzene leads to an increase in the mutant frequencies of a lacI transgene in lung and spleen tissues of mice.

The goal of this study was to determine if inhalation of benzene leads to an increase in the mutant frequencies in the tissues of male C57BL/6 mice. Mutant frequencies were measured using a previously described assay in which bacteriophage lambda lacI transgenes are rescued from mouse genomic DNA as infectious phage and scored for their LacI phenotype. Eight experimental mice were exposed to a target concentration of 300 ppm of benzene for 6 h/day x 5 days/week x 12 weeks, and eight control mice were treated similarly except that they were not exposed to benzene. Mutant frequencies were calculated as the ratio of LacI-/total phage recovered from organs of interest. The mean mutant frequency measured in lung tissues of mice exposed to benzene was (10.6 +/- 1.4) x 10(-5), which is about 1.7-fold higher than that of the unexposed controls. In spleen tissues from benzene-exposed mice the mean mutation frequency was (12.6 +/- 4.1) x 10(-5), which is about 1.5-fold higher than that of spleen tissues from unexposed controls. The differences in mean mutant frequencies between benzene-exposed and unexposed lung and spleen tissues are statistically significant. In liver tissues, however, the mean mutant frequencies of benzene-exposed mice and unexposed mice are not significantly different. These results demonstrate that inhaled benzene results in a statistically significant increase in the mutant frequencies in lung and spleen, but not in liver tissues of mice.

FlbD has a DNA-binding activity near its carboxy terminus that recognizes ftr sequences involved in positive and negative regulation of flagellar gene transcription in Caulobacter crescentus.

FlbD is a transcriptional regulatory protein that negatively autoregulates fliF, and it is required for expression of other Caulobacter crescentus flagellar genes, including flaN and flbG. In this report we have investigated the interaction between carboxy-terminal fragments of FlbD protein and enhancer-like ftr sequences in the promoter regions of fliF, flaN, and flbG. FlbDc87 is a glutathione S-transferase (GST)-FlbD fusion protein that carries the carboxy-terminal 87 amino acids of FlbD, and FlbDc87 binds to restriction fragments containing the promoter regions of fliF, flaN, and flbG, whereas a GST-FlbD fusion protein carrying the last 48 amino acids of FlbD failed to bind to these promoter regions. DNA footprint analysis demonstrated that FlbDc87 is a sequence-specific DNA-binding protein that makes close contact with 11 nucleotides in ftr4, and 6 of these nucleotides were shown previously to function in negative regulation of fliF transcription in vivo (S. M. Van Way, A. Newton, A. H. Mullin, and D. A. Mullin, J. Bacteriol. 175:367-376, 1993). Three DNA fragments, each carrying an ftr4 mutation that resulted in elevated fliF transcript levels in vivo, were defective in binding to FlbDc87 in vitro. We also found that a missense mutation in the recognition helix of the putative helix-turn-helix DNA-binding motif of FlbDc87 resulted in defective binding to ftr4 in vitro. These data suggest that the binding of FlbDc87 to ftr4 is relevant to negative transcriptional regulation of fliF and that FlbD functions directly as a repressor. Footprint analysis showed that FlbDc87 also makes close contacts with specific nucleotides in ftr1, ftr2, and ftr3 in the flaN-flbG promoter region, and some of these nucleotides were shown previously to be required for regulated transcription of flaN and flbG (D. A. Mullin and A. Newton, J. Bacteriol. 175:2067-2076, 1993). Footprint analysis also revealed a new ftr-like sequence, ftr5, at -136 from the transcription start site of flbG. Our results demonstrate that FlbD contains a sequence-specific DNA-binding activity within the 87 amino acids at its carboxy terminus, and the results suggest that FlbD exerts its effect as a positive and negative regulator of C. crescentus flagellar genes by binding to ftr sequences.

A sigma 54 promoter and downstream sequence elements ftr2 and ftr3 are required for regulated expression of divergent transcription units flaN and flbG in Caulobacter crescentus.

