The spectra of base substitutions induced by the impCAB, mucAB and umuDC error-prone DNA repair operons differ following exposure to methyl methanesulfonate

We have used the lacZ reversion assay to study the mutation spectra induced by the Escherichia coli chromosomal umuDC operon and of its two plasmid-borne analogues impCAB and mucAB following exposure of cells to UV light and methyl methane-sulfonate (MMS). We have shown that the impCAB, mucAB and umuDC operons all produce a similar response to UV light which results almost exclusively in AT GC transitions. However, we found that the three operons produced different responses to alkylating agents. We found that with MMS the chromosomal umuDC operon produced almost exclusively AT GC transitions, whilst both mucAB and impCAB produced predominantly transversions. In the case of the impCAB operon the mutation spectrum contained more AT TA than GC TA transversions; this balance was reversed with mucAB. The effect of the copy number of the error-prone DNA repair operons upon the mutagenic spectra was also studied. The results obtained suggest that the copy number of the imp operon does not greatly affect the specificity of base substitutions observed. However, an increase in the copy number of the umuDC operon greatly affected the specificity of base substitution, such that virtually no transitions were produced and the spectrum was dominated by GC/AT TA transversions. It appears that the three error-prone DNA repair operons impCAB, mucAB and umuDC, despite showing strong structural and functional homologies, can display major differences in the spectrum of base changes induced during mutagenesis. We propose that the type of misincorporation/chain extension which DNA polymerase III is allowed to synthesize on a damaged DNA template is extremely sensitive to both the amount and type of error-prone repair proteins present. The modulation of these events by the different proteins can result in widely different mutagenic changes in the repaired DNA.     

DNA sequence analysis of the imp UV protection and mutation operon of the plasmid TP110: identification of a third gene.

The sequence of the imp operon of the plasmid TP110 (which belongs to the Incl1 incompatibility group) has been determined, and is shown to contain three open reading frames. This operon, involved in UV protection and mutation, is functionally analogous to the umuDC operon of E. coli and the mucAB operon of the plasmid pKM101, which belongs to the quite unrelated IncN incompatibility group. The umu and muc operons however contain only two open reading frames, coding for proteins of approximately 16kD and 46kD. The high degree of homology between the two 16kD proteins (UmuD and MucA) and between the two 46kD proteins (UmuC and MucB) clearly shows their relatedness. This is shown also to extend to the imp gene products, with ImpA sharing homology with UmuD and MucA, and ImpB sharing homology with UmuC and MucB. However, the two imp genes are preceded in the operon by a third gene, impC, which encodes a small protein of 9.5kD and which has no equivalent in the umu and muc operons.     

Repair in E. coli of transforming plasmid DNA damaged by psoralen plus near-ultraviolet irradiation

Treatment of DNA with psoralen plus near-ultraviolet irradiation gives rise to both monoadducts and cross-links. We have examined the repair of plasmid NTP16 DNA treated in this way in vitro and then used to transform E. coli. Monoadducts are found to be potentially lethal, and can be repaired by uvr-dependent and recA-dependent pathways. The presence of a related resident plasmid in the transformed cells can enhance the survival of the incoming damaged NTP16 DNA. This effect is not recA-dependent, and a similar effect (designated "resident enhanced repair") has been observed previously with UV-irradiated plasmids of this particular incompatibility group. Removal of unbound psoralen from the plasmid DNA and exposure to further NUV is known to increase the ratio of cross-links to monoadducts, and we demonstrate that such cross-linked plasmid DNA is not readily repaired following transformation. However in the presence of homologous DNA (related resident plasmid) there is evidence for the repair, and hence uptake by the cell, of cross-linked DNA.     

Impaired incision of ultraviolet-irradiated deoxyribonucleic acid in uvrC mutants of Escherichia coli.

