Double-chain-cut sites are recombination hotspots in the Red pathway of phage lambda.

The Red recombination pathway of phage lambda is shown to target recombination to double-chain ends of DNA. A double-chain cut, delivered in vivo to only one of two parents participating in a lambda lytic cross by a type II restriction endonuclease, increases the proportion of crossing over in the interval containing the cut compared with other intervals. The stimulating effect of a cut is evident whether replication is inhibited or permitted. Cut stimulation can move away from the initial cut-site, presumably by double-chain degradation. Movement of the stimulating effect of a cut is dependent on the Escherichia coli gene recA when the cross is carried out under conditions that inhibit phage replication. When replication is permitted, all aspects of cut-stimulated recombination are independent of recA. Evidence is presented to show that the reaction that is stimulated by cutting is often non-reciprocal at the molecular level.

Sequential determination of ligands binding to discrete components in heterogeneous mixtures by iterative panning and blocking (IPAB).

Biopanning has been used extensively in conjunction with purified components, but there are also examples in which mixtures of targets have been investigated. This study introduces a methodological innovation, termed iterative panning and blocking (IPAB), to extend the range of specific interactions that can be probed in mixtures. Here this procedure is used to probe a mixture of high molecular mass components of human cord blood with phage-peptide display libraries. The initial panning recovered phage that bore the consensus motif Gly-Pro-Arg-Pro, a known fibrinogen-binding motif. These phage bound specifically to purified fibrinogen. A series of peptides containing the Gly-Pro-Arg-Pro motif efficiently blocked the binding of phage having the same motif, presumably by binding to their common target. A second round of panning was performed against the same target mixture in the presence of this blocking peptide. Phage recovered from this second panning exhibited a motif (Ser-His-Tyr) that was subsequently shown to bind specifically to complement component C1q. A second peptide containing this motif specifically blocked the interaction of the phage with C1q. A third round of panning performed in the presence of both the fibrinogen- and the C1q- blocking peptides yielded phage with a new peptide motif (Asn-Pro-Phe) that also bound specifically to C1q, apparently at a new site. The three motifs isolated through this iterative process were distinct in that each was blocked only by its corresponding peptide. This IPAB strategy can be applied to many high diversity selection procedures that target complex mixtures.

In vivo packaging of bacteriophage lambda monomeric chromosomes.

There is an apparent paradox between the reported requirements for lambda DNA packaging in vivo and in vitro. In vivo, DNA concatemers are required for packaging. On the other hand, in vitro, packaging extracts can encapsidate either linear or circular monomeric lambda DNA. Perhaps cellular nucleases restrict the in vivo ability of monomers to package by degrading a free double chain end present as an intermediate in the packaging reaction. Consistent with this hypothesis, enhanced packaging of monomers was found in an ExoV- host. No additional enhancement was noted in a host also mutant for sbcB and sbcC. We isolated a mutant phage for which in vivo packaging of monomeric lambda chromosomes is increased about 10(3)-fold. The responsible mutation (plm1 for packages lambda monomers) was mapped to cro, sequenced, and found to cause a change from Ala29 to Ser in the alpha3 helix of Cro's DNA binding domain. Density transfer experiments showed that packaging of both plm1 and wild-type lambda was aided by allowing some DNA synthesis. However, the packaged chromosomes had not themselves undergone a full round of replication and therefore were not part of a canonical concatemer made by replication. Other tests showed that packaged phage had not been part of concatemers made by recombination or by annealing at cos. Our results with wild-type lambda also favor models in which two cos sites are needed for packaging, but these sites need not be in cis. In lambda plm1, replication intermediates may serve as substrates for encapsidation.

Short-patch reverse transcription in Escherichia coli.

Chimeras of RNA and DNA have distinctive physical and biological properties. Chimeric oligonucleotides that contained one, two or three ribonucleotides whose phosphodiester backbone was covalently continuous with DNA were synthesized. Site-directed mutagenesis was used to assess genetic information transfer from the ribonucleotide positions. Transfer was scored by the formation or reversion of an ochre site that also corresponded to a restriction cleavage site. This allowed physical as well as genetic assay of mutational events. Bases attached to the ribonucleotides were able to accurately direct the synthesis of progeny DNA. The results suggest that in vivo DNA polymerases utilize a "running start" on a DNA backbone to continue across a covalent backbone junction into a region of ribonucleotides and then back again onto a normal DNA backbone. The phenomenon is designated short-patch reverse transcription (SPRT) by analogy to short-patch mismatch correction and reverse transcription as the term is generally used. The possibility is considered that SPRT contributes to an unrecognized pathway of mutagenesis.