In this study, we investigated the cis-acting sequences required for transcription of the divergent, cell cycle-regulated flaN and flbG operons of Caulobacter crescentus. Previous work showed that transcription of flbG in vivo depends on a sigma 54 promoter and a sequence element called ftr1 that is located about 100 bp upstream from the transcription start site (D. A. Mullin and A. Newton, J. Bacteriol. 171:3218-3227, 1989). We now show that regulation of flaN transcription in vivo depends on a sigma 54 promoter and two ftr elements located downstream of the transcription start site at +86 (ftr2) and +120 (ftr3). Mutations in or between the conserved elements at -24 and -12 in this sigma 54 promoter reduced or abolished flaN transcription, and one mutation that eliminated flaN expression led to an increased level of flbG transcript. Mutations in ftr2 resulted in greatly reduced levels of flaN transcript but had no noticeable effect on flbG transcript levels. All three mutations constructed in ftr3 resulted in elevated flaN and flbG transcript levels. We conclude that ftr2 is required for positive regulation of flaN, whereas ftr3 appears to play a negative regulatory role in flaN and flbG expression. To explain the coordinated positive activation and negative autoregulation of these two transcription units and the effect of mutations on gene expression, we propose a model in which the flaN and flbG promoters interact through alternative DNA looping to form structures that are transcriptionally active or inactive.

Identification of the promoter and a negative regulatory element, ftr4, that is needed for cell cycle timing of fliF operon expression in Caulobacter crescentus.

The fliF operon of Caulobacter crescentus, which was previously designated the flaO locus, is near the top of the flagellar-gene regulatory hierarchy, and it is one of the earliest transcription units to be expressed in the cell cycle. In this report, we have identified two cis-acting sequences that are required for cell cycle regulation of fliF transcription. The first sequence was defined by the effects of three 2-bp deletions and five point mutations, each of which greatly reduced the level of fliF operon transcript in vivo. These eight mutations lie between -37 and -22 within an 18-bp sequence that matches, at 11 nucleotides, sequences in the 5' regions of the flaQR (flaS locus) and fliLM operons, which are also expressed early and occupy a high level in the regulatory hierarchy (A. Dingwall, A. Zhuang, K. Quon, and L. Shapiro, J. Bacteriol. 174:1760-1768, 1992). We propose that this 18-bp sequence contains all or part of the fliF promoter. We have also identified a second sequence, 17 bp long and centered at -8, which we have provisionally designated ftr4 because of its similarity to the enhancer-like ftr sequences required for regulation of sigma 54 promoters flaN and flbG (D. A. Mullin and A. Newton, J. Bacteriol. 171:3218-3227, 1989). Six of the seven mutations in ftr4 examined resulted in a large increase in fliF operon transcript levels, suggesting a role for ftr4 in negative regulation. A 2-bp deletion at -12 and -13 in ftr4 altered the cell cycle pattern of fliF operon transcription; the transcript was still expressed periodically, but the period of its synthesis was extended significantly. We suggest that the ftr4 sequence may form part of a developmental switch which is required to turn off fliF operon transcription at the correct time in the cell cycle.

Cis- and trans-acting elements required for regulation of flagellar gene transcription in the bacterium Caulobacter crescentus.

The flagellar genes of the bacterium Caulobacter crescentus are organized into a regulatory hierarchy that consists of four classes or levels of genes, and expression of these genes is restricted to a discrete interval in the cell cycle that begins just prior to flagellum assembly. This paper summarizes data on the promoters and other cis-acting elements that are required for transcription of the level II gene fliF and the level III genes flaN and flbG. Regulated expression of flaN and flbG requires sigma 54 promoters, enhancer-like sequences called ftr, and sequences called ihf that conform to the consensus binding sequence for Escherichia coli integration host factor protein. The fliF regulatory region contains a new type of promoter sequence that is different from other known promoter motifs, and it has a sequence called ftr4 that is a site of negative regulation. ftr4 appears to function as part of a developmental switch that turns fliF transcription off at the correct time in the cell cycle. flbD, the last gene in the fliF operon is a negative regulator of fliF and an activator of both flaN and flbG expression. Evidence that FlbD protein plays a direct role as a transcriptional regulator comes from the finding that it has a DNA binding activity within its carboxy terminus that specifically recognizes ftr4 in fliF and four ftr elements in the flaN-flbG promoter region.

