Structural and Functional Impact of SRP54 Mutations Causing Severe Congenital Neutropenia

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Induction of SOS and adaptive responses by alkylating agents in Escherichia coli mutants deficient in 3-methyladenine-DNA glycosylase activities

The induction of SOS and adaptive responses by alkylating agents was studied in Escherichia coli mutants tagA and alkA deficient in 3-methyladenine-DNA glycosylase activities. The SOS response was measured using an sfiA::lacZ operon fusion. The sfiA operon, in the double mutant tagA alkA, is induced at 5-50-fold lower concentrations of all tested methylating and ethylating compounds, as compared to the wild-type strain. In all cases, the tagA mutation, which inactivates the constitutive and specific 3-alkyladenine-DNA glycosylase I (TagI), sensitizes the strain to the SOS response. The sensitization effect of alkA mutation, which inactivates the inducible 3-alkyladenine-DNA glycosylase II (TagII), is observed under conditions which allow the induction of the adaptive response. We conclude that the persistence of 3-methyladenine and 3-ethyladenine residues in DNA most likely leads to the induction of the SOS functions. In contrast, the adaptive response, evaluated by O6-methylguanine-DNA methyltransferase activity in cell extracts, was not affected by either tagA or alkA mutations. The results suggest that the SOS and adaptive responses use different alkylation products as an inducing "signal". However, adaptation protein TagII inhibits the induction of the SOS response to some extent, due to its action at the level of signal production. Finally, we provide conditions to improve short-term bacterial tests for the detection of genotoxic alkylating agents.     

A locus involved in kanamycin, chloramphenicol and L-serine resistance is located in the bglY-galU region of the Escherichia coli K12 chromosome

Summary Spontaneous mutants of Escherichia coli K12 displaying an increased level of the kanamycin resistance conferred by plasmid pGR71 were selected. Several mutants obtained in this way apparently carry large chromosomal deletions extending into galU and/or bglY (27 min). This positive selection of deletions allowed detection of a new locus located between galU and bglY. Deletions of this locus are responsible for increased resistance to kanamycin (Irk), decreased resistance to l-serine in minimal medium (Drs) and decreased resistance to chloramphenicol (Drc) when a cat gene is present in the bacteria.     

Mechanism of DNA strand nicking at apurinic/apyrimidinic sites by Escherichia coli [formamidopyrimidine]DNA glycosylase.

Escherichia coli [formamidopyrimidine]DNA glycosylase catalyses the nicking of both the phosphodiester bonds 3' and 5' of apurinic or apyrimidinic sites in DNA so that the base-free deoxyribose is replaced by a gap limited by 3'-phosphate and 5'-phosphate ends. The two nickings are not the results of hydrolytic processes; the [formamidopyrimidine]DNA glycosylase rather catalyses a beta-elimination reaction that is immediately followed by a delta-elimination. The enzyme is without action on a 3'-terminal base-free deoxyribose or on a 3'-terminal base-free unsaturated sugar produced by a beta-elimination reaction nicking the DNA strand 3' to an apurinic or apyrimidinic site.     

Ring-opened 7-methylguanine residues in DNA are a block to in vitro DNA synthesis.

Single-stranded M13mp18 phage DNA was methylated with dimethylsulfate (DMS), and further treated with alkali to ring-open N7-methylguanine residues and yield 2-6-diamino-4-hydroxy-5N-methylformamidopyrimidine (Fapy) residues. Nucleotide incorporation during in vitro DNA synthesis on methylated template using E. coli DNA polymerase Klenow fragment (Kf polymerase) was reduced compared to the unmethylated template. Additional treatment of the methylated template with NaOH to generate Fapy residues, further reduced in vitro DNA synthesis compared to the synthesis on methylated templates, which suggested that Fapy residues were a block to in vitro DNA synthesis. Analysis of the termination products on sequencing gels, assuming that synthesis stops one base before a blocking lesion, indicated that arrest of DNA synthesis upon direct alkylation of single-stranded DNA occurred 1 base 3' to template adenine residues in the case of Kf polymerase and 1 base 3' to adenine and cystosine residues for T4 polymerase. When the alkylated templates were treated with NaOH to produce a template which converted all the N7-methylguanine residues to Fapy residues, the blocks to DNA synthesis were still observed one base before adenine residues. In addition to the stops previously observed for the methylated templates, however, new stops occurred one base 3' to template guanine residues for synthesis using both Kf polymerase and T4 polymerase. Fapy residues, therefore, represent a potential lethal lesion which may also arrest in vivo DNA synthesis if not repaired.     

Mapping of FMR1, the gene implicated in fragile X-linked mental retardation, on the mouse X chromosome

A genetic map of the Cf-9 to Dmd region of the mouse X chromosome has been established by typing 100 offspring from a Mus musculus x Mus spretus interspecific backcross for the four loci Cf-9, Cdr, Gabra3, and Dmd. The following order and genetic distances in centimorgans were determined: (Cf-9)-2.4 +/- 1.7-(Cdr)-2.0 +/- 1.4-(Gabra3)-4.1 +/- 2.0-(Dmd). Six backcross offspring carrying X chromosomes with recombination events in the Cdr-Dmd region were identified. These recombination events were used to define the position of Fmr-1, the murine homologue of FMR1, which is the gene implicated in the fragile X syndrome in man, and that of DXS296h, the murine homologue of DXS296. Both Fmr-1 and DXS296h were mapped into the same recombination interval as Gabra3 on the mouse X chromosome. These findings provide strong support for the concept that the order of loci lying in the Cf-9 to Gabra3 segment of the X chromosome is highly conserved between human and mouse.     

Excision of uracil residues in DNA: mechanism of action of Escherichia coli and Micrococcus luteus uracil-DNA glycosylases.

Various octadeoxynucleotides containing uracil at different positions were synthesized and submitted to the action of Escherichia coli and Micrococcus luteus uracil-DNA glycosylases. A uracil residue situated at the 5'-end was excised by the M.luteus enzyme but not by the E.coli one. Uracil residues located at the ultimate and penultimate positions at the 3'-end were not cleaved by either enzymes. At the other central positions, uracil was eliminated with different initial velocities. Single stranded phi X 174 DNA fragments were used to study the influence of the sequence. Cytosine bases were deaminated to give uracil by bisulfite treatment. It was shown that the initial excision velocity of two vicinal uracil residues was decreased. The same observation was made for two uracils separated by one base. A hypothetical scheme is suggested to explain the mechanism of action of uracil-DNA glycosylases.     

Cloning of Micrococcus luteus 3-methyladenine-DNA glycosylase genes in Escherichia coli

The 3-methyladenine-DNA glycosylase (m3ADG) excises 3-methyladenine (m3A) residues formed in DNA after treatment with alkylating agents. In Escherichia coli, the repair of this type of damage depends on the products of the genes tagA and/or alkA, which code for m3ADG I (20 kDa) and II (30 kDa), respectively. The tagA- and alkA--single mutants are sensitive to alkylating agents, the double mutant much more so. We have cloned two genes of Micrococcus luteus that can partly substitute the function of the E. coli tagA- and alkA- genes. An M. luteus genome bank was made by shotgun cloning of EcoRI + BamHI-digested DNA into pBR322. Two hybrid plasmids were identified that confer methylmethane sulfonate (MMS) resistance to the tagA- ada+ mutant and a capacity to reactivate MMS-treated bacteriophage lambda. Each hybrid plasmid directed the synthesis of 21-kDa m3ADG in E. coli tagA- ada-, which were not inhibited by 4 mM m3A. However, the restriction maps of the two cloned genes were different, and they showed no sequence homology as judged by the lack of cross hybridization.