Some genetic properties of intrachromosomal recombination

Summary Intrachromosomal recombination was estimated by the occurrence of unequal crossing over without marker gene exchange in three different, independent tandem duplicaltions in Drosophila melanogaster. Each tandem duplication gave rise to intrachromosomal recombinants. The frequency of intrachromosomal recombination is independent of the genetic length of the tandem duplication. Further, intrachromosomal recombinants were recovered as frequently in ring as in rod X chromosomes implying that the recombination event is not equatable to a single interchromosomal crossover.Communicated by Ch. Auerbach     

The Cloning of the Bar Region and the B Breakpoint in Drosophila Melanogaster: Evidence for a Transposon-Induced Rearrangement

We have cloned the B breakpoint in Drosophila melanogaster using DNA from a P-M-induced revertant of B, which has a P element inserted at the B breakpoint. The analysis of the B DNA reveals that there is a transposable element, B104, right at the breakpoint. This suggests that this element may have been involved in the generation of the B breakpoint and the associated tandem duplication. One possible mechanism to generate the B duplication is a recombination event between two B104 elements, one at 16A1 and the other at 16A7. DNA sequencing data of the junctions of the B104 element support this model. Four partial revertants of B are the result of insertions of transposable elements very close to the B breakpoint. This supports the hypothesis that the breakpoint is the cause of the B mutation. The clones from B were used to isolate wild-type clones from 16A1, the location of the Bar gene. Four rearrangement breakpoints associated with various Bar mutations map within a 37-kb region, suggesting that the Bar gene is very large.     

Cytogenetics of an intrachromosomal transposition in Neurospora

Knowledge of intrachromosomal transpositions has until now been primarily cytological and has been limited to Drosophila and to humans, in both of which segmental shifts can be recognized by altered banding patterns. There has been little genetic information. In this study, we describe the genetic and cytogenetic properties of a transposition in Neurospora crassa. In Tp(IRIL)T54M94, a 20 map unit segment of linkage group I has been excised from its normal position and inserted near the centromere in the opposite arm, in inverted order. In crosses heterozygous for the transposition, about one-fifth of surviving progeny are duplications carrying the transposed segment in both positions. These result from crossing over in the interstitial region. There is no corresponding class of progeny duplicated for the interstitial segment. The duplication strains are barren in test crosses. A complementary deficiency class is represented by unpigmented, inviable ascospores. Extent of the duplication was determined by duplication-coverage tests. Orientation of the transposed segment was determined using Tp x Tp crosses heterozygous for markers inside and outside the transposed segment, and position of the insertion relative to the centromere was established using quasi-ordered half-tetrads from crosses x Spore killer. Quelling was observed in the primary transformants that were used to introduce a critical marker into the transposed segment by repeat-induced point mutation (RIP).     

A Duplication Including the Y Allele of Lcp2 and the Trim Retrotransposon at the Lcp Locus on the Degenerating Neo-Y Chromosome of Drosophila Miranda: Molecular Structure and Mechanisms by Which It May Have Arisen

Evolutionary changes during the process of sex chromosome differentiation in Drosophila miranda are associated with massive DNA rearrangements. Comparing the DNA structure of the larval cuticle protein (Lcp) region from the X2 and neo-Y chromosome pair, we observed insertions, deletions and a large duplication at the neo-Y chromosomal locus. The duplication encompasses a complete copy of the neo-Y allele of Lcp2, and the ISY3 and the ISY4 insertion sequences. The latter was identified as a retrotransposon, termed TRIM. ISY3 shows DNA sequence similarity to P element homologs identified in the Drosophila obscura species group. We were interested in mechanistic aspects generating the duplication. We cannot exclude unequivocally that unequal sister-chromatid exchange could give rise to the observed duplication; however, recombination is a rare event in Drosophila males. Location and sequence of the retrotransposon TRIM served as molecular markers allowing us to reconstruct two intrachromosomal transposition events that could lead to the observed duplication.     

