Generation of a Brassica oleracea composite RFLP map: linkage arrangements among various populations and evolutionary implications

Summary A composite linkage map of Brassica oleracea was developed from maps of four different populations, derived from 108 DNA, isozyme and morphological loci covering over 747 centimorgans in 11 linkage groups. Of these linkage groups, 8 were assigned to their respective chromosomes by alignment with gene synteny groups of B. oleracea. Distortions in segregation ratios increased with the level of divergence of the parents and were attributed to differentiation of parental chromosomes. Comparison of the individual maps demonstrates that the B. oleracea genome undergoes frequent chromosomal rearrangement, even at the subspecies level. Small inversions were the most frequent form of aberration followed by translocations. The former type of aberration could occur without a noticeable effect on meiotic behavior of chromosomes or on pollen fertility. The obvious deduction from the composite map is that a large fraction of the B. oleracea genome is duplicated, falling into three classes: randomly dispersed, linked-gene families, and blocks duplicated in non-homologous chromosomes. The genealogy of chromosomes sharing duplicated segments was formulated and indicates that B. oleracea is a secondary polyploid species derived from ancestral genome(s) of fewer chromosomes.     

Differences between genetic and physical centromere distances in the case of two genes for male sterility in barley

Summary Linkage studies with thirty translocations (one of the two chromosomes involved being number 4) in relation to msg24 (chromosome 4) and thirteen translocations (one of the two chromosomes involved being number 6) in relation to msg6 (chromosome 6) show without exception close linkage for all combinations tested. The results indicate that both genes are located genetically in or close to the centromere regions of their chromosomes.Cytological analysis of two BTT stocks (balanced tertiary trisomics) ascertained the respective chromosome arms (both msg24 and msg6 on the short arms) and revealed marked differences between genetic and physical centromere distances. The reason is obviously the high content of centromeric heterochromatin occupying both the chromosome arms involved.     

Mapping genetic factors controlling pollen viability in an interspecific cross in Helianthus sect. Helianthus

Segregation of 48 genetic markers, including one CMS restorer gene, one morphological character gene, six isozymes and 40 RAPD loci, was scored in a backcross progeny of an interspecific hybrid H. argophyllusxH. annuus cv RHA274. A linkage map was generated taking into account segregation distortions for 11 of the 48 loci in the frame of two different models considering locus-pair segregation in the context of either independent selection pressures or non-equilibrated parental classes. The map consists of nine linkage groups and nine isolated markers covering 390 cM. Approximately half of the plants of the BC1 were male fertile as expected for the segregation of one dominant male-fertility restorer gene; however, these displayed a large range of variation for pollen viability. About 80% of this variation was explained by three genomic regions located on linkage groups 1, 2 and 3. The observation of meiotic chromosomes revealed a significant rate of mispairing (rod bivalents and tetravalents) in tight correlation with pollen viability, indicating that chromosome rearrangements (translocations) are the preponderant factors reducing pollen viability in this progeny. Cytogenetic and mapping data suggest that the three genomic regions involved in pollen-viability variation are located close to translocation points which differentiate the parental-species karyotypes. Segregation distortion was observed for loci correlated with pollen-viability variation. These were most likely the result of two possible suggested mechanisms.     

Comparative Genome Mapping of Sorghum and Maize

Linkage relationships were determined among 85 maize low copy number nuclear DNA probes and seven isozyme loci in an F2 population derived from a cross of Sorghum bicolor ssp. bicolor x S. bicolor ssp. arundinaceum. Thirteen linkage groups were defined, three more than the 10 chromosomes of sorghum. Use of maize DNA probes to produce the sorghum linkage map allowed us to make several inferences concerning processes involved in the evolutionary divergence of the maize and sorghum genomes. The results show that many linkage groups are conserved between these two genomes and that the amount of recombination in these conserved linkage groups is roughly equivalent in maize and sorghum. Estimates of the proportions of duplicated loci suggest that a larger proportion of the loci are duplicated in the maize genome than in the sorghum genome. This result concurs with a prior estimate that the nuclear DNA content of maize is three to four times greater than that of sorghum. The pattern of conserved linkages between maize and sorghum is such that most sorghum linkage groups are composed of loci that map to two maize chromosomes. This pattern is consistent with the hypothesized ancient polyploid origin of maize and sorghum. There are nine cases in which locus order within shared linkage groups is inverted in sorghum relative to maize. These may have arisen from either inversions or intrachromosomal translocations. We found no evidence for large interchromosomal translocations. Overall, the data suggest that the primary processes involved in divergence of the maize and sorghum genomes were duplications (either by polyploidy or segmental duplication) and inversions or intrachromosomal translocations.     

