Isolation and analysis of multicopy extragenic suppressors of dnaA mutations

Acquisition of new metabolic capabilities: multicopy suppression by cloned transaminase genes in Escherichia coli K-12

The four general transaminases of Escherichia coli K-12 have overlapping, but discrete, substrate specificities and participate in the final step in the synthesis of at least seven different amino acids. Through the use of strains that have mutations in one or more transaminase genes and carry a different wild-type (wt) gene on a multicopy plasmid, it was possible to detect instances in which an amplified wt gene suppressed nonallelic mutations. In these cases, overproduction of the enzyme permitted a broader range of substrates to be used at physiologically significant levels, either because a low catalytic efficiency (in the case analyzed here) or a low affinity of the enzyme towards the substrate prevented its effective utilization under normal conditions. Consequently, by compensating for a low catalytic reaction rate, enzyme overproduction circumvents the original lesion and restores biosynthetic activity to the mutant strain. The suppression of a mutation in one gene by amplified copies of a different wt gene is termed 'multicopy suppression'. This phenomenon is useful for detecting poorly expressed genes, for detecting duplicate genes, for identifying secondary functions of the products of known genes, and for elucidating the metabolic role of the product of the suppressed gene.

Method for localization of cloned DNA fragments on the Escherichia coli chromosome

In exponentially growing cultures of Escherichia coli strains carrying the dnaC28 mutation, DNA replication can be synchronized by temperature changes (R. L. Rodriguez, M. S. Dalbey, and C. I. Davern, J. Mol. Biol. 74:599-604, 1973). We used this synchronization procedure and DNA-DNA hybridization to develop a technique for the localization of cloned chromosomal fragments on the genetic map. Because of the bidirectional nature of replication in E. coli, our method gave two possible positions (one on each replication arm). However because of the precision obtained for each position (+/- 1 map unit), the final mapping with various genetic techniques was greatly facilitated. Using this technique and a simple chromosomal mobilization test, we located at 93.2 +/- 1 min a cloned DNA fragment carrying an extragenic suppressor of dnaA46, a thermosensitive mutation in the dnaA initiation gene. Further analysis showed that the groES (mopA) and groEL (mopB) genes, both located at 94.2 min on the standard map, were indeed carried by the cloned suppressor fragment.

Suppression of the Escherichia coli dnaA46 mutation by amplification of the groES and groEL genes

A lambda hybrid phage (lambda Sda1), containing an 8.1 kb EcoRI DNA fragment from the Escherichia coli chromosome, was selected on the basis of its ability to suppress bacterial thermosensitivity caused by the dnaA46 mutation. We have shown that this suppression is due to a recA+-dependent amplification of the 8.1 kb fragment; consistent with this observation, cloning of the 8.1 kb fragment into a high copy number plasmid (pBR325) leads also to suppression of dnaA46. In the suppressed strains growing at high temperature, bidirectional replication starts in or near the oriC region and requires the presence of the DnaA polypeptide. These findings suggest that the overproduction of a gene product(s), encoded by the cloned 8.1 kb fragment, can restore dnaA-dependent initiation of replication at high temperature in the oriC region. Genetic mapping shows that the groES (mopB) and groEL (mopA) genes are located on the 8.1 kb suppressor fragment. Further analysis, including in vitro mutagenesis and subcloning, demonstrates that the amplification of the groES and groEL genes is both necessary and sufficient to suppress the temperature sensitive phenotype of the dnaA46 mutation.

A DNA fragment containing the groE genes can suppress mutations in the Escherichia coli dnaA gene

An 8.2 kb fragment of E. coli chromosomal DNA, when cloned in increased copy number, suppresses the dnaA46 mutation, and an abundant protein of about 68 kd (60 kd when measured by us), encoded by the fragment, is essential for the suppression (Takeda and Hirota 1982). Mapping experiments show that the fragment originates from the 94 min region of the chromosome. It encodes several proteins but only one abundant polypeptide of the correct size, the product of the groEL gene. Suppression by the fragment is allele specific; those mutations which map to the centre of the gene are suppressed. Other initiation mutants including dnaA203, dnaA204, dnaA508, dnaAam, dnaC, dnaP and dnaB252 are not suppressed. Most suppressed strains are cold-sensitive suggesting an interaction between the mutant proteins (or their genes) and the suppressing protein or proteins.

In vitro RNA polymerase interaction with a restriction fragment containing the Escherichia coli origin of replication

The interaction of RNA polymerase with a restriction fragment containing the origin of Escherichia coli replication (oriC) was examined by methods used to investigate transcription promoter activities. Interactions of RNA polymerase with oriC were determined and characterized by agarose gel exclusion under conditions of polymerase binding and RNA synthesis initiation. These interactions were further demonstrated and defined by nitrocellulose retention experiments under various reaction conditions. The binding of RNA polymerase to the oriC fragment was compared to binding to the tetracycline promoter (tet), a known strong promoter of transcription. Specific localization of the RNA polymerase-oriC interaction was determined by restriction protection experiments. The binding of RNA polymerase was determined to be located near the HindIII site of oriC. These methods allowed the observation and characterization of a specific association of RNA polymerase with the origin of E. coli DNA replication.