Architecture of the hin synaptic complex during recombination: the recombinase subunits translocate with the DNA strands

Most site-specific recombinases can be grouped into two mechanistically distinct families. Whereas tyrosine recombinases exchange DNA strands through a Holliday intermediate, serine recombinases such as Hin generate double-strand breaks in each recombining partner. Here, site-directed protein crosslinking is used to elucidate the configuration of protein subunits and DNA within the Hin synaptic complex and to follow the movement of protein subunits during DNA strand exchange. Our results show that the protein interface mediating synapsis is localized to a region within the catalytic domains, thereby positioning the DNA strands on the outside of the Hin tetrameric complex. Unexpected crosslinks between residues within the dimerization helices provide evidence for a conformational change that accompanies DNA cleavage. We demonstrate that the Hin subunits, which are linked to the cleaved DNA ends by serine-phosphodiester bonds, translocate between synapsed dimers to exchange the DNA strands.     

Mechanisms of tandem duplication in the Duchenne muscular dystrophy gene include both homologous and nonhomologous intrachromosomal recombination.

Three tandem duplications were previously identified in patients with Duchenne muscular dystrophy and were shown in each case to have a subset of dystrophin gene exons duplicated. The origin of these duplications was traced to the single X chromosome of the maternal grandfathers, suggesting that an intrachromosomal event (unequal sister chromatid exchange) was involved in the formation of these duplications. In the present study, a DNA segment containing the duplication junction and the normal DNA that corresponds to both ends of the duplicated region have been cloned. Subsequent mapping studies confirmed the tandem arrangement (head to tail) of these duplications and revealed their sizes to be 130 kb, approximately 300 kb, and 35-80 kb, respectively. Sequence analysis of the duplication junctions showed that one duplication was due to homologous recombination between two repetitive elements (Alu sequences) and the other two were due to recombination between unrelated nonhomologous sequences. In the latter cases, the preferred cleavage sites of the eukaryotic type I and II DNA topoisomerases were found at the junctions of these duplications, suggesting a possible role of these enzymes in the chromatid exchange events. This study provides the first insight into the molecular basis of gene duplications formed through unequal sister chromatid exchange in humans.     

Unequal crossing over is the principal pathway of homologous recombination in tandem duplications of Escherichia coli

Homologous recombination between direct DNA repeats in tandem duplications usually leads to their dissociation. An even number of crossovers between two copies of a duplication should lead to the formation of diploid segregants, i.e., to the preservation of the duplication. However, in studies of the genotype of diploid segregants in heterozygous tandem duplications of Escherichia coli, it was shown that they arise by unequal exchanges between sister chromosomes rather than by intrachromosomal exchanges. Generally, these exchanges lead to the establishment of the homozygous state of (heterozygous) duplications. Since the available data suggest that the exchange between sister chromosomes may be coupled with DNA replication, it is supposed that unequal exchanges between direct DNA repeats occur in the process of DNA replication.     

The temporal distribution of gene duplication events in a set of highly conserved human gene families

Using a data set of protein translations associated with map positions in the human genome, we identified 1520 mapped highly conserved gene families. By comparing sharing of families between genomic windows, we identified 92 potentially duplicated blocks in the human genome containing 422 duplicated members of these families. Using branching order in the phylogenetic trees, we timed gene duplication events in these families relative to the primate-rodent divergence, the amniote-amphibian divergence, and the deuterostome-protostome divergence. The results showed similar patterns of gene duplication times within duplicated blocks and outside duplicated blocks. Both within and outside duplicated blocks, numerous duplications were timed prior to the deuterostome-protostome divergence, whereas others occurred after the amniote-amphibian divergence. Thus, neither gene duplication in general nor duplication of genomic blocks could be attributed entirely to polyploidization early in vertebrate history. The strongest signal in the data was a tendency for intrachromosomal duplications to be more recent than interchromosomal duplications, consistent with a model whereby tandem duplication-whether of single genes or of genomic blocks-may be followed by eventual separation of duplicates due to chromosomal rearrangements. The rate of separation of tandemly duplicated gene pairs onto separated chromosomes in the human lineage was estimated at 1.7 x 10(-9) per gene-pair per year.     

Gene duplications in the structural evolution of chymotrypsin.

