Activation of Chi recombinational hotspots by RecBCD-like enzymes from enteric bacteria

Chi sites, 5'G-C-T-G-G-T-G-G-3', enhance homologous recombination in Escherichia coli and are activated by the RecBCD enzyme. To test the ability of Chi to be activated by analogous enzymes from other bacteria, we cloned recBCD-like genes from diverse bacteria into an E. coli recBCD deletion mutant. Clones from seven species of enteric bacteria conferred to this deletion mutant recombination proficiency, Chi hotspot activity in lambda Red- Gam- vegetative crosses, and RecBCD enzyme activities, including Chi-dependent DNA strand cleavage. Three clones from Pseudomonas aeruginosa and Ps. putida conferred recombination proficiency and ATP-dependent nuclease activity, but neither Chi hotspot activity nor Chi-dependent DNA cleavage. These results imply that Chi has been conserved as a recombination-promoting signal for RecBCD-like enzymes in enteric bacteria but not in more distantly related bacteria such as Pseudomonas spp. We discuss the possibility that other, presently unknown, nucleotide sequences serve the same function as Chi in Pseudomonas spp.     

Unexpected DNA context-dependence identifies a new determinant of Chi recombination hotspots

Homologous recombination occurs especially frequently near special chromosomal sites called hotspots. In Escherichia coli, Chi hotspots control RecBCD enzyme, a protein machine essential for the major pathway of DNA break-repair and recombination. RecBCD generates recombinogenic single-stranded DNA ends by unwinding DNA and cutting it a few nucleotides to the 3′ side of 5′ GCTGGTGG 3′, the sequence historically equated with Chi. To test if sequence context affects Chi activity, we deep-sequenced the products of a DNA library containing 10 random base-pairs on each side of the Chi sequence and cut by purified RecBCD. We found strongly enhanced cutting at Chi with certain preferred sequences, such as A or G at nucleotides 4–7, on the 3′ flank of the Chi octamer. These sequences also strongly increased Chi hotspot activity in E. coli cells. Our combined enzymatic and genetic results redefine the Chi hotspot sequence, implicate the nuclease domain in Chi recognition, indicate that nicking of one strand at Chi is RecBCD''s biologically important reaction in living cells, and enable more precise analysis of Chi''s role in recombination and genome evolution.     

A test for nucleotide sequence homology

Two macromolecular sequences which have evolved from a common ancestor sequence will tend to include a large number of elements unaffected by replacement mutations in both sequences, as long as the evolutionary rate is not too high or the divergence time is not too great. The positions of corresponding elements may have changed in either daughter sequence due to deletion/insertion mutations involving other sequence elements, but their order can be expected to be the same in both sequences. These sets of correspondences, called matches, may be computed by a recursive algorithm which incorporates constraints on the number of deletion/insertion mutations hypothesized to have occurred. A test is developed which computes the significance of each deletion/insertion hypothesized, based on Monte-Carlo sampling of random sequences with the same base composition as the experimental sequences being tested. Applying the test to 5 S RNAs confirms the relation of Escherichia coli and KB carcinoma 5 S RNAs and establishes the previously undetected homology between Pseudomonas fluorescens and KB 5 S RNAs.     

SequenceLDhot: detecting recombination hotspots

MOTIVATION: There is much local variation in recombination rates across the human genome--with the majority of recombination occurring in recombination hotspots--short regions of around approximately 2 kb in length that have much higher recombination rates than neighbouring regions. Knowledge of this local variation is important, e.g. in the design and analysis of association studies for disease genes. Population genetic data, such as that generated by the HapMap project, can be used to infer the location of these hotspots. We present a new, efficient and powerful method for detecting recombination hotspots from population data. RESULTS: We compare our method with four current methods for detecting hotspots. It is orders of magnitude quicker, and has greater power, than two related approaches. It appears to be more powerful than HotspotFisher, though less accurate at inferring the precise positions of the hotspot. It was also more powerful than LDhot in some situations: particularly for weaker hotspots (10-40 times the background rate) when SNP density is lower (< 1/kb). AVAILABILITY: Program, data sets, and full details of results are available at: http://www.maths.lancs.ac.uk/~fearnhea/Hotspot.     

