Enhanced recombination associated with the presence of insertion and deletion mutations in poxvirus-infected cells

Abstract Rhizobium meliloti mutants carrying ndvF insertion or deletion mutations induce nodules on alfalfa which contain very few infected cells and fail to fix N2 (Fix-). We have characterized five independent second site mutations (designated sfx) which completely suppress the Fix- phenotype of ndvF mutants on Medicago sativa but not on another R. meliloti host Melilotus alba. Genetic mapping and phenotypic analysis revealed that the suppressor mutations sfx-1, sfx-4 and sfx-5 mapped to a single locus which was distinct from another locus defined by the sfx-2 and sfx-3 mutations. Tn5-mob-mediated conjugal mapping experiments showed that the sfx-1 locus was located clockwise from trp-33 on the R. meliloti chromosome and a detailed cotransduction map of this region was generated. To clone the sfx-1 locus, we prepared a cosmid library from total DNA obtained from an sfx-1, ndvF deletion strain. From this library, a cosmid pTH56, which converted Fix- ndvF mutants to Fix+, was isolated. Southern blot analysis provided direct physical evidence that the insert DNA in plasmid pTH56 was contiguous with the sfx-1 region. On low osmolarity glutamate-yeast extract-mannitol-salts medium (GYM) agar medium, ndvF insertion and deletion mutants were found to have a mucoid colony phenotype, as opposed to the dry colony phenotype of the wild-type strain. This phenotype was shown to be dependent on the exoB and expE genes required for synthesis of exopolysaccharide II in R. meliloti but not to be dependent on genes required exclusively for the synthesis of the succinoglycan or exopolysaccharide I. Transduction of either sfx-1 or sfx-2 or transfer of the cosmid pTH56 into the ndvF mutants restored them to a wild-type dry colony phenotype. The mucoid phenotype is not responsible for the Fix- phenotype of ndvF mutants as the Fix-, ndvF exp double mutants can be complemented to Fix+ by introducing plasmids which carry only the wild-type ndvF genes.

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RAISE: a simple and novel method of generating random insertion and deletion mutations

Nucleic Acids Research ◽

10.1093/nar/gnj032 ◽

2006 ◽

Vol 34 (4) ◽

pp. e30-e30 ◽

Cited By ~ 36

Author(s):

R. Fujii

Keyword(s):

Deletion Mutations ◽

Insertion And Deletion ◽

Novel Method ◽

Random Insertion

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Effects of DNA heterologies on bacteriophage lambda recombination.

Genetics ◽

10.1093/genetics/118.1.13 ◽

1988 ◽

Vol 118 (1) ◽

pp. 13-19

Author(s):

R K Pearson ◽

M S Fox

Keyword(s):

Bacteriophage Lambda ◽

Indirect Evidence ◽

Direct Products ◽

Base Pairs ◽

Heteroduplex Dna ◽

Deletion Mutations ◽

Genetic Crosses ◽

Insertion And Deletion ◽

Progeny Phage ◽

Substitution Mutation

Abstract Previous studies of bacteriophage lambda recombination have provided indirect evidence that substantial sequence nonhomologies, such as insertions and deletions, may be included in regions of heteroduplex DNA. However, the direct products of heterology-containing heteroduplex DNA--heterozygous progeny phage--have not been observed. We have constructed a series of small insertion and deletion mutations in the cI gene to examine the possibility that small heterologies might be accommodated in heterozygous progeny phage. Genetic crosses were carried out between lambda cI- Oam29 and lambda cI+ Pam80 under replication-restricted conditions. Recombinant O+P+ progeny were selected on mutL hosts and tested for cI heterozygosity. Heterozygous recombinants were readily observed with crosses involving insertions of 4 to 19 base pairs (bp) in the cI gene. Thus, nonhomologies of at least 19 bp can be accommodated in regions of heteroduplex DNA during lambda recombination. In contrast, when a cI insertion or deletion mutation of 26 bp was present, few of the selected recombinants were heterozygous for cI. Results using a substitution mutation, involving a 26-bp deletion with a 22-bp insertion, suggest that the low recovery of cI heterozygotes containing heterologies of 26 bp or more is due to a failure to encapsulate DNA containing heterologies of 26 bp or more into viable phage particles.

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Base insertion and deletion mutations induced in an Escherichia coli plasmid by benzo[a]pyrene-7,8-dihydrodiol-9,10-epoxide.

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.78.11.6817 ◽

1981 ◽

Vol 78 (11) ◽

pp. 6817-6820 ◽

Cited By ~ 10

Author(s):

H. Mizusawa ◽

C. H. Lee ◽

T. Kakefuda ◽

K. McKenney ◽

H. Shimatake ◽

...

Keyword(s):

Escherichia Coli ◽

Deletion Mutations ◽

Insertion And Deletion ◽

Coli Plasmid ◽

Base Insertion

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Domain-Level Differences in Microsatellite Distribution and Content Result from Different Relative Rates of Insertion and Deletion Mutations

Genome Research ◽

10.1101/gr.198602 ◽

2002 ◽

Vol 12 (3) ◽

pp. 408-413 ◽

Cited By ~ 24

Author(s):

D. Metzgar

Keyword(s):

Deletion Mutations ◽

Insertion And Deletion ◽

Domain Level

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Unique K-mer sequences for validating cancer-related substitution, insertion and deletion mutations

10.1101/2020.06.20.163113 ◽

2020 ◽

Author(s):

HoJoon Lee ◽

Ahmed Shuaibi ◽

John M. Bell ◽

Dmitri S. Pavlichin ◽

Hanlee P. Ji

Keyword(s):

Genome Sequencing ◽

Somatic Mutations ◽

Variant Calling ◽

Cancer Genome ◽

Sequencing Data ◽

Deletion Mutations ◽

Insertion And Deletion ◽

Cancer Genome Sequencing ◽

Significant Difference ◽

Model Tuning

ABSTRACTThe cancer genome sequencing has led to important discoveries such as identifying cancer gene. However, challenges remain in the analysis of cancer genome sequencing. One significant issue is that mutations identified by multiple variant callers are frequently discordant even when using the same genome sequencing data. For insertion and deletion mutations, oftentimes there is no agreement among different callers. Identifying somatic mutations involves read mapping and variant calling, a complicated process that uses many parameters and model tuning. To validate the identification of true mutations, we developed a method using k-mer sequences. First, we characterized the landscape of unique versus non-unique k-mers in the human genome. Second, we developed a software package, KmerVC, to validate the given somatic mutations from sequencing data. Our program validates the occurrence of a mutation based on statistically significant difference in frequency of k-mers with and without a mutation from matched normal and tumor sequences. Third, we tested our method on both simulated and cancer genome sequencing data. Counting k-mer involving mutations effectively validated true positive mutations including insertions and deletions across different individual samples in a reproducible manner. Thus, we demonstrated a straightforward approach for rapidly validating mutations from cancer genome sequencing data.

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