Chymotrypsin and other members of the serine protease enzyme family have a structure built from two similar domains, each of which is a hydrogen-bonded barrel, containing six antiparallel strands of beta-sheet bonded in the order ABCFED-A …. The folding patterns of the domains have been re-examined by several newly improved shape comparison methods to see whether the barrels could have evolved by gene duplication, as proposed by Matthews and Blow (Birktoft &; Blow, 1972). The domains have a similar hydrogen-bond pattern, the same shear number (defined in this paper) for the twist of the barrel, and the cores of their β-sheets can be superimposed so that 46 topologically equivalent α-carbons fit within a root-mean-square distance of 2.43 Å and a larger set of 57 α-carbons fit within 3.4 Å. These results are highly significant when judged against shape comparisons of many other proteins with themselves, and give strong evidence for gene duplication. The duplication does not include any SS bridges.Both domains have a surprisingly symmetrical structure of two halves ABC, DEF paired round a dyad axis, and the half-domains are each made of two loops twisted in an L-shape, since the second strand (B or E) is bent into two halves B₁, B₂ or E₁, E₂. The cores of the four half-domains, each of 23 α-carbons, superimpose in pairs with root-mean-square distances ranging from 1.79 to 2.45 Å. In the entire molecule the half-domains are related by a screw dyad which converts domain I strands (ABC) (DEF) into domain II strands (DEF) (ABC) superimposing the six strands with a root-mean-square distance of 2.35 Å. These observations suggest that the Chymotrypsin barrel originally evolved from a closely-linked dimer of two intertwined half-domains which became united into one. domain by gene duplication. The enzyme evolved from a second dimer of two full domains and a second duplication. The bacterial protease B from Streptomyces griseus shows the same structural repeats and is consistent with the gene duplication hypothesis.Improved methods for shape comparison of proteins have been developed which are very fast and reliable.     

Segregation of Recombinant Chromatids following Mitotic Crossing over in Yeast

It has long been assumed that chromatid segregation following mitotic crossing over in yeast is random, with the recombinant chromatids segregating to opposite poles of the cell (x-segregation) or to the same pole of the cell (z-segregation) with equal frequency. X-segregation events can be readily identified because heterozygous markers distal to the point of the exchange are reduced to homozygosity. Z-segregation events yield daughter cells which are identical phenotypically to nonrecombinant cells and thus can only be identified by the altered linkage relationships of genetic markers on opposite sides of the exchange. We have systematically examined the segregation patterns of chromatids with a spontaneous mitotic exchange in the CEN5-CAN1 interval on chromosome V. We find that the number of x-segregation events is equal to the number of z-segregations, thus demonstrating that chromatid segregation is indeed random. In addition, we have found that at least 5% of the cells selected for a recombination event on chromosome V are trisomic for this chromosome, indicating a strong association between mitotic recombination and chromosome nondisjunction.     

Isolation and molecular analysis of inv dup(15) and construction of a physical map of a common breakpoint in order to elucidate their mechanism of formation

An inverted duplication of chromosome 15 [inv dup(15)] is the most common supernumerary marker chromosome, comprising approximately 50% of all chromosomes in this class. Structurally, the inv dup(15) is a mirror image with the central axis defining a distal break within either the heterochromatic alpha-satellite array or along the euchromatin in the long (q) arm of the chromosome. There are several types of inv dup(15), classified by the amount of euchromatic material present. Generally, they are bisatellited, pseudodicentric and have a breakpoint in 15q11-q14. A suggested mechanism of formation of inv dup(15) involves illegitimate recombination between homologous chromosomes followed by nondisjunction and centromere inactivation. The proximal portion of chromosome 15 contains several low-copy repeat sequence families and it has been hypothesized that errors in pairing among these repeats may result in structural rearrangements of this chromosome including the inv dup(15). To test this hypothesis and to determine the mechanism of formation, the inv dup(15) from four cases was isolated in somatic cell hybrids and polymerase chain reaction microsatellite markers were used to determine the origin of exchange. Two appeared to result from interchromosomal and two from intrachromosomal exchange, one of which occurred post-recombination. In addition, a detailed physical map of the breakpoint region in the largest inv dup(15) was constructed placing eight new sequence-tagged sites and ten new bacterial artificial chromosome markers in the region.     

