TrfA dimers play a role in copy-number control of RK2 replication.

Copy-number regulation of the broad-host-range plasmid RK2 is dependent on the plasmid-encoded initiator protein, TrfA, and the RK2 origin of replication. The handcuffing model for copy-number control proposes that TrfA-bound oris reversibly couple to prevent the further initiation of plasmid replication when the copy number in vivo is at or above the replicon-specific copy number. TrfA mutants have been isolated which allow for oriV replication at elevated copy numbers. To better understand the mechanism of 'handcuffing', the copy-up TrfA(G254D/S267L) mutant was characterized further. In the present study we show by size exclusion chromatography and native gel electrophoresis that unlike wt TrfA which is largely dimeric, purified His6-TrfA(G254D/S267L) is primarily monomeric. In vivo, TrfA33(G254D/S267L) supports replication of an RK2 ori plasmid in trans at a greatly elevated copy number, while in cis the plasmid exhibits runaway replication. However, expression of either of two previously isolated DNA-binding defective TrfA mutants, TrfA33(P151S) or TrfA33(S257F), in a cell transformed with a mini-RK2 replicon encoding TrfA33(G254D/S267L) results in suppression of the runaway phenotype. His6-TrfA(P151S) and His6-TrfA(S257F) purify as dimers, and when expressed in vivo are incapable of supporting RK2 plasmid replication. In contrast, combination of the trfA(P151S) or trfA(S257F) mutation with the trfA(G254D/S267L) mutations results in the expression of mutant TrfA proteins which are mainly monomers and which can no longer restore copy control to replication directed by TrfA33(G254D/S267L) in vivo. On the basis of these findings a handcuffing model is proposed, whereby oriV-bound TrfA monomers are coupled by dimeric TrfA molecules.

Copy-up mutants of the plasmid RK2 replication initiation protein are defective in coupling RK2 replication origins.

The broad host range plasmid RK2 replicates and regulates its copy number in a wide range of Gram-negative bacteria. The plasmid-encoded trans-acting replication protein TrfA and the origin of replication oriV are sufficient for controlled replication of the plasmid in all Gram-negative bacteria tested. The TrfA protein binds specifically to direct repeat sequences (iterons) at the origin of replication. A replication control model, designated handcuffing or coupling, has been proposed whereby the formation of coupled TrfA-oriV complexes between plasmid molecules results in hindrance of origin activity and, consequently, a shut-down of plasmid replication under conditions of higher than normal copy number. Therefore, according to this model, the coupling activity of an initiation protein is essential for copy number control and a copy-up initiation protein mutant should have reduced ability to form coupled complexes. To test this model for plasmid RK2, two previously characterized copy-up TrfA mutations, trfA-254D and trfA-267L, were combined and the resulting copy-up double mutant TFrfA protein TrfA-254D/267L was characterized. Despite initiating runaway (uncontrolled) replication in vivo, the copy-up double-mutant TrfA protein exhibited replication kinetics similar to the wild-type protein in vitro. Purified TrfA-254D, TrfA-267L, and TrfA-254D/267L proteins were then examined for binding to the iterons and for coupling activity using an in vitro ligase-catalyzed multimerization assay. It was found that both single and double TrfA mutant proteins exhibited substantially reduced (single mutants) or barely detectable (double mutant) levels of coupling activity while not being diminished in their capacity to bind to the origin of replication. These observations provide direct evidence in support of the coupling model of replication control.

The plasmid RK2 initiation protein binds to the origin of replication as a monomer.

The TrfA protein encoded by the broad host range bacterial plasmid RK2 specifically binds to eight direct repeats (iterons) present at the plasmid replication origin to initiate DNA replication. Purified TrfA protein is largely in the form of a dimer, and using a dimerization test system that involves the fusion of the amino-terminal domain of the lambda cI repressor protein to TrfA, we show that the TrfA protein forms dimers in vivo. Because of the high stability of the dimer form of TrfA, the formation of heterodimers between the wild-type and different sized TrfA proteins requires in vivo de novo folding of the primary protein sequence or in vitro denaturation and renaturation. The results of gel mobility shift assays using in vitro or in vivo formed heterodimers indicated that the TrfA protein binds to the iteron DNA as a monomer. Furthermore, when the monomeric and dimeric forms of TrfA are separated by gel filtration chromatography, only the protein in the chromatographic position of the monomeric form demonstrated significant DNA binding activity. These results indicate that only the monomer form of the TrfA protein is active for binding to the iterons at the RK2 replication origin.

