Nancy Kleckner

Improved single and multicopy lac-based cloning vectors for protein and operon fusions

We describe several new vectors for the construction of operon and protein fusions to the Escherichia coli lacZ gene. In vitro constructions utilize multicopy plasmids containing suitable cloning sites located between upstream transcription terminators and downstream lac operon segments whose lacZ genes retain or lack translational start signals. Single-copy lambda prophage versions of multicopy constructs can be made genetically, without in vitro manipulation. The new vectors, both single and multicopy, are improved in that they have very low levels of background lac gene expression, which makes possible the easy detection and accurate quantitation of very weak transcriptional and translational signals. These vectors were developed for analysis of the expression of IS10s transposase gene, which is transcribed less than, once per generation, and whose transcripts are translated on average less than once each. Both single and multicopy constructs can also be used to select mutations affecting fusion expression, and mutations isolated in single-copy constructs can be crossed genetically back onto multicopy plasmids for further analysis.

Meiosis-Specific DNA Double-Strand Breaks Are Catalyzed by Spo11, a Member of a Widely Conserved Protein Family

Meiotic recombination in S. cerevisiae is initiated by double-strand breaks (DSBs). In certain mutants, breaks accumulate with a covalently attached protein, suggesting that cleavage is catalyzed by the DSB-associated protein via a topoisomerase-like transesterase mechanism. We have purified these protein-DNA complexes and identified the protein as Spo11, one of several proteins required for DSB formation. These findings strongly implicate Spo11 as the catalytic subunit of the meiotic DNA cleavage activity. This is the first identification of a biochemical function for any of the gene products involved in DSB formation. Spo11 defines a protein family with other members in fission yeast, nematodes, and archaebacteria. The S. pombe homolog, rec12p, is also known to be required for meiotic recombination. Thus, these findings provide direct evidence that the mechanism of meiotic recombination initiation is evolutionarily conserved.

A pathway for generation and processing of double-strand breaks during meiotic recombination in S. cerevisiae

We have identified and analyzed a meiotic reciprocal recombination hot spot in S. cerevisiae. We find that double-strand breaks occur at two specific sites associated with the hot spot and that occurrence of these breaks depends upon meiotic recombination functions RAD50 and SPO11. Furthermore, these breaks occur in a processed form in wild-type cells and in a discrete, unprocessed form in certain nonnull rad50 mutants, rad50S, which block meiotic prophase at an intermediate stage. The breaks observed in wild-type cells are similar to those identified independently at another recombination hot spot, ARG4. We show here that the breaks at ARG4 also occur in discrete form in rad50S mutants. Occurrence of breaks in rad50S mutants is also dependent upon SPO11 function. These observations provide additional evidence that double-strand breaks are a prominent feature of meiotic recombination in yeast. More importantly, these observations begin to define a pathway for the physical changes in DNA that lead to recombination and to define the roles of meiotic recombination functions in that pathway.

The Single-End Invasion: An Asymmetric Intermediate at the Double-Strand Break to Double-Holliday Junction Transition of Meiotic Recombination

We identify a novel meiotic recombination intermediate, the single-end invasion (SEI), which occurs during the transition from double-strand breaks (DSBs) to double-Holliday junction (dHJs). SEIs are products of strand exchange between one DSB end and its homolog. The structural asymmetry of SEIs indicates that the two ends of a DSB interact with the homolog in temporal succession, via structurally (and thus biochemically) distinct processes. SEIs arise surprisingly late in prophase, concomitant with synaptonemal complex (SC) formation. These and other data imply that SEIs are preceded by nascent DSB-partner intermediates, which then undergo selective differentiation into crossover and noncrossover types, with SC formation and strand exchange as downstream consequences. Late occurrence of strand exchange provides opportunity to reverse recombinational fate even after homologs are coaligned and/or synapsed. This feature can explain crossover suppression between homeologous and structurally heterozygous chromosomes.

Analysis of wild-type and rad50 mutants of yeast suggests an intimate relationship between meiotic chromosome synapsis and recombination.

The RAD50 gene of S. cerevisiae is required during meiosis for both recombination and chromosome synapsis and is also required for repair of double strand breaks during vegetative growth. We present below the isolation and analysis of several types of rad50 mutants. We show that null mutations block both meiotic recombination and formation of synaptonemal complex (SC) at early stages, while nonnull mutations block both processes at intermediate stages. These observations suggest that recombination and SC formation involve a series of intimately related events. Furthermore, all rad50 mutants block formation of tripartite SC structure but permit other aspects of SC development, i.e., formation of axial cores. In light of this and other observations, the meiotic and mitotic defects of rad50 mutants can be accounted for economically by the proposal that meiotic recombination, meiotic chromosome pairing, and vegetative DNA repair all use a common chromosomal homology search that involves RAD50 function.