A small tandem duplication is responsible for the unstable white-ivory mutation in Drosophila

The white-ivory (wi) mutation, an unstable allele of the white locus in Drosophila, reverts to wild-type at frequencies of 5 X 10(-5) in homozygous females, and 5 X 10(-6) in males and deletion heterozygous females. We show by molecular cloning and Southern blot analysis of DNA from wi flies that a 2.9 kilobase tandem duplication within the white locus is responsible for the mutation. Phenotypic reversion appears, in most cases, to be due to an exact excision of the extra copy of the sequence. Two derivative alleles of wi, one phenotypically wild-type, the other a partial revertant, carry insertions of moderately repetitive DNA from outside the locus, in addition to suffering deletions of some white locus DNA. Earlier genetic data preclude unequal crossing-over between homologs as an explanation for the precise reversions. Rather, an intrachromosomal meiotic event seems to be responsible. Our results suggest that intrachromosomal recombination may be responsible in other systems for a larger number of rearrangements than has been suspected, and that interallelic recombination frequencies in Drosophila do not always correlate in a simple way with DNA length or extent of homology.     

Meiotic exchange within and between chromosomes requires a common Rec function in Saccharomyces cerevisiae.

We used haploid yeast cells that express both the MATa and MAT alpha mating-type alleles and contain the spo13-1 mutation to characterize meiotic recombination within single, unpaired chromosomes in Rec+ and Rec- Saccharomyces cerevisiae. In Rec+ haploids, as in diploids, intrachromosomal recombination in the ribosomal DNA was detected in 2 to 6% of meiotic divisions, and most events were unequal reciprocal sister chromatid exchange (SCE). By contrast, intrachromosomal recombination between duplicated copies of the his4 locus occurred in approximately 30% of haploid meiotic divisions, a frequency much higher than that reported in diploids; only about one-half of the events were unequal reciprocal SCE. The spo11-1 mutation, which virtually eliminates meiotic exchange between homologs in diploid meiosis, reduced the frequency of intrachromosomal recombination in both the ribosomal DNA and the his4 duplication during meiosis by 10- to greater than 50-fold. This Rec- mutation affected all forms of recombination within chromosomes: unequal reciprocal SCE, reciprocal intrachromatid exchange, and gene conversion. Intrachromosomal recombination in spo11-1 haploids was restored by transformation with a plasmid containing the wild-type SPO11 gene. Mitotic intrachromosomal recombination frequencies were unaffected by spo11-1. This is the first demonstration of a gene product required for recombination between homologs as well as recombination within chromosomes during meiosis.     

Gene duplication events producing muscle (M) and brain (B) isoforms of cytoplasmic creatine kinase: cDNA and deduced amino acid sequences from two lower chordates.

Creatine kinase (CK) is coded for by at least four loci in higher vertebrates--two cytoplasmic isoforms, muscle (M) and brain (B), and two mitochondrial isoforms, sarcomeric and ubiquitous. M is expressed primarily in skeletal muscle, while B is expressed in a variety of cells, including cardiac and smooth muscle fibers, neurons, transport epithelia, and photoreceptors. M and B subunits form very stable homodimers (MM [M-CK], BB [B-CK]) and heterodimers (MB). M-CK is capable of binding to the M line of the myofibril, thereby creating an energy transfer microcompartment; BB and MB CKs are not. M- and B-like CKs are present in all vertebrates yet examined, including fish. Cytoplasmic, dimeric CKs are widely distributed in the invertebrates. The only available amino acid sequence for an invertebrate dimeric CK, that of the protostome polychaete Chaetopterus variopedatus, is just as similar to the vertebrate M isoform as to the B isoform. Echinoderms lack dimeric, cytoplasmic CKs, which appear to be replaced by a dimeric arginine kinase which evolved secondarily from CK. Thus, it is likely that the gene duplication event producing the M and B isoforms occurred after the divergence of the chordates from echinoderms. To narrow down the timing of this duplication event, we obtained the cDNA and deduced amino acid sequences of dimeric CKs from the tunicate Ciona intestinalis (subphylum Urochordata) and the lancelet Branchiostoma floridae (subphylum Cephalochordata). Our results show that these CKs are strikingly similar to both invertebrate and vertebrate CKs. However, phylogenetic analyses by neighbor-joining and parsimony show that these two enzymes appeared to have diverged before the point of divergence of the M and B isoforms. Thus, the gene duplication event for formation of the muscle and brain isoforms of CK most likely occurred during the radiation of the fish, a time noted for gene duplication events at a variety of other loci.     