Karyotypes ofMegaselia scalaris (Diptera) wild-type and translocation strains

Making use of somatic pairing of homologous chromosome arms and of balanced translocations as cytogenetic markers, the three chromosome pairs of the phorid flyMegaselia scalaris have been identified and described. From measurements of the compliments a standard karyotype was constructed. Identification of the chromosomes allows cytogenetic, phenotypic and molecular markers to be assigned to specific chromosomes. Sex linkage of t(1;2) and t(2;3) translocations define chromosome 2 as the normal sex determining chromosome pair in our translocation strains, and therefore also, probably, in the wild-type strain from which they were derived. No differences between X and Y with respect to size of arms or C-bands were detected.     

Cytogenetic studies of Lucilia cuprina dorsalis R.-D. (Diptera: Calliphoridae)

Standard photographic maps of the trichogen cell polytene chromosomes are presented. Polytene chromosome locations of 39 mutations have been determined by genetic mapping of autosomal duplications, inversions and translocations. Homologies between the polytene chromosomes of L. cuprina, other Calliphoridae, and Sarcophagidae are noted; genetic linkage groups may have been conserved largely intact during the evolution of the higher Diptera.     

Assignment of RFLP linkage groups to their respective chromosomes in aneuploids of sugi (Cryptomeria japonica)

Aneuploids of sugi (Cryptomeria japonica) were found in the open-pollinated progenies of triploidplus tree clones. Seven trisomics and one hypotriploid were used to assign the chromosomes to the RFLP linkage groups constructed previously. The Southern blots containing their genomic DNA were hybridized with the labeled DNA clones corresponding to the loci in the linkage map. The additional dosage in autoradiographs showed that the cloned DNA fragment was located on the extra chromosome in the trisomics. On the other hand, the extra chromosome in two trisomics and the chromosome lacking the triplet in the hypotriploid were cytologically identified as chromosome 10 by consistent presence of a secondary constriction in the proximal region of its short arm. As a result, three linkage groups were assigned to their respective chromosomes, namely chromosome 10 and two other chromosomes.     

Stratification by CARD15 variant genotype in a genome-wide search for inflammatory bowel disease susceptibility loci

Previously we have conducted a genome-wide search for inflammatory bowel disease susceptibility loci in a large European cohort. Results from this study demonstrated suggestive evidence of linkage to loci at chromosomes 1q, 6p, and 10p and replicated linkages on chromosomes 12 and 16. Recently, NOD2/CARD15 on chromosome 16q12 has been found to be strongly associated with Crohn's disease. In order to determine if there are other loci in the genome that interact with the three associated functional variants in CARD15 (R702W, G908R, 1007fs), we have stratified our large inflammatory bowel disease genome scan cohort by dividing pedigrees into two groups stratified by CARD15 variant genotype. The two pedigree groups were analysed using non-parametric allele sharing methods. The group of pedigrees that contained one of the three CARD15 variants had two suggestive linkage results occurring in 6p (lod = 3.06 at D6S197, IBD phenotype) and 10p (lod=2.29 at D10S197, CD phenotype). In addition, at 16q12 where CARD15 is located, the original genome scan had a peak lod score of 2.18 at D16S415 (CD phenotype). The stratified pedigree cohort containing one of three CARD15 variants had a peak lod score of 0.90 at D16S415 (CD phenotype), accounting for approximately less than half of the genetic evidence for linkage at this locus. This result is in agreement with the existence of a substantial number of private variants at the NOD2/CARD15 locus. Interaction with NOD2/CARD15 needs to be considered in future gene identification efforts on chromosomes 6 and 10.     

Chromosomal mapping of tRNA genes from Dictyostelium discoideum

Summary Different wild-type isolates of Dictyostelium discoideum exhibit extensive polymorphism in the length of restriction fragments carrying tRNA genes. These size differences were used to study the organisation of two tRNA gene families which encode a tRNA^Val(GUU) and a tRNA^Val(GUA) gene. The method used involved a combination of classitics. The tRNA genes were mapped to specific linkage groups (chromosomes) by correlating the presence of polymorphic DNA bands that hybridized with the tRNA gene probes with the presence of genetic markers for those linkage groups. These analyses established that both of the tRNA gene families are dispersed among sites on several of the chromosomes. Information of nine tRNA^Val(GUU) genes from the wild-type isolate NC4 was obtained: three map to linkage group I (C, E, F,), two map to linkage group II (D, I), one maps to linkage group IV (G), one, which corresponds to the cloned gene, maps to either linkage group III or VI (B), and two map to one of linkage groups III, VI or VIII (A, H). Six tRNA^Val(GUA) genes from the NC4 isolate were mapped; one to linkage group I (D), two to linkage group III, VI or VII (B, C) and three to linkage group VII or III (A, E, F).     