SEQ: a nucleotide sequence analysis and recombination system

SEQ is an interactive, self-documenting computer program that contains procedures for the analysis of nucleotide sequences and the manipulation of such sequences to allow the simulation and prediction of the results of recombinant DNA experiments.     

Interplay between modifications of chromatin and meiotic recombination hotspots

Meiotic recombination lies at the heart of sexual reproduction. It is essential for producing viable gametes with a normal haploid genomic content and its dysfunctions can be at the source of aneuploidies, such as the Down syndrome, or many genetic disorders. Meiotic recombination also generates genetic diversity that is transmitted to progeny by shuffling maternal and paternal alleles along chromosomes. Recombination takes place at non-random chromosomal sites called 'hotspots'. Recent evidence has shown that their location is influenced by properties of chromatin. In addition, many studies in somatic cells have highlighted the need for changes in chromatin dynamics to allow the process of recombination. In this review, we discuss how changes in the chromatin landscape may influence the recombination map, and reciprocally, how recombination events may lead to epigenetic modifications at sites of recombination, which could be transmitted to progeny.     

Extent of sequence homology required for bacteriophage lambda site-specific recombination

Bacteriophage lambda integration and exicision occur by reciprocal recombination within a 15-base homologous core region present in the recombining attachment (att) sites. Strand exchange within the core occurs at precise nucleotide positions, which define an overlap region in which the products of recombination contain DNA strands derived from different parents. In order to define the role of sequence homology during recombination we have constructed point mutations within the core and assayed their effects in vivo and in vitro on site-specific recombination. Two of the mutations are located at position ?3 of the core, which is one base-pair outside of the overlap region where strand exchange occurs. These mutations do not affect integrative or excisive recombination, thereby suggesting that homology outside the overlap region is not required for recombination. Two other mutations are located at position ?2 of the core, which is one base-pair within the overlap region. These mutations show severely depressed integrative and excisive recombination activities in vitro and in vivo when recombined against wild-type att sites. However, the ?2 mutations show normal recombination activity when recombined against att sites containing the homologous mutation, thereby suggesting that homology-dependent DNA interactions are required within the overlap region for effective recombination. In vitro recombination between homoduplex attP sites and heteroduplex attB sites demonstrated that the DNA interactions require only one strand of the attB overlap region to be homologous to attP in order to promote recombination.     

Detecting sequence polymorphisms associated with meiotic recombination hotspots in the human genome

Background  

Meiotic recombination events tend to cluster into narrow spans of a few kilobases long, called recombination hotspots. Such hotspots are not conserved between human and chimpanzee and vary between different human ethnic groups. At the same time, recombination hotspots are heritable. Previous studies showed instances where differences in recombination rate could be associated with sequence polymorphisms.     

Chi hotspots trigger a conformational change in the helicase-like domain of AddAB to activate homologous recombination

In bacteria, the repair of double-stranded DNA breaks is modulated by Chi sequences. These are recognised by helicase-nuclease complexes that process DNA ends for homologous recombination. Chi activates recombination by changing the biochemical properties of the helicase-nuclease, transforming it from a destructive exonuclease into a recombination-promoting repair enzyme. This transition is thought to be controlled by the Chi-dependent opening of a molecular latch, which enables part of the DNA substrate to evade degradation beyond Chi. Here, we show that disruption of the latch improves Chi recognition efficiency and stabilizes the interaction of AddAB with Chi, even in mutants that are impaired for Chi binding. Chi recognition elicits a structural change in AddAB that maps to a region of AddB which resembles a helicase domain, and which harbours both the Chi recognition locus and the latch. Mutation of the latch potentiates the change and moderately reduces the duration of a translocation pause at Chi. However, this mutant displays properties of Chi-modified AddAB even in the complete absence of bona fide hotspot sequences. The results are used to develop a model for AddAB regulation in which allosteric communication between Chi binding and latch opening ensures quality control during recombination hotspot recognition.     

Method for determination of nucleotide sequence homology between viral genomes by DNA reassociation kinetics.