Tests of the double-strand-break repair model for red-mediated recombination of phage lambda and plasmid lambda dv.

The double-strand-break repair (DSBR) model was formulated to account for various aspects of yeast mitotic and meiotic recombination. In this study three features of the DSBR model are tested for Red-mediated recombination between phage lambda and lambda dv, a plasmid that is perfectly homologous to about 10% of lambda. The results support the applicability of the DSBR model to lambda's Red system: (1) Creating a double-strand-break (DSB) within the region of homology shared by phage and plasmid increases their genetic interaction by about 20-fold. A DSB outside the region of shared homology has no such effect. (2) Both patches, i.e., simple marker rescue, and splices, i.e., co-integration of the phage and plasmid, are stimulated by a DSB in the region of shared homology. (3) Co-integrants harbor a duplication of the region of shared homology. Among co-integrants that were formed by the creation of a DSB, there is a preferential loss of whichever allele was in cis to a utilized cut site. The DSBR model as originally formulated involves the isomerization and cleavage of Holliday junctions to resolve the canonical intermediate. We propose as an alternative mechanism that a topoisomerase can resolve the canonical DSBR intermediate.

C1q-binding peptides share sequence similarity with C4 and induce complement activation.

Two peptide motifs that bind to C1q have been identified from phage displayed libraries. A first panning cycle recovered phage that displayed a [N/S]PFxL motif. A synthetic peptide with that motif blocked those phage from binding to C1q. A second panning cycle was conducted with the [N/S]PFxL motif peptide present, leading to recovery of phage displaying a different motif, SHY. The two motifs are specific for C1q and are competed by DNA and the cognate synthetic peptide but not by immunoglobulins. Phage displayed peptide sequences containing the [N/S]PFxL have significant sequence similarity to a region of complement component C4, suggesting a possible site of interaction between C4, or one of its processed forms, and C1q. The SHY motif peptide induces C4 consumption in a hemolytic assay, suggesting that it activates C1 independent of immune complexes. This peptide may activate C1 by a mechanism similar to the beta-amyloid peptides found in Alzheimer's disease.

Specific blocking to improve biopanning in biological samples such as serum and hybridoma supernatants.

Screening phage-displayed peptide libraries (biopanning) is an important technique for acquiring peptide ligands and for mapping peptide epitopes recognized by antibodies (Ab). In biological samples, other materials, not only contaminants but also natural constituents, often interfere with biopanning. Capture methods use anchoring Abs that reduce the need for purification of the intended panning target from a crude sample. This capture method is analogous to sandwich ELISA. However, when the target molecule concentration is low in the initial mixture, the panning of a captured target often yields epitopes that bind to the capture antibody rather than the target of interest. We have developed a methodology that utilizes specific blocking reagents of the capture Ab to extend the sensitivity and applicability of the capture approach to phage panning. A flowchart is presented to enable the worker to begin panning with the simplest approach and then to employ sandwich capture and specific blocking reagents as necessary.

Interspecies recombination between enterococci: genetic and phenotypic diversity of vancomycin-resistant transconjugants.

Handwerger and colleagues demonstrated that a particular clinical isolate of Enterococcus faecium, designated GUC, and here redesignated as GUCR, can conjugatively transfer vancomycin resistance. The vancomycin resistance is encoded by a chromosomally born linked set of genes in the donor, designated the vanA cluster, to the chromosome of an E. faecalis recipient, JH2-2. Here it is reported that an earlier isolate of E. faecium from the same patient who later harbored the vancomycin-resistant E. faecium GUCR lacks the vanA gene cluster but is otherwise similar (by SmaI chromosomal fingerprint and metabolic fingerprinting) to the vancomycin-resistant GUCR. Therefore, "GUCS" is a strong suspect as the base strain for the clinical acquisition of the vanA cluster present in GUCR. Thirteen laboratory-generated vanA transconjugants derived from conjugation between GUCR and JH2-2 were subjected to further analysis, allowing a comparison between transfer in the laboratory and transfer that occurred in the clinical setting. Surprisingly, each JH2-2 transconjugant had a unique constellation of abilities to oxidize various members of a panel of potential carbon sources. This pattern was stable for each transconjugant, and it was not changed by growing the strains with or without vancomycin. Transconjugants had pulsed-field gel electrophoretic (PFGE) patterns largely consistent with that of JH2-2, the recipient in conjugation experiments. However, PFGE analysis showed that a large but variable amount of DNA, between 145 kb and 277 kb, was transferred into different transconjugants. The mechanism appears to be conjugative transposition in which new DNA is added to the pre-existing genome rather than substituting for a segment in the recipient. Mapping and hybridization studies of several transconjugants showed that each received similar, but not exactly the same, DNA fragment of at least 30 kb from the donor. Sequencing of 16S ribosomal genes was used to confirm that the recipient and donor strains used in transconjugation experiments were different species. Sequence analysis was also used to consider the possibility that rRNA operons might be mobilized in conjugation, but no evidence for the transfer of rDNA operons was found. An apparent insertion sequence in E. faecium almost identical to IS 1485 and 57% sequence identity to IS 199 of Streptococcus mutans was found in the region of DNA transferred. The results imply new consequences of conjugative transfer and interspecies recombination.