The production of single-strand breaks in the deoxyribonucleic acid of irradiated uvrC mutants of Escherichia coli K-12 was studied both in vivo and in vitro. In vivo, uvrC mutants displayed a slow accumulation of breaks after irradiation, and in this respect appeared different from uvrA mutants, in which very few breaks could be detected. The breakage observed in uvrC mutants differed from that observed in wild-type strains in both the slow rate of break accumulation and the very limited dose response. The behavior of the uvrC lig-7(Ts) double mutant was shown not to be consistent with the suggestion of ligase reversal as the explanation for the lower rate and limited dose response of break formation observed in ultraviolet-irradiated uvrC mutants in vivo. Rather, there appeared to be a real defect in incision. In toluene-treated cells, we studied the effect of the ligase inhibitor nicotinamide mononucleotide on strand incision. Whereas uvrC mutants displayed more strand breakage in the presence of this inhibitor, the same amount of breakage was seen in uvrA mutants, and as such the breakage could be judged as not due to the main excision repair pathway. Experiments using a cell-free system comprising the partially purified uvr+ gene products demonstrated clearly that there is a requirement for the uvrC+ gene product for strand incision. We suggest that in vivo in the absence of the uvrC+ gene product, a partial analog of this protein may allow some abnormal incision.     

Amplification of DNA from native populations of soil bacteria by using the polymerase chain reaction.

Specific DNA sequences from native bacterial populations present in soil, sediment, and sand samples were amplified by using the polymerase chain reaction with primers for either "universal" eubacterial 16S rRNA genes or mercury resistance (mer) genes. With standard amplification conditions, 1.5-kb rDNA fragments from all 12 samples examined and from as little as 5 micrograms of soil were reproducibly amplified. A 1-kb mer fragment from one soil sample was also amplified. The identity of these amplified fragments was confirmed by DNA-DNA hybridization.     

UV inducible UV protection and mutation functions on the I group plasmid TP110

Summary The UV protection and mutation properties of the I group plasmid TP110 have been investigated. It is demonstrated that the genes responsible for these effects are able to complement the deficiency in umuC36 mutants of E. coli, as are the similar genes carried by the B group plasmid R16. Mu-lac inserts into TP110 have been isolated which abolish the UV protection and mutation functions. Restriction mapping of these inserts locates them within a single region of the genome. A comparison of the restriction sites of this region with the muc region of pKM101 reveals very little similarity. Expression of -galactosidase in those Mu-lac inserts in which the lacZ gene is fused to the promoter for the protection and mutation functions is inducible by DNA damaging agents, and induction in mutant strains suggests that these genes are under the direct control of the lexA repressor.     

A pathway for the evolution of the plasmid NTP16 involving the novel kanamycin resistance transposon Tn4352

The kanamycin resistance determinant of the drug resistance plasmid NTP16 has been characterized by DNA sequencing and has been shown to possess all of the structural features of a transposable element. It is made up of a 1040-bp central region encoding a protein identical to the aminoglycoside 3'-phosphotransferase of Tn903, flanked by direct repeats of an element identical to IS26. This novel transposon has been designated Tn4352. Analysis of the host sequences flanking the transposon reveal that they are derived from a Tn3-like element, and contain no 8 base pair target size duplications which are normally created by the insertion of IS26-like elements. Comparison to the Tn3 sequence shows that the flanking sequences are noncontiguous within Tn3, with the clear implication that NTP16 has evolved from a similar plasmid encoding only ampicillin resistance (presumably NTP1) by the insertion of Tn4352 into the Tn3-like element, followed by a substantial deletion. The sequence analysis suggests that the initial insertion was into the tnpR gene of the ampicillin transposon, followed by a deletion extending to a specific site within tnpA.     

Collagen-induced arthritis in common marmosets: a new nonhuman primate model for chronic arthritis

Introduction  

There is an ever-increasing need for animal models to evaluate efficacy and safety of new therapeutics in the field of rheumatoid arthritis (RA). Particularly for the early preclinical evaluation of human-specific biologicals targeting the progressive phase of the disease, there is a need for relevant animal models. In response to this requirement we set out to develop a model of collagen-induced arthritis (CIA) in a small-sized nonhuman primate species (300 to 400 g at adult age); that is, the common marmoset (Callithrix jacchus).