Characterization of the Caulobacter crescentus flbF promoter and identification of the inferred FlbF product as a homolog of the LcrD protein from a Yersinia enterocolitica virulence plasmid.

We have investigated the organization and expression of the Caulobacter crescentus flbF gene because it occupies a high level in the flagellar gene regulatory hierarchy. The nucleotide sequence comprising the 3' end of the flaO operon and the adjacent flbF promoter and structural gene was determined, and the organization of transcription units within this sequence was investigated. We located the 3' ends of the flaO operon transcript by using a nuclease S1 protection assay, and the 5' end of the flbF transcript was precisely mapped by primer extension analysis. The nucleotide sequence upstream from the 5' end of the flbF transcript contains -10 and -35 elements similar to those found in promoters transcribed by sigma 28 RNA polymerase in other organisms. Mutations that changed nucleotides in the -10 or -35 elements or altered their relative spacing resulted in undetectable levels of flbF transcript, demonstrating that these sequences contain nucleotides essential for promoter function. We identified a 700-codon open reading frame, downstream from the flbF promoter region, that was predicted to be the flbF structural gene. The amino-terminal half of the FlbF amino acid sequence contains eight hydrophobic regions predicted to be membrane-spanning segments, suggesting that the FlbF protein may be an integral membrane protein. The FlbF amino acid sequence is very similar to that of a transcriptional regulatory protein called LcrD that is encoded in the highly conserved low-calcium-response region of virulence plasmid pYVO3 in Yersinia enterocolitica (A.-M. Viitanen, P. Toivanen, and M. Skurnik, J. Bacteriol. 172:3152-3162, 1990).

Timing of flagellar gene expression in the Caulobacter cell cycle is determined by a transcriptional cascade of positive regulatory genes.

The Caulobacter crescentus flagellar (fla) genes are organized in a regulatory hierarchy in which genes at each level are required for expression of those at the next lower level. To determine the role of this hierarchy in the timing of fla gene expression, we have examined the organization and cell cycle regulation of genes located in the hook gene cluster. As shown here, this cluster is organized into four multicistronic transcription units flaN, flbG, flaO, and flbF that contain fla genes plus a fifth transcription unit II.1 of unknown function. Transcription unit II.1 is regulated independently of the fla gene hierarchy, and it is expressed with a unique pattern of periodicity very late in the cell cycle. The flaN, flbG, and flaO operons are all transcribed periodically, and flaO, which is near the top of the hierarchy and required in trans for the activation of flaN and flbG operons, is expressed earlier in the cell cycle than the other two transcription units. We have shown that delaying flaO transcription by fusing it to the II.1 promoter also delayed the subsequent expression of the flbG operon and the 27- and 25-kDa flagellin genes that are at the bottom of the regulatory hierarchy. Thus, the sequence and timing of fla gene expression in the cell cycle are determined in large measure by the positions of these genes in the regulatory hierarchy. These results also suggest that periodic transcription is a general feature of fla gene expression in C. crescentus.

Sequence and expression of the Escherichia coli recR locus.