Sex is for sisters: intragenomic recombination and homology-dependent mutation as sources of evolutionary variation.

Sex and recombination generate variation via processes that depend on an underlying complementarity between participants. Sex between DNA segments depends on their sequences having enough in common. Viewed in this way, sex does not depend on genes that originate in separate cells. Sex in the single genome uses many of the same mechanisms as intergenomic sex but has not been properly appreciated as a source of variation or as a selectable process. Mutation is the generation of new sequences rather than the novel grouping of pre-existing alleles. Mechanisms of mutation that depend on pre-existing sequence similarities in the haploid genome are a source of variation with significant and special characteristics.

Hereditary stability and variation in evolution and development.

Evolution and development are both lineage processes but are often conceptualized as occurring by different and mutually exclusive mechanisms. It is conventionally asserted that evolution occurs via the random generation of diversity and the subsequent survival of those that pass selection. On the other hand, development is too often presented as proceeding via the unfolding of a deterministic program encoded in the DNA sequence. In biology, universal generalizations are rare and dogmas are often wrong for particular cases. Deterministic mechanisms contribute some of the new DNA sequences that subsequently become substrates for natural selection. Conversely, stochastic and selective mechanisms are intrinsic to development, and also to maintenance of the immune, and possibly, nervous systems. Cancer appears to be another process that straddles distinctions between evolutionary and developmental modes of hereditary change and stabilization. DNA sequence changes are an essential feature of many cancers, but there are also aspects of the disease similar to developmental lineage gone awry. The literature suggests that the cellular changes that give rise to cancer occur by mechanisms commonly associated with both evolutionary and developmental lineage pathways.

MEPS parameters and graph analysis for the use of recombination to construct ordered sets of overlapping clones.

Homologous recombination can provide a basis for the construction of an ordered set of overlapping clones. The principle is to make two libraries, each in a vector that has a different selectable marker flanking the insert site. Recombination between the flanking markers, leading to a selectable phenotype, can only occur as the consequence of crossing over between inserts. The two libraries are crossed in a matrix, allowing the construction of an ordered set. The logic, akin to S. Benzer's (1961, Genetics 47:403-415) for the arrangement of deletion and point mutations, has a graph theoretic formulation, which helps to cope with the complex and noisy data inherent in the physical mapping of genomes rich in repeated sequences. The minimum length of identity required for homologous recombination is called the MEPS (minimum efficient processing segment) and is a property of each recombination pathway. The amount and the type of sequence similarity required for two sequences to recombine is different from that implied by either the conservation of restriction sites or by most procedures of hybridization.

The barrier to recombination between Escherichia coli and Salmonella typhimurium is disrupted in mismatch-repair mutants.

The requirement for DNA sequence homology in generalized genetic recombination is greatly relaxed in bacterial mutL, mutS and mutH mutants deficient in mismatch repair. In such mutants, intergeneric recombination occurs efficiently between Escherichia coli and Salmonella typhimurium, which are approximately 20% divergent in DNA sequence. This finding has implications for speciation, for regulating recombination between diverged repeated sequences, and for hitherto difficult interspecies hybridizations.

Evidence that the normal route of replication-allowed Red-mediated recombination involves double-chain ends.

Recombination mediated by the Red pathway of bacteriophage lambda is focused towards sites of double-chain cuts. Double-chain ends created either by type II restriction enzymes acting at unmodified recognition sites or by lambda's packaging enzyme, terminase, acting at cos are utilized in a manner similar to the double-chain break repair pathway of recombination in yeast. When lambda is allowed to recombine during replicative growth, spontaneous recombination is approximately evenly distributed along the chromosome. It has been proposed that replication-allowed recombination also is initiated by double-chain ends. In order to test this hypothesis we ask if the in vivo expression of the Mu gam protein is inhibitory to Red recombination. Mu gam has been shown in vitro to bind to linearized duplex DNA and to shield bound DNA from exonucleases. The expression of Mu gam is found to be inhibitory to Red recombination whether replication is blocked or allowed. As a control we ask if Mu gam inhibits Int-mediated recombination. It has been well documented that the Int pathway of recombination does not involve any double-chain breaks and, consistent with this, the Int pathway is not inhibited by Mu gam. We suggest that the in vivo expression of Mu gam or other similar activities may be a generally useful way to determine if those processes that respond to an artificially introduced double-chain cut normally involve double-chain ends.

