Filamentous phage integration requires the host recombinases XerC and XerD

Many bacteriophages and animal viruses integrate their genomes into the chromosomal DNA of their hosts as a method of promoting vertical transmission. Phages that integrate in a site-specific fashion encode an integrase enzyme that catalyses recombination between the phage and host genomes. CTX phi is a filamentous bacteriophage that contains the genes encoding cholera toxin, the principal virulence factor of the diarrhoea-causing Gram-negative bacterium Vibrio cholerae. CTX phi integrates into the V. cholerae genome in a site-specific manner; however, the approximately 6.9-kilobase (kb) CTX phi genome does not encode any protein with significant homology to known recombinases. Here we report that XerC and XerD, two chromosome-encoded recombinases that ordinarily function to resolve chromosome dimers at the dif recombination site, are essential for CTX phi integration into the V. cholerae genome. The CTX phi integration site was found to overlap with the dif site of the larger of the two V. cholerae chromosomes. Examination of sequences of the integration sites of other filamentous phages indicates that the XerCD recombinases also mediate the integration of these phage genomes at dif-like sites in various bacterial species.     

Uncoupling of the recombination and topoisomerase activities of the gamma delta resolvase by a mutation at the crossover point

In several well-characterized site-specific recombination systems it has been shown that, for efficient recombination, the two recombining sites must have identical DNA sequences across the region between the staggered points of exchange. The precise DNA sequence of this overlap region, however, appears to be of little importance (with the exception of one position in the loxP site of bacteriophage P1 (ref. 6]. In this report we characterize a mutant recombination site for the site-specific recombination enzyme gamma delta resolvase (encoded by the gamma delta transposon), in which the dinucleotide at the crossover point is changed from AT to CT. Our results indicate that identity of the two overlap regions is not sufficient for recombination. Although resolvase binds normally to the mutant site and induces the structural deformation characteristic of the wild-type recombination site, catalysis at the crossover point (cutting and rejoining of DNA strands) is effectively limited to just one of the two strands, allowing resolvase to act as a topoisomerase but not as a recombinational enzyme.     

Direct role of the himA gene product in phage lambda integration

The integration of phage lambda into the Escherichia coli chromosome is accomplished by a site-specific recombination between two unique DNA sequences (attB on the bacterial genome and attP on the phage; reviewed in refs 2, 3) and requires proteins encoded by both the bacterium and the phage. Genetic and biochemical studies have shown that bacterial strains mutant in the himA gene, located at 38 min on the E. coli map, are defective in the activity of the host-encoded component. They are, moreover, defective for the growth of bacteriophage Mu, for precise excision of transposable antibiotic resistance determinants and for the synthesis of the lambda int gene product. We now show that the himA gene product (phimA) is not solely a regulator of genes involved in integration but is one of two host polypeptides required for integrative recombination.     

Spatial relationship of the Fis binding sites for Hin recombinational enhancer activity

Site-specific recombination reactions involve the joining or rearrangement of discrete DNA segments in a highly precise manner. A site-specific DNA inversion regulates the expression of flagellin genes in Salmonella by switching the orientation of a promoter. Analysis of the reaction has shown that, in addition to DNA sequences at the two boundaries of the 1-kilobase invertible segment where strand exchange occurs, another cis acting sequence is required for efficient inversion. This 60-base-pair enhancer-like sequence can function at many different locations and in either orientation in a plasmid substrate. It includes two binding sites for a host protein called Factor II or Fis (refs 4 and 5). Here we have investigated the importance of the spatial relationship between the two Fis binding sites for enhancer activity and have found that the correct helical positioning of the binding sites on the DNA is critical. However, this result could not be accounted for by effects on Fis binding. We propose a model for enhancer function in which the enhancer region acts to align the recombination sites into a specific conformation required for productive synapsis.     