The Escherichia coli RecR protein participates in a recombinational DNA repair process. Its gene is located in a region of chromosome that extends from 502 to 509 kilobases on the physical map and that contains apt, dnaX, orf12-recR, htpG, and adk. Most, if not all, of these are involved in nucleic acid metabolism. The orf12-recR reading frames consist of 935 base pairs and overlap by one nucleotide, with the 3' A of the orf12 termination codon forming the 5' nucleotide of the recR initiation codon. The orf12-recR promoter was located upstream of orf12 by sequence analysis, promoter cloning, and S1 nuclease protection analysis. The start point of transcription was determined by primer extension. The transcript 5' end contained a long, apparently untranslated region of 199 nucleotides. Absence of a detectable promoter specific for recR and the overlap of the orf12 and recR reading frames suggest that translation of recR is coupled to that of orf12. By maxicell analysis, it was determined that both orf12 and recR are translated.

Identification, distribution, and sequence analysis of new insertion elements in Caulobacter crescentus.

We describe two insertion elements isolated from Caulobacter crescentus that are designated IS298 and IS511. These insertion elements were cloned from spontaneous flagellar (fla) gene mutants SC298 and SC511 derived from the wild-type strain CB15 (ATCC 19089), in which they were originally identified as insertions in the flbG operon of the hook gene cluster (N. Ohta, E. Swanson, B. Ely, and A. Newton, J. Bacteriol. 158:897-904, 1984). IS298 and IS511 were each present in C. crescentus CB2 and CB15 in at least four different positions, but neither was present in strain CB13 or in several Caulobacter species examined, including C. vibrioides, C. leidyia, and C. henricii. Nucleotide sequence analysis across the chromosome-insertion element junctions showed that IS298 is located 152 base pairs (bp) upstream from the ATG translation start of the hook protein gene flaK, where it is bounded by a 4-bp direct repeat derived from the site of insertion, and that IS511 is inserted at codon 186 of the flaK coding sequence, where it is also bounded by a 4-bp direct repeat duplicated from the site of insertion. The ilvB102 mutation in strain SC125 was also shown to result from insertion sequence IS511, but no duplication of the genomic sequence was present at the insertion element junctions. IS298 contains an imperfect terminal inverted repeat 16 bp long, and IS511 contains a 32-bp inverted repeat at the termini. IS298 and IS511 are the first insertion elements described in C. crescentus.

Characterization of the cryptic lambdoid prophage DLP12 of Escherichia coli and overlap of the DLP12 integrase gene with the tRNA gene argU.

The argU (dnaY) gene of Escherichia coli is located, in clockwise orientation, at 577.5 kilobases (kb) on the chromosome physical map. There was a cryptic prophage spanning the 2 kb immediately downstream of argU that consisted of sequences similar to the phage P22 int gene, a portion of the P22 xis gene, and portions of the exo, P, and ren genes of bacteriophage lambda. This cryptic prophage was designated DLP12, for defective lambdoid prophage at 12 min. Immediately clockwise of DLP12 was the IS3 alpha 4 beta 4 insertion element. The argU and DLP12 int genes overlapped at their 3' ends, and argU contained sequence homologous to a portion of the phage P22 attP site. Additional homologies to lambdoid phages were found in the 25 kb clockwise of argU. These included the cryptic prophage qsr' (P. J. Highton, Y. Chang, W. R. Marcotte, Jr., and C. A. Schnaitman, J. Bacteriol. 162:256-262, 1985), a sequence homologous to a portion of lambda orf-194, and an attR homolog. Inasmuch as the DLP12 att int xis exo P/ren region, the qsr' region, and homologs of orf-194 and attR were arranged in the same order and orientation as the lambdoid prophage counterparts, we propose that the designation DLP12 be applied to all these sequences. This organization of the DLP12 sequences and the presence of the argU/DLP12 int pair in several E. coli strains and closely related species suggest that DLP12 might be an ancestral lambdoid prophage. Moreover, the presence of similar sequences at the junctions of DLP12 segments and their phage counterparts suggests that a common mechanism could have transferred these DLP12 segments to more recent phages.

Ntr-like promoters and upstream regulatory sequence ftr are required for transcription of a developmentally regulated Caulobacter crescentus flagellar gene.

