Homologous recombination in hybridoma cells: dependence on time and fragment length.

Mutant hybridoma-myeloma cell lines that are defective in immunoglobulin production are expected to be useful for defining the molecular requirements of immunoglobulin gene expression. The analysis of such mutants would be greatly facilitated if they could be mapped by marker rescue, i.e., by identifying the segments of wild-type DNA that can restore the normal phenotype by homologous recombination with the mutant chromosomal immunoglobulin gene. To assess the feasibility of this type of mapping, we have measured the efficiency with which fragments of wild-type DNA recombine with a mutant hybridoma immunoglobulin gene and restore normal immunoglobulin production. We found that most if not all recombinants were detectable 2 days after DNA transfer and that the frequency of gene restoration increased with increasing length of the transferred mu gene fragments, between 1.2 and 9.5 kilobases. These results indicate that the available technology should be adequate to map mutations in the mu gene to within approximately 1 kilobase.     

Immunoglobulin molecular genetics: the prospects for mutational analysis of the chromosomal immunoglobulin genes

Homologous recombination between transferred and chromosomal DNA can be used to effect precise, predetermined modifications of the chromosomal genes. Ultimately this phenomenon should allow the assessment of genetic regulatory elements as they function in the normal chromosomal environment. We have previously described a system for isolating mutant hybridoma cells that are defective in immunoglobulin (Ig) production, with a view toward using these mutants to define cis-acting elements that influence Ig gene expression. Here we describe results that indicate that homologous recombination between transferred and chromosomal Ig genes can be used to map Ig mutations by marker rescue.     

Fine Structure Recombinational Analysis of Cloned Genes Using Yeast Transformation

We describe a general method for analyzing the genetic fine structure of plasmid-borne genes in yeast. Previously we had reported that a linearized plasmid is efficiently rescued by recombination with a homologous restriction fragment when these are co-introduced by DNA-mediated transformation of yeast. Here, we show that a mutation can be localized to a small DNA interval when members of a deletion series of wild-type restriction fragments are used in the rescue of a linearized mutant plasmid. The resolution of this method is to at least 30 base pairs and is limited by the loss of a wild-type marker with proximity to a free DNA end. As a means for establishing the nonidentity of two mutations, we determined the resolution of two-point crosses with a mutant linearized plasmid and a mutant homologous restriction fragment. Recombination between mutations separated by as little as 100 base pairs was detected. Moreover, the results indicate that exchange within a marked interval results primarily from one of two single crossovers that repair the linearized plasmid. These approaches to mapping the genetic fine structure of plasmids should join existing methods in a robust approach to the mutational analysis of gene structure in yeast.     

Physical mapping of DNA-temperature-sensitive mutations of vaccinia virus

Four DNA-temperature-sensitive (ts) mutations were mapped in the genome of vaccinia virus (VV). Physical mapping of these mutations was performed by restriction analysis of the genomes of recombinants between VV DNA- ts mutants and ectromelia virus as well as by the marker rescue with cloned restriction fragments of VV DNA. One of the mutations was mapped on the HindIII-E-fragment. Biochemical studies of this mutant indicate that the mutation is not in the DNA polymerase gene which is located on the same fragment. The other three mutations were mapped in a 10 kilobase region in the middle of the HindIII-D-fragment. As shown previously, these mutations inactivate different genes, and the products of these genes participate directly in the DNA synthesis. Thus, at least three proteins involved in the VV DNA synthesis are encoded by neighboring genes in the central part of the viral genome.     