Unequal Crossing Over Is the Principal Pathway of Homologous Recombination in Tandem Duplications of <Emphasis Type="Italic">Escherichia coli</Emphasis>

Homologous recombination between direct DNA repeats in tandem duplications usually leads to their dissociation. An even number of crossovers between two copies of a duplication should lead to the formation of diploid segregants, i.e., to the preservation of the duplication. However, in studies of the genotype of diploid segregants in heterozygous tandem duplications of Escherichia coli, it was shown that they arise by unequal exchanges between sister chromosomes rather than by intrachromosomal exchanges. Generally, these exchanges lead to the establishment of the homozygous state of (heterozygous) duplications. Since the available data suggest that the exchange between sister chromosomes may be coupled with DNA replication, it is supposed that unequal exchanges between direct DNA repeats occur in the process of DNA replication.__________Translated from Genetika, Vol. 41, No. 8, 2005, pp. 1038–1044.Original Russian Text Copyright © 2005 by Prokop’ev, Sukhodolets.     

The effect of estrogen receptor genotype on litter size and placental traits at term in F2 crossbred gilts

The effect of estrogen receptor (ESR) genotype (two alleles, A and B) on litter size of 275 Large White x Meishan F2 crossbred gilts (73 AA, 126 AB and 76 BB gilts) was tested. In addition, for 63 of these gilts (18 AA, 24 AB, and 21 BB) the effect of ESR genotype on average placental traits at term was tested, since individual placental information was available for 88% of the 628 liveborn piglets. Without affecting average birth weight of the piglets, ESR genotype significantly affected litter size, i.e. AB gilts had larger litters than BB gilts (P < 0.05). Total number born was 11.38+/-0.38, 11.88+/-0.28, and 10.68+/-0.35, while number born alive was 10.45+/-0.39, 11.07+/-0.29, and 9.85+/-0.36 for AA, AB and BB gilts, respectively. Since the B allele in previous research was associated with largest litters, the hypothesis that ESR is a marker rather than the major gene itself is discussed. Average placental length, surface area, and weight including and excluding amnion were not affected by ESR genotype. However, placentae of AB gilts had a significantly lower number of areolae per placenta than BB gilts and had a lower number of areolae/cm2 placenta than AA and BB gilts. Number of areolae was 8945+/-663, 7240+/-619, and 9694+/-633, for AA, AB and BB gilts, respectively. Although the reason for the low number of areolae on placentae in AB gilts is not yet known, the results suggest that the ESR linked major gene for litter size might be involved in the development and activity of endometrial glands.     

The Hin recombinase assembles a tetrameric protein swivel that exchanges DNA strands

Most site-specific recombinases can be grouped into two structurally and mechanistically different classes. Whereas recombination by tyrosine recombinases proceeds with little movements by the proteins, serine recombinases exchange DNA strands by a mechanism requiring large quaternary rearrangements. Here we use site-directed crosslinking to investigate the conformational changes that accompany the formation of the synaptic complex and the exchange of DNA strands by the Hin serine recombinase. Efficient crosslinking between residues corresponding to the ‘D-helix’ region provides the first experimental evidence for interactions between synapsed subunits within this region and distinguishes between different tetrameric conformers that have been observed in crystal structures of related serine recombinases. Crosslinking profiles between cysteines introduced over the 35 residue E-helix region that constitutes most of the proposed rotating interface both support the long helical structure of the region and provide strong experimental support for a subunit rotation mechanism that mediates DNA exchange.     