The flbG (hook operon or transcription unit II) and flaN (transcription unit I) operons of Caulobacter crescentus have a -12, -24 nucleotide sequence motif that is very similar to those of the Nif and Ntr promoters of enteric bacteria and Rhizobium spp. and a conserved ftr (flagellar gene transcription regulation) sequence, previously designated II-1 (D. A. Mullin, S. A. Minnich, L.-S. Chen, and A. Newton, J. Mol. Biol. 195:939-943, 1987) at approximately -100. We have used site-directed mutagenesis to examine the role of these sequences in the transcriptional regulation of these periodically expressed flagellar genes. Mutations in the flbG promoter that removed the conserved GC at -12, -13, the GG at -24, -25, or an AC base pair at -18, -19 in the nonconserved sequence between the -12, -24 elements completely eliminated detectable transcription. Mutations at other positions resulted in either a slight decrease (position 26), no change (position 15), or an elevated level (position -16 or -19) of the flbG transcript. By contrast, most of these flbG promoter mutations resulted in greatly elevated levels of transcription from the opposing flaN operon. Similar experiments were used to confirm the location of the flaN promoter to a -12, -24 Nif and Ntr sequence motif. Deletion of all or part of the ftr element or point mutations in the sequence drastically reduced the level of flbG transcript and resulted in increased levels of the flaN transcript. Thus, the conserved sequences at -12 and -24 in flbG and flaN are required for transcription of these genes in vivo, and the ftr element is required for transcription of flbG. This analysis also suggested that the ftr sequence and sequences in the flbG promoter are required for the negative autoregulation of the flbG and flaN operons. We speculate that the flbG and flaN promoters and the ftr element interact in some way to mediate the negative control of these divergent transcription units.

Escherichia coli sigma 54 RNA polymerase recognizes Caulobacter crescentus flbG and flaN flagellar gene promoters in vitro.

A set of the periodically regulated flagellar (fla) genes of Caulobacter crescentus contain conserved promoter sequence elements at -24 and -12 that are very similar to the sequence of the nitrogen assimilation (Ntr) and nitrogen fixation (Nif) promoters of enteric bacteria and Rhizobium spp. Transcription from Ntr and Nif promoters requires RNA polymerase containing sigma 54 instead of the usual sigma 70 and, in the case of the Ntr promoters, is activated by the transcription factors NRI and NRII. We have now demonstrated that the C. crescentus flbG and flaN promoters, which contain the Ntr/Nif type of consensus sequence, are utilized by purified Escherichia coli sigma 54 RNA polymerase (E sigma 54) in the presence of NRI and NRII but not by the purified sigma 70 RNA polymerase (E sigma 70) of E. coli. Oligonucleotide-generated flbG promoter deletions that removed the highly conserved GG dinucleotide at -24 or the GC dinucleotide at -12 or altered the spacing between the -24 and -12 sequence elements prevented utilization of the flbG promoter by the E. coli E sigma 54. Transversions of T to G at positions -26 and -15 also inactivated flbG promoter function in the E. coli cell-free transcription system, while a transition of G to A at position -16 in the nonconserved spacer region had no effect. The C. crescentus flaO and flbF promoters, which do not contain the Ntr/Nif-type promoter consensus sequence, were not utilized by either purified E sigma 54 or E sigma 70 from E. coli. Our results help to define the features of the Ntr/Nif-type consensus sequence required for promoter utilization by purified E. coli E sigma 54 and support the idea that C. crescentus may contain a specialized polymerase with similar promoter specificity required for expression of a set of fla genes.

The E. coli dnaY gene encodes an arginine transfer RNA.

The E. coli dnaY gene product is an arginine tRNA. Its 77 nucleotide sequence can be folded into a typical cloverleaf structure with a UCU anticodon corresponding to the rare arginine codon AGA. A dnaY+ plasmid confers overproduction of at least one arginine-accepting minor species of tRNAArg. The dnaY promoter was identified by run-off transcription studies, and the initiating nucleotide was identified by sequencing the 5' end of the in vitro transcript. The primary products in vitro are RNAs of 180 and 190 nucleotides, which presumably are processed in vivo to generate the mature form. Transcription is terminated in vitro, and presumably in vivo, by a rho-dependent process.