DNA sequence at the end of IS1 required for transposition

The insertion sequence IS1 belongs to a class of bacterial transposable genetic elements that can form compound transposons in which two copies of IS1 flank an otherwise non-transposable segment of DNA. IS1 differs from other known elements of this class (such as IS10, IS50 and IS903) in several respects. It is one of the smallest known insertion elements, exhibits a relatively complex array of open reading frames, is present in the chromosomes of various Enterobacteria, in some cases in many copies, and its insertion can result in the duplication of either 8 or 9 base pairs (bp) in the target DNA. Furthermore, although, like other members of the compound class, it seems to undergo direct transposition, IS1 also promotes replicon fusion (co-integrate formation) at a relatively high frequency. Like all other elements studied to date, the integrity of the extremities of IS1 are essential for efficient transposition. We have constructed a test system to determine the minimal DNA sequences at the extremities of IS1 required for transposition. Sequential deletions of the end sequences reveal that 21-25 bp of an isolated extremity are sufficient for transposition. A specific sequence 13-23 bp from the ends, defining the edge of the minimal sequence, is implicated as an essential site. The sites, symmetrically arrayed at both ends of IS1, correspond to the apparent consensus sequence of the known binding sites for the Escherichia coli DNA-binding protein (called integration host factor or IHF) which is required for the site-specific recombination that leads to integration of bacteriophage lambda into the bacterial genome. The sites at the ends of IS1 may thus bind a host protein, such as JHF or a related protein, that is involved in regulating the transposition apparatus.     

Functional replacement of a protein-induced bend in a DNA recombination site

In recent years the capacity of proteins to bend DNA by binding to specific sites has become a widely appreciated phenomenon. In many cases, the protein-DNA interaction is known to be functionally significant because destruction of the DNA site or the protein itself results in an altered phenotype. An important question to be answered in these cases is whether bending of DNA is important per se or is merely a consequence of the way a particular protein binds to DNA. Here we report direct evidence from the bacteriophage lambda integration system that a bend introduced by a protein is intrinsically important. We find that a binding site for a specific recombination protein known to bend DNA can be successfully replaced by two other modules that also bend DNA; related modules that fail to bend DNA are ineffective.     

Polypeptide ligation occurs during post-translational modification of concanavalin A

Lectins are proteins with multivalent carbohydrate-binding sites, which confer the ability to agglutinate. The seeds of legumes are particularly rich in lectins, for example, concanavalin A (Con A) comprises up to 15% of the protein in the cotyledons of jack bean (Canavalia ensiformis) seeds. The amino acid sequences of Con A and several other legume lectins have been partially or fully determined, and comparison of these sequences from different species reveals a circular homology (Fig. 1A); rearrangements within the genome have been suggested to explain this. We report here that the circular homology displayed by Con A is due to a post-translational transposition and ligation within the initial polypeptide. This type of modification has not been reported previously for eukaryotes, although it has been suggested to occur in bacteriophage lambda.     

Communication between segments of DNA during site-specific recombination

Some site-specific recombination systems require the interacting DNA sequences to have a specific relative orientation. This means that DNA segments can sense each other's direction even though they may be separated by many thousands of base pairs. Here, we review the surprising results of recent experiments that lead to a new model which accounts for site orientation specificity and relates it to other recombination systems where relative orientation is not critical.     

A structural basis for allosteric control of DNA recombination by lambda integrase

Site-specific DNA recombination is important for basic cellular functions including viral integration, control of gene expression, production of genetic diversity and segregation of newly replicated chromosomes, and is used by bacteriophage lambda to integrate or excise its genome into and out of the host chromosome. lambda recombination is carried out by the bacteriophage-encoded integrase protein (lambda-int) together with accessory DNA sites and associated bending proteins that allow regulation in response to cell physiology. Here we report the crystal structures of lambda-int in higher-order complexes with substrates and regulatory DNAs representing different intermediates along the reaction pathway. The structures show how the simultaneous binding of two separate domains of lambda-int to DNA facilitates synapsis and can specify the order of DNA strand cleavage and exchange. An intertwined layer of amino-terminal domains bound to accessory (arm) DNAs shapes the recombination complex in a way that suggests how arm binding shifts the reaction equilibrium in favour of recombinant products.     

A protein binding to the J kappa recombination sequence of immunoglobulin genes contains a sequence related to the integrase motif

Site-specific recombination requires conserved DNA sequences specific to each system, and system-specific proteins that recognize specific DNA sequences. The site-specific recombinases seem to fall into at least two families, based on their protein structure and chemistry of strand breakage. One of these is the resolvase-invertase family, members of which seem to form a serine-phosphate linkage with DNA. Members of the other family, called the integrase family, contain a conserved tyrosine residue that forms a covalent linkage with the 3'-phosphate of DNA at the site of recombination. Structural comparison of integrases shows that these proteins share a highly conserved 40-residue motif. V-(D)-J recombination of the immunoglobulin gene requires conserved recombination signal sequences (RS) of a heptamer CACTGTG and a T-rich nonamer GGTTTTTGT, which are separated by a spacer sequence of either 12 or 23 bases We have recently purified, almost to homogeneity, a protein that specifically binds to the immunoglobulin J kappa RS containing the 23-base-pair spacer sequence. By synthesizing probes on the basis of partial amino-acid sequences of the purified protein, we have now isolated and characterized the complementary DNA of this protein. The amino-acid sequence deduced from the cDNA sequence reveals that the J kappa RS-binding protein has a sequence similar to the 40-residue motif of integrases of phages, bacteria and yeast, indicating that this protein could be involved in V-(D)-J recombination as a recombinase.     