Bacteriophage T4 gp2 interferes with cell viability and with bacteriophage lambda Red recombination.

The T4 head protein, gp2, promotes head-tail joining during phage morphogenesis and is also incorporated into the phage head. It protects the injected DNA from degradation by exonuclease V during the subsequent infection. In this study, we show that recombinant gp2, a very basic protein, rapidly kills the cells in which it is expressed. To further illustrate the protectiveness of gp2 for DNA termini, we compare the effect of gp2 expression on Red-mediated and Int-mediated recombination. Red-mediated recombination is nonspecific and requires the transient formation of double-stranded DNA termini. Int-mediated recombination, on the other hand, is site specific and does not require chromosomal termini. Red-mediated recombination is inhibited to a much greater extent than is Int-mediated recombination. We conclude from the results of these physiological and genetic experiments that T4 gp2 expression, like Mu Gam expression, kills bacteria by binding to double-stranded DNA termini, the most likely mode for its protection of entering phage DNA from exonuclease V.

Extending the chemistry that supports genetic information transfer in vivo: phosphorothioate DNA, phosphorothioate RNA, 2'-O-methyl RNA, and methylphosphonate DNA.

DNA and RNA are the polynucleotides known to carry genetic information in life. Chemical variants of DNA and RNA backbones have been used in structure-function and biosynthesis studies in vitro, and in antisense pharmacology, where their properties of nuclease resistance and enhanced cellular uptake are important. This study addressed the question of whether the base(s) attached to artificial backbones encodes genetic information that can be transferred in vivo. Oligonucleotides containing chemical variants of DNA or RNA were used as primers for site-specific mutagenesis of bacteriophage f1. Progeny phage were scored both genetically and physically for the inheritance of information originally encoded by bases attached to the nonstandard backbones. Four artificial backbone chemistries were tested: phosphorothioate DNA, phosphorothioate RNA, 2'-O-methyl RNA and methylphosphonate DNA. All four were found capable of faithful information transfer from their attached bases when one or three artificial positions were flanked by normal DNA. Among oligonucleotides composed entirely of nonstandard backbones, only phosphorothioate DNA supported genetic information transfer in vivo.

Chromosomal transformation of Escherichia coli recD strains with linearized plasmids.

Wild-type Escherichia coli are resistant to genetic transformation by purified linear DNA, probably in part because of exonuclease activity. We demonstrate that E. coli containing a recD mutation could be easily transformed by linearized plasmids containing a selectable marker. The marker was transferred to the chromosome by homologous recombination, whereas plasmid markers not in the region of homology were lost.

The spo0A gene is implicated in the maintenance of non-complementing diploids in Bacillus subtilis.

Bacillus subtilis can exist in a diploid state in which two genetically distinct chromosomes co-exist in the same cell and yet only one of them is expressed, thereby determining the phenotype. Such cells are called non-complementing diploids (Ncds). In this study, two types of experiments are reported which indicate that a previously known pleiotropic gene, spo0A, plays a role in the maintaining the diploid state, as follows. (i) When protoplasts of two Spo0A mutant strains were fused, the resulting products continued to segregate cells of both parental phenotypes for many more divisions than had been reported previously. (ii) When a stable Ncd (an Ncd in which the unexpressed markers are not spontaneously activated at a detectable level) harbouring a chloramphenicol acetyltransferase gene on the silent chromosome was transformed with spo0A null alleles the transformants often expressed chloramphenicol acetyltransferase activity. Together these results indicate that the spo0A gene is involved in maintenance of the diploid state in both unstable and stable Ncds.

Parallel overlap assembly for the construction of computational DNA libraries.

Algorithms for computing with DNA currently require the construction of pools of molecules in which each distinct molecule represents a different starting point for the calculation. We have begun building such pools using the technique of parallel overlap assembly that is already used for the generation of diversity in biologically useful combinatorial search techniques such as gene shuffling. Unlike these applications, a pool in a molecular computer must be complete, containing all possible strands, and ordered, having minimal contamination from incorrectly assembled DNA. We present an experiment in which parallel overlap assembly is used to construct a computational pool and an experiment in which this pool is used to solve the NP-complete maximal-clique problem.