Initiation of DNA replication in Escherichia coli: RNase H-deficient mutants do not require the dnaA function

A series of temperature-resistant revertants were isolated from strains of Escherichia coli K12 carrying a temperature-sensitive mutation in the dnaA gene. Four independent revertants were found which still carry the original ts mutation. The ability of these strains to grow at high temperature is due to a suppressor mutation, called sin. All four sin mutations are located between the genes metD and proA on the genetic map of E. coli, which suggests that they all affect the same gene. The sin suppressors, which were isolated for their ability to suppress one dnaA mutation, are also able to suppress three other temperature-sensitive dnaA mutations, but they are not able to suppress mutations in either of the two genes dnaB or dnaC. The sin suppressors alone do not confer any particular phenotype on bacteria, but they are deficient in the enzyme RNase H. On the basis of these findings we propose that the function of the dnaA protein is to protect a DNA-RNA hybrid at the origin of replication against RNase H.

Functional interchangeability of DNA replication genes in Salmonella typhimurium and Escherichia coli demonstrated by a general complementation procedure

Twenty-four genes from Salmonella typhimurium that affect DNA replication were isolated from a lambda-Salmonella genomic library by lysogenic complementation of temperature-sensitive mutants of Salmonella or E. coli, using a new plaque complementation assay. The complementing lambda clones, which make red plaques in this assay, and noncomplementing mutant derivatives, which make uncolored plaques, were used to further characterize the temperature-sensitive Salmonella mutants and to establish the functional similarity of E. coli and Salmonella DNA replication genes. For 17 of 18 E. coli mutants representing distinct loci, a Salmonella gene that complemented the mutant was found. This result indicates that single Salmonella replication proteins are able to function in otherwise all E. coli replication complexes and suggests that the detailed properties of Salmonella and E. coli replication proteins are very similar. The other seven Salmonella genes that were cloned were unrelated functionally to any E. coli genes examined. --As an aid to the derivation of chromosomal mutations affecting some of the cloned genes, a general method was developed for placing a transposon in the Salmonella chromosome in a segment corresponding to cloned DNA. Chromosomal mutations were derived in Salmonella affecting a gene (dnaA) that was cloned by complementation of an E. coli mutant by using the transposon-encoded drug resistance as a selectable marker in local mutagenesis.

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.

Determination of plasmid copy number by fluorescence densitometry

A simple and reliable method for the determination of plasmid copy numbers by direct fluorescence densitometry of ethidium bromide-stained electrophoretic gels was developed. In developing the method, the following parameters were evaluated and controlled: plasmid DNA trapping in the linear chromosomal DNA, staining-destaining kinetics for ethidium bromide, linearity of the fluorescence response, and the effect of the molecular topology of DNA on ethidium bromide binding to DNA in agarose.

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 bacterial DNA replication genes in bacteriophage lambda

Recombinant lambda phages containing the genes for dnaZ protein (the gamma subunit of DNA polymerse III holoenzyme), primase (dnaG protein) and dnaC protein from Escherichia coli and Salmonella typhimurium were isolated. Each gene cloned from S. typhimurium has extensive DNA sequence homology to the corresponding E. coli gene. Clones selected by complementation of a dnaA temperature-sensitive mutant appear similar to other isolated suppressors of dnaA (Projan and Wechsler 1981). Derivatives of each cloned fragment suitable for overproduction of the protein were constructed. Of those tested, only the phage containing the E. coli dnaZ gene resulted in significant overproduction.

RNA polymerase is required for DNA initiation in vitro

We have previously reported in vitro complementation assays for chromosome initiation that enable dnaA and dnaC mutant extracts to synthesize DNA. To examine the role of RNA polymerase in chromosome initiation, inhibitors of the enzyme and anti-RNA polymerase antibody were used. Though rifampicin failed to efficiently inhibit ribonucleoside triphosphate polymerization under the assay conditions, both streptolydigin and anti-RNA polymerase antibody abolished ribonucleic acid synthesis completely. Antibody effectively inhibited chromosome initiation in the dnaA mutant based reaction but streptolydigin did not. Neither streptolydigin nor antibody affected the dnaC-dependent assay. It was concluded that RNA polymerase is required for initiation but not necessarily to polymerize a polyribonucleotide. A scheme for the sequence of initiation events is presented.

Complementation of a dnaC initiation defect in vitro

The dnaC28 mutant, CT28-3b, is an initiation defective dnaC strain. Extracts of the mutant failed to synthesize DNA in vitro when the strain was incubated at the restrictive temperature for two generation times prior to preparation of the extract. Addition of a complementing extract from a Col-E1::dnaC+ hybrid plasmid containing strain or of partially purified dnaC protein resulted in substantial synthesis. Hybridization of the DNA made by these in vitro complementation extracts showed that a significant portion of this DNA was from the region near the chromosomal origin of replication.

Initiation of chromosomal DNA synthesis in vitro

An in vitro complementation assay for initiation of chromosomal DNA replication is described. The initiation reaction is dependent upon extract from either of two hybrid-plasmid containing strains. Each hybrid plasmid carries a suppressor of dna A-ts mutations. The in vitro DNA synthesis is heavily biased toward the origin region, and the origin of replication (oriC) is replicated as determined by DNA-DNA hybridizations.

Deoxyribonucleic acid initiation mutation dnaB252 is suppressed by elevated dnaC+ gene dosage

The Escherichia coli dnaB252 allele is the only dnaB mutation which confers a deoxyribonucleic acid initiation-defective phenotype on the cell. The presence of a multicopy hybrid plasmid containing the dnaC+ gene in a dnaB252 strain completely suppressed the temperature-sensitive phenotype. It is suggested that at high temperature the dnaB252 protein has a lowered affinity for dnaC protein, and that the formation of a dnaB-dnaC complex is mandatory for initiation.