An E. coli DNA fragment 118 base pairs in length provides dnaY+ complementing activity.

The dnaY gene of E. coli, thought to be involved in the polymerization phase of DNA replication, was localized on a fragment 118 base pairs in length. This fragment, cloned in two different vectors and tested in a dnaY (Ts) recA host, has dnaY + complementing activity. The nucleotide sequence of the 118 base pairs and flanking bases was determined. The dnaY complementing activity was inactivated by transposon insertion and by localized chemical mutagenesis. Three independent insertions of Tn5 into the 118 base pair region eliminated dnaY activity. Eight single-base-change mutations that resulted in loss of dnaY activity also were located within the 118 base pair region. Analysis of the nucleotide sequence reveals a potential promoter but reveals no open reading frames likely to be translated into polypeptides. However, an RNA transcript of the dnaY region is synthesized in vivo. Perhaps the active product of dnaY is a small RNA or perhaps the dnaY region functions as a site.

Physiological properties of cold-sensitive suppressor mutations of a temperature-sensitive dnaZ mutant of Escherichia coli.

Suppressors of a temperature-sensitive dnaZ polymerization mutant of Escherichia coli have been identified by selecting temperature-insensitive revertants. Those suppressed strains which concomitantly became cold sensitive were chosen for further study. Intragenic suppressor mutations, which caused cold-sensitive defects in DNA polymerization, were located in dnaZ by transduction with lambda dnaZ+ phages. Extragenic suppressor mutations were mapped within the initiation gene dnaA. These suppressor-containing strains were defective in initiation at low temperature as determined by measurements of DNA synthesis in vivo and in toluene-treated cells. The occurrence of suppressor mutations of dnaZ(Ts) within the dnaA gene is considered evidence that the dnaA and dnaZ products interact in vivo. A second indication of a dnaA-dnaZ protein-protein interaction was provided by the observation that the introduction of additional copies of the dnaZ+ gene into a strain carrying the dnaA suppressor mutation was lethal [whether the strain was dnaZ+ or dnaZ(Ts)].

Cloning of the Escherichia coli dnaZX region and identification of its products.

The Escherichia coli DNA replication genes dnaZ and dnaX have previously been localized very near each other at 10.4 to 10.5 min on the chromosome map. These genes were cloned from a dnaZ+X+ plasmid of the Clarke and Carbon collection by identifying complementing fragments and both were located on a 2.1 kilobase pair (kb) fragment. The organization of the Z and X genes was investigated by Tn5 mutagenesis of a Z+X+ plasmid. Insertions which abolished Z or X complementing activity were mapped by restriction enzyme analysis within the 2.1 kb fragment. With the exception of one atypical insertion, all the insertions inactivated both Z and X complementation. The protein products of the dnaZ-dnaX region were labelled in minicells containing dnaZ+X+ and dnaZX::Tn5 plasmids. The 2.1 kb ZX region (which has a maximum coding capacity of 77,000 daltons of protein in a single reading frame) directed the synthesis of two proteins, one of 75,000 daltons, designated dnaX, and another of 56,500 daltons, designated dnaZ. Tn5 insertion into the ZX region interrupted the synthesis of these proteins; the detection of truncated fragments of dnaX determined the direction of transcription. In vitro, using a coupled transcription-translation system dependent on plasmid DNA, synthesis of the 75,000 dalton dnaX protein was demonstrated, but there was no detectable synthesis of the smaller dnaZ protein. Probably, therefore, the 75,000 dalton dnaX protein is cleaved in vivo to generate the dnaZ protein. It is possible that the 75,000 dalton product is the tau subunit of DNA polymerase III because they migrated similarly in electrophoresis.