Mapping of the vaccinia virus DNA polymerase gene by marker rescue and cell-free translation of selected RNA

The previous demonstration that a phosphonoacetate (PAA)-resistant (PAAr) vaccinia virus mutant synthesized an altered DNA polymerase provided the key to mapping this gene. Marker rescue was performed in cells infected with wild-type PAA-sensitive (PAAs) vaccinia by transfecting with calcium phosphate-precipitated DNA from a PAAr mutant virus. Formation of PAAr recombinants was measured by plaque assay in the presence of PAA. Of the 12 HindIII fragments cloned in plasmid or cosmid vectors, only fragment E conferred the PAAr phenotype. Successive subcloning of the 15-kilobase HindIII fragment E localized the marker within a 7.5-kilobase BamHI-HindIII fragment and then within a 2.9-kilobase EcoRI fragment. When the latter was digested with ClaI, marker rescue was not detected, suggesting that the PAAr mutation mapped near a ClaI site. The sensitive ClaI site was identified by cloning partial ClaI-EcoRI fragments and testing them in the marker rescue assay. The location of the DNA polymerase gene, about 57 kilobases from the left end of the genome, was confirmed by cell-free translation of mRNA selected by hybridization to plasmids containing regions of PAAr vaccinia DNA active in marker rescue. A 100,000-dalton polypeptide that comigrated with authentic DNA polymerase was synthesized. Correspondence of the in vitro translation product with purified vaccinia DNA polymerase was established by peptide mapping.     

Fine mapping and molecular cloning of mutations in the herpes simplex virus DNA polymerase locus.

Mutations in five phenotypically distinct mutants derived from herpes simplex virus type 1 strain KOS which lie in or near the herpes simplex virus DNA polymerase (pol) locus have been fine mapped with the aid of cloned fragments of mutant and wild-type viral DNAs to distinct restriction fragments of 1.1 kilobase pairs (kbp) or less. DNA sequences containing a mutation or mutations conferring resistance to the antiviral drugs phosphonoacetic acid, acyclovir, and arabinosyladenine of pol mutant PAAr5 have been cloned as a 27-kbp Bg+II fragment in Escherichia coli. These drug resistance markers have been mapped more finely in marker transfer experiments to a 1.1-kbp fragment (coordinates 0.427 to 0.434). In intratypic marker rescue experiments, temperature-sensitive (ts), phosphonoacetic acid resistance, and acyclovir resistance markers of pol mutant tsD9 were mapped to a 0.8-kbp fragment at the left end of the EcoRI M fragment (coordinates 0.422 to 0.427). The ts mutation of pol mutant tsC4 maps within a 0.3-kbp sequence (coordinates 0.420 to 0.422), whereas that of tsC7 lies within the 1.1-kbp fragment immediately to the left (coordinates 0.413 to 0.420). tsC4 displays the novel phenotype of hypersensitivity to phosphonoacetic acid; however, the phosphonoacetic acid hypersensitivity phenotype is almost certainly not due to the mutation(s) conferring temperature sensitivity. The ts mutation of mutant tsN20--which does not affect DNA polymerase activity--maps to a 0.5-kbp fragment at the right-hand end of the EcoRI M fragment (coordinates 0.445 to 0.448). The mapping of the mutations in these five mutants further defines the limits of the pol locus and separates mutations differentially affecting catalytic functions of the polymerase.     

Fine-structure mapping of herpes simplex virus type 1 temperature-sensitive mutations within the short repeat region of the genome.

Cloned herpes simplex virus type 1 (HSV-1) DNA fragments were used to fine-structure map the temperature-sensitive (ts) lesions from four mutants, ts T, D, c75, and K, by marker rescue. These mutants all overproduced immediate-early viral polypeptides at the nonpermissive temperature. Although one of these viruses, ts K, gave a more restricted infected-cell polypeptide profile under these conditions than the other three, no complementation was detected between pairwise crosses of these mutants in the yield test. Recombination, however, was obtained between all mutant pairs except ts T and D. In physical mapping experiments, ts+ virus was recovered from cells coinfected with DNA of ts T, D, or c75 and BamHI fragment k from wild-type strain 17 HSV-1 DNA cloned in pAT153, whereas ts K was rescued by cloned HSV-1 BamHI-y. Both of these cloned DNA fragments contained sequences from the short repeat region of the HSV-1 genome. The ts mutations were more precisely mapped by marker rescue, using restriction enzyme fragments within BamHI-k and -y from cloned DNA. The smallest fragment able to rescue a mutant was 320 base pairs long. The order of the four mutations derived from these studies was consistent with the assignment by genetic recombination. All four lesions mapped within the coding sequences of the immediate-early polypeptide Vmw IE 175 (ICP4) which lie outside the "a" sequence. The results showed that mutations in different regions of the gene encoding Vmw IE 175 could produce similar phenotype effects at the nonpermissive temperature.     