Preferential synapsis of loxP sites drives ordered strand exchange in Cre-loxP site-specific recombination

The bacteriophage P1 Cre recombinase catalyzes site-specific recombination between 34-base-pair loxP sequences in a variety of topological contexts. This reaction is widely used to manipulate DNA molecules in applications ranging from benchtop cloning to genome modifications in transgenic animals. Despite the simple, highly symmetric nature of the Cre-loxP system, there is strong evidence that the reaction is asymmetric; the 'bottom' strands in the recombining loxP sites are preferentially exchanged before the 'top' strands. Here, we address the mechanistic basis for ordered strand exchange in the Cre-loxP recombination pathway. Using suicide substrates containing 5'-bridging phosphorothioate linkages at both cleavage sites, fluorescence resonance energy transfer between synapsed loxP sites and a Cre mutant that can cleave the bridging phosphorothioate linkage but not a normal phosphodiester linkage, we showed that preferential formation of a specific synaptic complex between loxP sites imposes ordered strand exchange during recombination and that synapsis stimulates cleavage of loxP sites.     

Action of repeat-induced point mutation on both strands of a duplex and on tandem duplications of various sizes in Neurospora.

In Neurospora crassa, DNA sequence duplications are detected and altered efficiently during the sexual cycle by a process known as RIP (repeat-induced point mutation). Affected sequences are subjected to multiple GC-to-AT mutations. To explore the pattern in which base changes are laid down by RIP we examined two sets of strains. First, we examined the products of a presumptive spontaneous RIP event at the mtr locus. Results of sequencing suggested that a single RIP event produces two distinct patterns of change, descended from the two strands of an affected DNA duplex. Equivalent results were obtained using an exceptional tetrad from a cross with a known duplication flanking the zeta-eta (zeta-eta) locus. The mtr sequence data were also used to further examine the basis for the differential severity of C-to-T mutations on the coding and noncoding strands in genes. The known bias of RIP toward CpA/TpG sites in conjunction with the sequence bias of Neurospora accounts for the differential effect. Finally, we used a collection of tandem repeats (from 16 to 935 bp in length) within the mtr gene to examine the length requirement for RIP. No evidence of RIP was found with duplications shorter than 400 bp while all longer tandem duplications were frequently affected. A comparison of these results with vegetative reversion data for the same duplications is consistent with the idea that reversion of long tandem duplications and RIP share a common step.     

Immunity to melanoma mediated by 4-1BB is associated with enhanced activity of tumour-infiltrating lymphocytes

4-1BB costimulates T cells to carry out effector functions such as eradication of established tumours. 4-1BB (CD137) is a member of the TNF receptor family, and its triggering by either 4-1BB ligand or antibody ligation induces T-cell activation and growth. We analysed tumour-infiltrating lymphocytes (TIL) in the experimental B16F10 melanoma model to determine the mechanisms involved in 4-1BB-mediated tumour suppression. 4-1BB(+/+) mice survived longer than 4-1BB(-/-) mice, and survival was further prolonged by triggering 4-1BB with an agonistic mAb. The number of metastatic B16F10 colonies in the lung was much greater in 4-1BB(-/-) mice than in their 4-1BB(+/+) littermates. Administration of agonistic anti-4-1BB mAb increased the number of TIL in the tumour masses in the lungs of 4-1BB(+/+) mice. The numbers of CD4(+) T, CD8(+) T and CD11b(+) TIL increased in these mice. Anti-4-1BB mAb induced not only CD8(+) 4-1BB(+) T cells but also a CD8(+) IFN-gamma(+) T-cell population. B16F10 cells from the lungs of anti-4-1BB-treated mice showed enhanced expression of MHC class Iota and IotaIota antigens compared with the same cells from control IgG-treated mice. Thus, the increase in number of CD8(+) T cells and enhanced MHC Iota and IotaIota expression in B16F10 cells that result from augmented IFN-gamma production in response to anti-4-1BB mAb may lead to suppression of tumour growth and metastasis.