Construction and analysis of a two-chromosome double reciprocal translocation that functions as a ‘balancer’ inNeurospora crassa

T(IIL; VL;IIR; VR) BLNC-1 is a compound chromosome rearrangement inNeurospora crassa that combines two reciprocal translocations:T(IIL; VL) AR30 which interchanges the left end of linkage group II with the left end of linkage group V, andT(IIR;VR) ALS154 which interchanges the right end of linkage group II with the right end of linkage group V.BLNC-1 acts as a crossover suppressor for most of both linkage groups II and V since single crossovers between the rearrangement breakpoints result in progeny with lethal unbalanced duplications and deficiencies. The integrity ofBLNC-1 following meiosis was tested in crosses of markedBLNC-1 by marked Normal sequence, with markers located at critical points on linkage groups II and V. Although recombination between distal markers in the four arms was reduced markedly, double crossovers in the long intervening regions occurred with a frequency of 21%. Of these double crossovers, most were coincidental crossovers, one in each of the long intervening regions, resulting in the resolution of the complex into its component rearrangements (16%), while a minority of the double crossovers (5%) were crossovers involving only one of the two component linkage groups, and resulted in the insertion of a segment between the breakpoints. - TheBLNC-1 balancer can be used for: (1) mapping new loci to linkage groups II and V, especially for identifying markers mapping near the tips of the linkage groups; (2) for isolating genetically intact chromosomes from natural populations or for quantitative genetic studies; and (3) for studying recombinational hot-spots which can be detected as escapes from crossover suppression. -Based on experience withBLNC-1, future two-chromosome balancers should be designed with two breakpoints near, but not at, the opposite ends of the chromosome to be balanced, and the other two breakpoints close to, but spanning, the centromere of a second chromosome. Such a construction when combined with appropriately placed selective markers should prevent breakdown of the complex, and should resemble an inversion in eliminating crossover products. Contribution no. 85-218-J from the Department of Plant Pathology, Kansas Agricultural Experiment Station, Kansas State University, Manhattan.     

Genetics of screwworm: new genetic markers and preliminary linkage map

Eight new genetic markers for Cochliomyia hominivorax (Diptera: Calliphoridae), the screwworm, are characterized. The markers include three eye mutants, lemon-eye (le), cherry-eye (ch), and red-eye (re); one wing mutant, curly-wing (cw); and four allozyme markers, amylase (Amy-1), glycerol-3-phosphate dehydrogenase (Gpd), phosphoglucomutase (Pgm), and octanol dehydrogenase (Odh). The markers are associated into four linkage groups. Radiation-induced translocations were used to correlate the linkage groups with their respective chromosomes. A preliminary genetic linkage map with these and three previously characterized loci is presented.     

A reciprocal translocation radically reshapes sex‐linked inheritance in the common frog

X and Y chromosomes can diverge when rearrangements block recombination between them. Here we present the first genomic view of a reciprocal translocation that causes two physically unconnected pairs of chromosomes to be coinherited as sex chromosomes. In a population of the common frog (Rana temporaria), both pairs of X and Y chromosomes show extensive sequence differentiation, but not degeneration of the Y chromosomes. A new method based on gene trees shows both chromosomes are sex‐linked. Furthermore, the gene trees from the two Y chromosomes have identical topologies, showing they have been coinherited since the reciprocal translocation occurred. Reciprocal translocations can thus reshape sex linkage on a much greater scale compared with inversions, the type of rearrangement that is much better known in sex chromosome evolution, and they can greatly amplify the power of sexually antagonistic selection to drive genomic rearrangement. Two more populations show evidence of other rearrangements, suggesting that this species has unprecedented structural polymorphism in its sex chromosomes.     

Genomic organization of the yeast Yarrowia lipolytica

We produced electrophoretic karyotypes of the reference strain E150 and of seven other isolates from different geographical origins to study the genomic organization of the dimorphic yeast Yarrowia lipolytica. These karyotypes differed in the number and size of the chromosomal bands. The karyotype of the reference stain E150 consisted of five bands of between 2.6 and 4.9 Mb in size. This strain contained at least five rDNA clusters, from 190 to 620 kb in size, which were scattered over most of the chromosomes. The assignment of 43 markers, including rRNA genes and three centromeres, to the E150 bands defined five linkage groups. Hybridization to the karyotypes of other isolates with pools of markers of each linkage group showed that linkage groups I, II, IV and V were conserved in the strains tested whereas group III was not and was split between at least two chromosomes in most strains. Use of a meganuclease I-SceI site targeted to one locus of E150 linkage group III showed that two chromosomes actually comigrated in band III of this strain. Our results are compatible with six chromosomes defining the haploid complement of strains of Y. lipolytica and that, despite an unprecedented chromosome length polymorphism, the overall structure of the genome is conserved in different isolates. Received: 27 March 1997; in revised form: 8 July 1997 / Accepted: 9 July 1997     