Use of the Caulobacter crescentus genome sequence to develop a method for systematic genetic mapping

The functional analysis of sequenced genomes will be facilitated by the development of tools for the rapid mapping of mutations. We have developed a systematic approach to genetic mapping in Caulobacter crescentus that is based on bacteriophage-mediated transduction of strategically placed antibiotic resistance markers. The genomic DNA sequence was used to identify sites distributed evenly around the chromosome at which plasmids could be nondisruptively integrated. DNA fragments from these sites were amplified by PCR and cloned into a kanamycin-resistant (Kan(r)) suicide vector. Delivery of these plasmids into C. crescentus resulted in integration via homologous recombination. A set of 41 strains containing Kan(r) markers at 100-kb intervals was thereby generated. These strains serve as donors for generalized transduction using bacteriophage phiCr30, which can transduce at least 120 kb of DNA. Transductants are selected with kanamycin and screened for loss of the mutant phenotype to assess linkage between the marker and the site of the mutation. The dependence of cotransduction frequency on sequence distance was evaluated using several markers and mutant strains. With these data as a standard, previously unmapped mutations were readily localized to DNA sequence intervals equivalent to less than 1% of the genome. Candidate genes within the interval were then examined further by subcloning and complementation analysis. Mutations resulting in sensitivity to ampicillin, in nutritional auxotrophies, or temperature-sensitive growth were mapped. This approach to genetic mapping should be applicable to other bacteria with sequenced genomes for which generalized transducing phage are available.     

A method for rapid mapping of mutations by plasmid rescue strategy inSaccharomyces cerevisiae

The products ofPRP17 andPRP18 genes are required for the second step of pre-mRNA splicing reactions inSaccharomyces cerevisiae. Temperature-sensitive mutants at either of these loci accumulate products of the first splicing reaction at nonpermissive temperature. To characterize functional regions in these proteins the mutations in three temperature-sensitive alleles ofPRP17 and two temperature-sensitive alleles ofPRP18 were mapped by the plasmid rescue strategy, One of the procedures adopted in the past is plasmid rescue of the mutant allele followed by sequencing of the entire gene. In this work we describe an adaptation of the above procedure that allows, first, rapid mapping of chromosomal segments bearing the mutations, followed by sequence characterization of the minimal segment. The strategy adopted was to integrate a wild-type copy of the gene at the homologous mutant chromosomal locus, followed by recovery of the chromosomal fragments from these integrants as plasmids inE. coli. The recovered plasmids were screened by a complementation assay for those that contained in them the chromosomal mutation. The mutations in all the three alleles ofPRP17 map to a small region in the N-terminal half of the protein, whereas the temperature-sensitive mutations in the two alleles ofPRP18 map to different regions of the PRP18 protein. The recovered mutant plasmids from all five alleles at the two loci were sequenced and the nucleotide changes were found to result in missense mutations in each case. Our strategy is therefore a rapid method to map chromosomal mutations and is of general use in structure-function analysis of cloned genes.     

Two mutations in the dispensable part of alanine tRNA synthetase which affect the catalytic activity

Two previously described chromosomal mutant alleles, alaS4 and alaS5, of Escherichia coli Ala-tRNA synthetase have been analyzed. Each causes a sharp diminution in aminoacylation activity and disrupts the alpha 4 tetramer structure of identical chains of 875 amino acids; neither mutation significantly disturbs the activity for synthesis of alanyladenylate. The location of each mutation within the structural gene has been mapped by marker rescue with specific gene fragments. Each mutant allele was cloned from the genome by reciprocal recombination with a multicopy plasmid that contains segments of alaS which flank the respective mutations. Further analysis established: 1) a single G----A transition results in a Gly----Asp change for each mutant allele at codon 674 (alaS4) and at codon 677 (alaS5). 2) The mutations are in the oligomerization domain, about 200 amino acids beyond the C-terminal side of the catalytic domain that previously was mapped by deletion analysis; the mutations are, thus, in a part of the polypeptide which is dispensable for catalytic activity. 3) For both mutant enzymes, there is little effect of the mutation on the Km for tRNAAla; kcat for aminoacylation is decreased by an order of magnitude. These point mutations reveal a subtle integration of the catalytic core with parts of the polypeptide that are not essential for catalytic activity.     