The importance of repairing stalled replication forks

The bacterial SOS response to unusual levels of DNA damage has been recognized and studied for several decades. Pathways for re-establishing inactivated replication forks under normal growth conditions have received far less attention. In bacteria growing aerobically in the absence of SOS-inducing conditions, many replication forks encounter DNA damage, leading to inactivation. The pathways for fork reactivation involve the homologous recombination systems, are nonmutagenic, and integrate almost every aspect of DNA metabolism. On a frequency-of-use basis, these pathways represent the main function of bacterial DNA recombination systems, as well as the main function of a number of other enzymatic systems that are associated with replication and site-specific recombination.     

Structural basis for broad DNA-specificity in integron recombination

Lateral DNA transfer--the movement of genetic traits between bacteria--has a profound impact on genomic evolution and speciation. The efficiency with which bacteria incorporate genetic information reflects their capacity to adapt to changing environmental conditions. Integron integrases are proteins that mediate site-specific DNA recombination between a proximal primary site (attI) and a secondary target site (attC) found within mobile gene cassettes encoding resistance or virulence factors. The lack of sequence conservation among attC sites has led to the hypothesis that a sequence-independent structural recognition determinant must exist within attC. Here we report the crystal structure of an integron integrase bound to an attC substrate. The structure shows that DNA target site recognition and high-order synaptic assembly are not dependent on canonical DNA but on the position of two flipped-out bases that interact in cis and in trans with the integrase. These extrahelical bases, one of which is required for recombination in vivo, originate from folding of the bottom strand of attC owing to its imperfect internal dyad symmetry. The mechanism reported here supports a new paradigm for how sequence-degenerate single-stranded genetic material is recognized and exchanged between bacteria.     

Banach空间中一类受控的脉冲系统

研究Banach空间中一类控制元为可积函数的脉冲受控系统。研究了这类模型温和解的存在性、唯一性和正规性及其对初值和控制的连续依赖性。最后，举例说明了所得出的抽象结论的应用。     

The lambda phage att site: functional limits and interaction with Int protein

Site specific integrative recombination of bacteriophage lambda involves unequal partners. The minimal phage att site is composed of approximately 240-base pairs and four distinct binding sites for Int protein, at least three of which are crucial for function. This 'donor site' recombines efficiently with a smaller 'recipient site' that lacks the extensive interactions with Int protein.     

Different recombination site specificity of two developmentally regulated genome rearrangements

In the absence of a combined nitrogen source, such as ammonia, approximately every tenth vegetative cell along filaments of the cyanobacterium Anabaena develops into a heterocyst, a terminally differentiated cell that is morphologically and biochemically specialized for nitrogen fixation. At least two specific DNA rearrangements involving the nitrogen-fixation (nif) genes occur during heterocyst differentiation, one within the nifD gene and the other near the nifS gene. The two rearrangements have several properties in common. Both occur quantitatively in all heterocyst genomes, both occur at approximately the same developmental time, late in the process of heterocyst differentiation, and both result from site-specific recombination between short repeated DNA sequences. We report here the nucleotide sequences found at the site of recombination near the nifS gene. These sequences differ from those found previously for the nifD rearrangement, suggesting that the two rearrangements are catalysed by different enzymes and may be regulated independently. We also show that the nifS gene is transcribed only from rearranged genomes.     

Co-transformation to tobacco of Cre/lox site-specific recombination system and its precise recombination

For the temporally and spatially regulated expression of the barnase gene in plant,two kinds of plasmids with cre gene and its directly repeat recognition sites lox from bacteriophage P1 were constructed and co-transformed into tobacco by agrobacterium mediated procedure.The transgenic plants were conformed by PCR analysis.The blocking fragment between the two lox directly repeat sites was excised by Cre protein in the transgenic plant genome.Cloning and sequencing the DNA fragment from the co-transformed plant DNA showed that the precise DNA excision occurred in transgenic tobacco genome directed by Cre/lox site-specific recombination.