Isolation and characterization of DNA-binding mutants of a plasmid replication initiation protein utilizing an in vivo binding assay.

An in vivo screen was developed for the identification of mutants of the RK2 replication initiation protein, TrfA, that were altered in their binding to the iterons within the plasmid RK2 origin of replication. This assay is based on an antibiotic selection system originally described by Elledge, Sugiono, Guarente, and Davis (Proc. Natl. Acad. Sci. USA86, 3689-3693, 1989) for the isolation in vivo of genes encoding sequence-specific DNA-binding proteins. A TrfA-specific binding site consisting of two 17-bp iterons separated by a nonrandom 6-bp spacer was placed 3' to a strong constitutive promoter. This promoter-iteron fragment was then inserted into the assay vector convergent to the aadA gene such that an increased level of spectinomycin resistance by the Escherichia coli host was dependent on the binding of wild-type TrfA protein to the binding site. The in vivo system was used to specifically isolate TrfA mutants which were either defective in binding or capable of effecting increased levels of spectinomycin resistance as compared to wild-type TrfA. The defective TrfA mutants isolated by this screen were purified and found to be considerably less effective in DNA binding by in vitro gel mobility shift assays. The map location was determined for these six defective TrfA mutants. Each of the mutations consisted of a single base change and mapped within codons extending over a 162 amino acid sequence. All of the mutants which were capable of effecting increased levels of spectinomycin resistance in the in vivo DNA-binding assay also showed some alteration in RK2 replication in vivo with most of the mutants having a copy-up phenotype similar to previously isolated TrfA mutants able to maintain an eight-iteron RK2 origin plasmid at a higher copy number.

Nitrogen metabolism in a new obligate methanotroph, 'Methylosinus' strain 6.

A new obligate methanotroph was isolated and characterized. It was classified as a 'Methylosinus' species and named 'Methylosinus' sp. strain 6. Nitrogen metabolism in 'Methylosinus' 6 was found to be similar to other Type II methanotrophs, including the assimilation of nitrogen exclusively by the glutamine synthetase/glutamate synthase system. However, unlike other Type II methanotrophs, it appeared that glutamine synthetase activity was regulated by adenylylation in this organism. 'Methylosinus' 6 was grown in continuous culture with either dinitrogen or nitrate as sole nitrogen source under various dissolved oxygen tensions. Higher rates of methane oxidation and a more developed intracytoplasmic membrane system were found at lower oxygen tensions with nitrate as the nitrogen source but at higher oxygen tensions with dinitrogen as the nitrogen source. This suggested that carbon metabolism was influenced by nitrogen metabolism in this organism.

DNA hybridization analysis of the nif region of two methylotrophs and molecular cloning of nif-specific DNA.

DNA isolated from two diazotrophic methylotrophs, the obligate methanotroph Methylosinus sp. strain 6 and the methanol autotroph Xanthobacter sp. H4-14, hybridized to DNA fragments encoding nitrogen fixation (nif) genes from Klebsiella pneumoniae. This interspecific nif homology was limited to DNA fragments encoding the nitrogenase structural proteins (nifH, nifD, and nifK) and specific methylotroph DNA sequences. The hybridization patterns obtained with the two methylotrophs were dissimilar, indicating that the nif region of methylotrophs is not physically conserved. By using the K. pneumoniae nif structural genes as a probe, a fragment of nif DNA from each methylotroph was cloned and characterized. The DNA fragment from Methylosinus sp. 6 encoded two polypeptides of 57,000 and 34,000 molecular weight.

Molecular construction and characterization of nif mutants of the obligate methanotroph Methylosinus sp. strain 6.

We describe here a method for constructing mutants in bacteria that are not amenable to mutant isolation by conventional means. A one-step marker exchange procedure was used to construct nitrogen fixation (nif) mutants of the obligate methane-utilizing bacterium Methylosinus sp. strain 6, using transposon 5 (Tn5)-containing nif genes cloned into pBR325. The resultant mutants appeared to contain defects in nif structural genes, and DNA hybridization analysis showed that although one out of five had apparently been produced as a result of double-crossover homologous recombination, a variety of molecular events had led to the production of the other four mutants.

Manipulation of methanotrophs.

Methanotrophs have interesting properties concerning the oxidation and dehalogenation of both straight-chain and aromatic hydrocarbons. However, the potential of these bacteria in the degradation of these compounds cannot be assessed until more experiments are carried out. It seems likely that genetic capabilities will play a major role in the exploitation of these bacteria. We have shown that it is possible to use recombinant DNA techniques to generate mutants and transfer genes in methanotrophic bacteria.