Plasmid marker rescue transformation in Bacillus subtilis

We constructed an 18-megadalton plasmid (pBD221) carrying resistance determinants for kanamycin, chloramphenicol, and erythromycin, as well as the hisH determinant from the Bacillus licheniformis chromosome. This plasmid has a copy number of about one and can be stably maintained in Bacillus subtilis. Linear fragments of pBD221 DNA were used to transform competent cultures carrying mutant variants of the same plasmid. Rescue transformation did not proceed by recircularization and replication of the donor DNA. Rescue transformation exhibited first-order dependence on DNA concentration, and the concentration dependence curve was virtually identical to the curve obtained with chromosomal DNA. The donor DNA molecular weight dependence of plasmid marker rescue transformation obtained by using restriction fragments was not distinguishable from previously published data obtained by using fractionated sheared chromosomal DNA. Plasmid rescue transformation, like chromosomal transformation, was dependent on the recE, recA, recB, and recD gene products. Plasmid rescue transformation, like chromosomal transformation, proceeded with few exchanges. Linkage data obtained with the plasmid rescue system fit a quantitative model based on studies with chromosomal transformation. We conclude that plasmid marker rescue transformation probably proceeds by a mechanism similar to the mechanism used during the formation of chromosomal transformants and hence may be considered an appropriate general model for the study of transformational recombination.     

Physical mapping of two herpes simplex virus type 1 host shutoff loci: rescue of each ts mutation occurs with two unique cloned regions of the viral genome.

Two complementing temperature-sensitive (ts) herpes simplex virus type 1 (HSV-1) mutants, PAA1rts1 and ts199, were defective in viral DNA synthesis and in the shutoff of cellular macromolecular synthesis at 39.5 degrees C, the nonpermissive temperature. PAA1sts1 and PAA1rts1+ recombinants and PAA1rts1+ revertants were used to examine the contributions of the PAA1r mutation and the ts1 mutation of PAA1rts1 in affecting the levels of viral and cellular DNA synthesized at 34 and 39.5 degrees C. The results of this study suggests an interaction between the viral DNA polymerase and the ts1+ gene product during HSV-1 DNA replication and possibly in the inhibition of host DNA synthesis by HSV-1. Physical mapping of the ts mutations present in ts199 and the PAA1sts1 recombinant ts1-8 were performed by intratypic marker rescue experiments. Surprisingly, both the ts1-8 and ts199 mutations were rescued by two cloned fragments: ts1-8 by BglII-K (map coordinates 0.095 to 0.163) and BglII-I (map coordinates 0.314 to 0.417), while ts199 was rescued by BglII-K and BglII-O (map coordinates 0.163 to 0.197). In more refined mapping experiments, the regions between coordinates 0.347 to 0.378 and 0.126 to 0.163 were able to rescue the ts1-8 mutation. Southern hybridization analysis confirmed that the fragments that rescued ts1-8 and those that rescued ts199 had homology, as predicted by the physical mapping results.     

Physical mapping of the mutation in an antigenic variant of herpes simplex virus type 1 by use of an immunoreactive plaque assay.

Two mutations affecting herpes simplex virus type 1 glycoprotein B were mapped by marker rescue using cloned sequences of wild-type herpes simplex virus type 1 strain KOS DNA. One mutant, tsB5, is a temperature-sensitive mutant which does not express mature, functional glycoprotein B at the nonpermissive temperature. The other mutant, marB1.1, expresses an antigenic variant of glycoprotein B and was selected for resistance to neutralization by a monoclonal antibody. The mutation in tsB5 mapped to a 1.2-kilobase segment of the herpes simplex virus type 1 genome between coordinates 0.361 and 0.368, whereas the mutation in marB1.1 mapped to a 1.6-kilobase segment between coordinates 0.350 and 0.361. An in situ enzyme immunoassay was used to detect plaques of recombinant wild-type virus among the progeny of transfections with mutant marB1.1 DNA and wild-type DNA fragments.     