Crossover/Noncrossover Differentiation, Synaptonemal Complex Formation, and Regulatory Surveillance at the Leptotene/Zygotene Transition of Meiosis

Yeast mutants lacking meiotic proteins Zip1, Zip2, Zip3, Mer3, and/or Msh5 (ZMMs) were analyzed for recombination, synaptonemal complex (SC), and meiotic progression. At 33 degrees C, recombination-initiating double-strand breaks (DSBs) and noncrossover products (NCRs) form normally while formation of single-end invasion strand exchange intermediates (SEIs), double Holliday junctions, crossover products (CRs), and SC are coordinately defective. Thus, during wild-type meiosis, recombinational interactions are differentiated into CR and NCR types very early, prior to onset of stable strand exchange and independent of SC. By implication, crossover interference does not require SC formation. We suggest that SC formation may require interference. Subsequently, CR-designated DSBs undergo a tightly coupled, ZMM-promoted transition that yields SEI-containing recombination complexes embedded in patches of SC. zmm mutant phenotypes differ strikingly at 33 degrees C and 23 degrees C, implicating higher temperature as a positive effector of recombination and identifying a checkpoint that monitors local CR-specific events, not SC formation, at late leptotene.

New Tn10 derivatives for transposon mutagenesis and for construction of lacZ operon fusions by transposition

We describe below several new variants of the tetracycline-resistance transposon Tn10 which are more useful than the wild-type transposon for many types of genetic and physical analysis of bacteria. These derivatives have one or more of the following new properties: (i) new drug resistance markers; (ii) high transposition frequencies; (iii) removal of the transposase gene to a position outside of the transposing segment; (iv) internal deletions which eliminate the ability of Tn10 to make adjacent deletion/inversions; or (v) addition of a trp-lac operon fusion segment just inside one terminus such that insertion can automatically generate a transcriptional fusion to the interrupted operon. Phage and plasmid vehicles carrying these new elements are described.

SeqA: A negative modulator of replication initiation in E. coli

In E. coli, replication initiates at a genetically unique origin, oriC. Rapidly growing cells contain multiple oriC copies. Initiation occurs synchronously, once and only once per cell cycle at all origins present. Secondary initiations are prevented by a sequestration process that acts uniquely on newly replicated origins, which are marked because they are hemimethylated at GATC sites. We report the identification of a gene required for sequestration and demonstrate that this gene, seqA, also serves as a negative modulator of the primary initiation process. All previously identified in vivo initiation factors play positive roles. Thus, precise control of replication initiation may involve a balance between positive and negative elements. We suggest that SeqA might be a cooperativity factor, acting to make the replication initiation process dependent upon cooperative interactions among components.

Identification of double holliday junctions as intermediates in meiotic recombination

During meiosis, branched DNA molecules containing information from both parental chromosomes occur in vivo at loci where meiosis-specific double-stranded breaks occur. We demonstrate here that these joint molecules are recombination intermediates: they contain single strands that have undergone exchange of information. Moreover, these joint molecules are resolved into both parental and recombinant duplexes when treated in vitro with Holliday junction-resolving endonucleases RuvC or T4 endo VII. Taken together with previous observations, these results strongly suggest that joint molecules are double Holliday junctions.

Genetic engineering in vivo using translocatable drug-resistance elements. New methods in bacterial genetics.

Abstract A number of translocatable drug-resistance elements have recently been described which are able to insert themselves into a large number of different sites in prokaryotic genomes. These elements cause recognizable mutations when insertion occurs within a structural gene or an operon. Drug-resistance elements are also associated with other kinds of illegitimate recombination events, notably deletions and inversions. This paper summarizes uses to which these properties of translocatable drugr-esistance elements can be put in genetic manipulations of bacteria. Translocatable drug-resistance elements are useful in isolation of mutants (even where the mutant phenotype is not easily scored), in the construction of strains and other genetic manipulations (even when selection is difficult or impossible), in localized mutagenesis, in chromosomal mapping, in construction of Hfr strains with known origin and direction of chromosome transfer, in complementation tests, in construction of new F′ plasmids, in construction of new specialized transducing phages, in isolation of deletions with one or both endpoints specified, in construction of gene and operon fusions, and in the selection and maintenance of chromosomal duplications. Experiments are described which illustrate many of these techniques.