A model and appropriate equations were derived for the quantitative estimation of nucleotide sequence homology between two partially related viral genomes by measurement of the initial rate of reassociation of one labeled DNA in the presence of a second unlabeled DNA. The validity and usefulness of this procedure were demonstrated by the analysis of the reassociation kinetics of labeled adenovirus 7 DNA in the presence of unlabeled adenovirus 2 DNA. Based on DNA reassociation, the extent of homology between adenovirus 2 and 7 genomes was found to be 10 to 12%. The duplex formed between adenovirus 2 and 7 DNA had the appropriate thermal stability for a well-matched DNA-DNA hybrid.     

iRSpot-SF: Prediction of recombination hotspots by incorporating sequence based features into Chou's Pseudo components

Recombination hotspots in a genome are unevenly distributed. Hotspots are regions in a genome that show higher rates of meiotic recombinations. Computational methods for recombination hotspot prediction often use sophisticated features that are derived from physico-chemical or structure based properties of nucleotides. In this paper, we propose iRSpot-SF that uses sequence based features which are computationally cheap to generate. Four feature groups are used in our method: k-mer composition, gapped k-mer composition, TF-IDF of k-mers and reverse complement k-mer composition. We have used recursive feature elimination to select 17 top features for hotspot prediction. Our analysis shows the superiority of gapped k-mer composition and reverse complement k-mer composition features over others. We have used SVM with RBF kernel as a classification algorithm. We have tested our algorithm on standard benchmark datasets. Compared to other methods iRSpot-SF is able to produce significantly better results in terms of accuracy, Mathew's Correlation Coefficient and sensitivity which are 84.58%, 0.6941 and 84.57%. We have made our method readily available to use as a python based tool and made the datasets and source codes available at: https://github.com/abdlmaruf/iRSpot-SF. An web application is developed based on iRSpot-SF and freely available to use at: http://irspot.pythonanywhere.com/server.html.     

Rec-mediated recombinational hot spot activity in bacteriophage lambda. III. Chi mutations are site-mutations stimulating rec-mediated recombination.

Lambda phage defective for Red and gam function make small plaques on rec⁺ bacteria. Mutants (called Chi) of λ arise which suppress the small-plaque phenotype. Chi mutations arise at at least four well-separated sites; one site is between gene L and att, one is between att and gam, one is in the cII gene, and one is near gene S. A phage strain carrying a Chi mutation at a given site has an extraordinarily high rate of Rec-mediated crossing-over near that site.     

Inference of selection and recombination from nucleotide sequence data*

Two techniques for obtaining information about population structure from nucleotide sequences in DNA are summarized. The first focuses on the selection or neutrality of enzyme polymorphisms, the second on the detection of recombination. Neither method requires phylogeny estimation.     

Complete nucleotide sequence of a thermophilic alpha-amylase gene: homology between prokaryotic and eukaryotic alpha-amylases at the active sites

The nucleotide sequence of a thermophilic, liquefying alpha-amylase gene cloned from B. stearothermophilus was determined. The NH2-terminal amino acid sequence analysis of the B. stearothermophilus alpha-amylase confirmed that the reading frame of the gene consisted of 1,644 base pairs (548 amino acids). The B. stearothermophilus alpha-amylase had a signal sequence of 34 amino acids, which was cleaved at exactly the same site in E. coli. The mature enzyme contained two cysteine residues, which might play an important role in maintenance of a stable protein conformation. Comparison of the amino acid sequence inferred from the B. stearothermophilus alpha-amylase gene with those inferred from other bacterial liquefying alpha-amylase genes and with the amino acid sequences of eukaryotic alpha-amylases showed three homologous sequences in the enzymatically functional regions.     

Inference about recombination from haplotype data: lower bounds and recombination hotspots.

Recombination is an important evolutionary mechanism responsible for creating the patterns of haplotype variation observable in human populations. Recently, there has been extensive research on understanding the fine-scale variation in recombination across the human genome using DNA polymorphism data. Historical recombination events leave signature patterns in haplotype data. A nonparametric approach for estimating the number of historical recombination events is to compute the minimum number of recombination events in the history of a set of haplotypes. In this paper, we provide new and improved methods for computing lower bounds on the minimum number of recombination events. These methods are shown to detect a higher number of recombination events for a haplotype dataset from a region in the lipoprotein lipase gene than previous lower bounds. We apply our methods to two datasets for which recombination hotspots have been experimentally determined and demonstrate a high density of detectable recombination events in the regions annotated as recombination hotspots. The programs implementing the methods in this paper are available at www.cs.ucsd.edu/users/vibansal/RecBounds/.