Construction and characterization of Pseudomonas aeruginosa algB mutants: role of algB in high-level production of alginate.

The algB gene, which is involved in the production of alginate in Pseudomonas aeruginosa, was localized to approximately 2.2 kilobases of DNA from strain FRD by using transposon Tn501 insertion mutagenesis, subcloning, and complementation techniques. The previously reported alg-50(Ts) mutation, which confers the phenotype of temperature-sensitive alginate production, was here designated as an algB allele. A transduction-mediated gene replacement technique was used for site-directed mutagenesis to isolate and characterize algB::Tn501 mutants of P. aeruginosa FRD. Although algB::Tn501 mutants had a nonmucoid phenotype (indicating an alginate deficiency), they still produced about 1 to 5% of wild-type levels of alginate in most growth media and up to 16% in very rich media. The algB::Tn501 mutations had no apparent effect on growth rate or growth requirements. Using another gene replacement technique called excision marker rescue, we constructed a chromosomal algB deletion (delta algB) mutant of P. aeruginosa FRD. The delta algB mutant also produced low levels of alginate as did the algB::Tn501 mutants. The alginate produced by algB::Tn501 mutants resembled wild-type alginate by all criteria studied: molecular weight, acetylation, and proportion of mannuronic and guluronic acids. Thus, the algB gene product is apparently involved in the high-level production of alginate by P. aeruginosa and is not directly involved in the pathway leading to its biosynthesis. Chromosomal mapping of an algB::Tn501 insertion showed linkage to the trp-2 marker on the FRD chromosome as does the algB50(Ts) mutation. The excision marker rescue technique was also used to place the algB::Tn501 marker on the chromosome of characterized strains of P. aeruginosa PAO. The algB::Tn501 mutation mapped near 21 min on the PAO chromosome.     

Method for induction of mutations in physically defined regions of the herpes simplex virus genome

A procedure was developed for inducing mutations in isolated restriction enzyme fragments of herpes simplex virus type 1 (HSV-1) DNA with nitrous acid. The mutations were then transferred to the viral genome by genetic recombination during cotransfection of rabbit kidney cells with the mutagenized fragments and intact HSV-1 DNA. The HpaI restriction enzyme fragments LD, B, LG, I, and J were mutagenized. Temperature-sensitive mutants were found at frequencies of 1 to 5% among the progeny of the transfections. Syncytial mutants also were found at high frequency when fragment B or LD was used for mutagenesis. Fifteen of these mutants, 11 temperature sensitive and 4 syncytial, were used for further studies, including complementation analysis, DNA synthesis, and marker rescue. Marker rescue data presented here and in the accompanying publication (A. L. Goldin, R. M. Sandri-Goldin, M. Levine, and J. C. Glorioso, J. Virol. 38: 50-58, 1981) confirm the map position of some of the newly isolated mutants.     

Correlation between umuC induction and Salmonella mutagenicity assay for quinolone antimicrobial agents

Abstract A novel genetic procedure is described to identify stress genes in Bacillus subtilis by insertion mutagenesis. In addition, this method allows the rapid mapping of the mutation and the establishment of the DNA sequence of the gene impaired by the mutation. Small restriction fragments of chromosomal DNA of B. subtilis are inserted into a pBR322-based vector, the recombinant plasmids are transformed into B. subtilis , and integrants are selected which arise by recombination between the insert and its homologous region within the bacterial chromosome. About two dozen heat-, cold- and salt-sensitive mutants were isolated. Four mutations were mapped using PBS1 transduction, and the physiology of one salt-sensitive mutant was analysed.     

Localization of symbiotic mutations in Rhizobium meliloti

A total of 5 Nod- and 57 Fix- symbiotic mutants of Rhizobium meliloti strain 41 have been isolated after either nitrosoguanidine or Tn5 transposition mutagenesis. Chromosomal locations of mutations in 1 Nod- and 11 Fix- derivatives were ascertained by transferring the chromosome (mobilized by plasmid R68.45), in eight fragments, into symbiotically effective recipients and testing the recombinants for symbiotic phenotype. Alternatively, the kanamycin resistance marker of Tn5 was mapped. In five mutants the fix alleles were localized on different chromosomal regions, but six other fix mutations and one nod mutation tested did not map onto the chromosome. It was shown that the chromosome-mobilizing ability (Cma+) of R68.45 was not involved in the mobilization of genes located extrachromosomally. Moreover, Cma- derivatives of R68.45 could mobilize regions of the indigenous plasmid pRme41b but not chromosomal genes. Thus, mobilization of a marker by Cma- R68.45 indicates its extrachromosomal location. With a 32P-labeled DNA fragment carrying Tn5 as a hybridization probe, it was shown that in five extrachromosomally located Tn5-induced fix mutants and one nod mutant Tn5 was localized on plasmid pRme41b. This is in agreement with the genetic mapping data.     

Chromosomal Basis of the Merozygosity in a Partially Diploid Mutant of Pneumococcus

A sulfonamide-resistant mutant of pneumococcus, sulr-c, displays a genetic instability, regularly segregating to wild type. DNA extracts of derivatives of the strain possess transforming activities for both the mutant and wild-type alleles, establishing that the strain is a partial diploid. The linkage of sulr-c to strr-61, a stable chromosomal marker, was established, thus defining a chromosomal locus for sulr-c. DNA isolated from sulr-c cells transforms two mutant recipient strains at the same low efficiency as it does a wild-type recipient, although the mutant property of these strains makes them capable of integrating classical "low-efficiency" donor markers equally as efficiently as "high efficiency" markers. Hence sulr-c must have a different basis for its low efficiency than do classical low efficiency point mutations. We suggest that the DNA in the region of the sulr-c mutation has a structural abnormality which leads both to its frequent segregation during growth and its difficulty in efficiently mediating genetic transformation.     

Genes from the cyanobacterium Agmenellum quadruplicatum isolated by complementation: characterization and production of merodiploids

The isolation of several biosynthetic genes from a cyanobacterium, Agmenellum quadruplicatum, by complementation of auxotrophic mutations in Escherichia coli, and their partial characterization, is described. Although our search for such genes has not been exhaustive, it appears that complementation of E. coli mutations may be of limited utility for the identification and/or isolation of cyanobacterial genes. Despite some overlap in the complementation abilities of these isolated cyanobacterial DNA fragments, the genes that we have studied in some detail are not located in operons. We have used mutagenized versions of these cyanobacterial DNA fragments to produce mutant phenotypes in the cyanobacterium, but clean auxotrophs were not obtained. Complementation of these mutant phenotypes can be obtained when the appropriate wild-type DNA fragment is introduced into the cyanobacterium on a shuttle vector. Recombination between two copies of a cyanobacterial gene occurs at high frequency in the cyanobacterium.     

Activation of protein kinase Tel1 through recognition of protein-bound DNA ends

Double-strand breaks (DSBs) in chromosomal DNA elicit a rapid signaling response through the ATM protein kinase. ATM corresponds to Tel1 in budding yeast. Here we show that the catalytic activity of Tel1 is altered by protein binding at DNA ends via the Mre11-Rad50-Xrs2 (MRX) complex. Like ATM, Tel1 is activated through interaction with the MRX complex and DNA ends. In vivo, Tel1 activation is enhanced in sae2Δ or mre11-3 mutants after camptothecin treatment; both of these mutants are defective in the removal of topoisomerase I from DNA. In contrast, an sae2Δ mutation does not stimulate Tel1 activation after expression of the EcoRI endonuclease, which generates "clean" DNA ends. In an in vitro system, tethering of Fab fragments to DNA ends inhibits MRX-mediated DNA end processing but enhances Tel1 activation. The mre11-3 mutation abolishes DNA end-processing activity but does not affect the ability to enhance Tel1 activation. These results support a model in which MRX controls Tel1 activation by recognizing protein-bound DNA ends.