Holozygosity for sex-linked genes in males of the termiteIncisitermes schwarzi

The termite Incisitermes schwarzi has multiple sex chromosomes that have arisen by repeated translocations between autosomes and previously existing sex chromosomes. Two sex-linked allozyme loci--Acp-1 and Est-3--are holozygous, not hemizygous, in males (the heterogametic sex). Both loci show less than 1% crossing-over between X and Y chromosomes, and alleles of both are in marked disequilibrium with respect to X vs Y linkage. The two loci assort independently in female meiosis, indicating that they lie on different sex chromosomes. But they are tightly linked in male meiosis because of nonrandom assortment of the multiple X and Y chromosomes in males of this species. The findings of holozygosity and strong linkage disequilibrium suggest that differential selection in the two sexes at or near these loci may be responsible for the establishment of the translocations in this species. The existence of active Y-linked alleles also suggests that the translocations may have occurred recently.     

Pairing and recombination between individual chromosomes of wheat and rye in hybrids carrying the ph1b mutation

Wheat-rye chromosome associations at metaphase I studied by Naranjo and Fernández-Rueda (1991) in ph1b ABDR hybrids have been reanalysed to establish the frequency of pairing between individual chromosomes of wheat and rye. Wheat chromosomes, except for 2A and 2D, and their arms were identified by C-banding. Diagnostic C-bands and other cytological markers such as telocentrics or translocations were used to identify each one of the rye chromosomes and their arms. Both the amount of telomeric C-heterochromatin and the structure of the rye chromosomes relative to wheat affected the level of wheatrye pairing. The degree to which rye chromosomes paired with their wheat homoeologues varied with each of the three wheat genomes; in most groups, the B-R association was more frequent than the A-R or D-R associations. Recombination between arms 1RL and 2RL and their homoeologues of wheat possessing a different telomeric C-banding pattern was detected and quantified at anaphase I. The frequency of recombinant chromosomes obtained supports the premise that recombination between wheat and rye chromosomes may be estimated from wheat-rye pairing.     

An algorithm for analyzing linkages affected by heterozygous translocations: QuadMap

Heterozygous chromosome rearrangements such as reciprocal translocations are most accurately displayed as two-dimensional linkage maps. Standard linkage mapping software packages, such as MapMaker, generate only one-dimensional maps and so reciprocal translocations appear as clusters of markers, even though they originate from two nonhomologous chromosomes. To more accurately map these regions, researchers have developed statistical methods that use the variance in map distance to distinguish among the four segments (two translocation, two interstitial) of the translocation. In this study, we describe modifications to one of these protocols, that proposed by Livingstone et al. (2000). We also introduce QuadMap, a new software application for dissecting heterozygous translocation-affected linkage maps.     

Polytene chromosomes and linkage group-chromosome correlations in the Australian sheep blowfly Lucilia cuprina (Diptera: Calliphoridae)

The trichogen cell polytene chromosome maps for the Australian sheep blowfly Lucilia cuprina dorsalis R.-D. are presented. Correlations between the autosomal linkage groups and the polytene and mitotic chromosomes were accomplished using autosome-autosome and sex chromosome-autosome translocations. It is suggested that the sex chromosomes are largely inert.This work was completed during the tenure of a Fulbright fellowship and was supported in part by Public Health Service grant 2T1 GM 373-08.     

Conserved linkage groups associated with large-scale chromosomal rearrangements between Old World and New World Leishmania genomes

The genus Leishmania can be taxonomically separated into three main groups: the Old World subgenus L. (Leishmania), the New World subgenus L. (Leishmania) and the New World subgenus L. (Viannia). The haploid genome of Old World Leishmania species has been shown to contain 36 chromosomes defined as physical linkage groups; the latter were found entirely conserved across species. In the present study, we tried to verify whether this conservation of the genome structure extends to the New World species of Leishmania. 300 loci were explored by hybridization on optimized pulsed field gel electrophoresis separations of the chromosomes of polymorphic strains of the six main pathogenic Leishmania species of the New World. When comparing these New World karyotypes with their Old World counterparts, 32 out of 36 linkage groups were found conserved among all species. Four chromosomal rearrangements were found. All species belonging to the L. (Viannia) subgenus were characterized by the presence (i) of a short sequence exchange between chromosomes 26 and 35, and (ii) more importantly, of a fused version of chromosomes 20 and 34 which are separated in all Old World species. 69 additional markers were isolated from a plasmid library specifically constructed from the rearranged chromosomes 20+34 in an attempt to detect mechanisms other than a fusion or breakage: only two markers out of 40 did not belong to the linkage groups 20 and 34. On the other hand, all strains belonging to the New World subgenus L. (Leishmania) were characterized by two different chromosomal rearrangements of the same type (fusion/breakage) as above as compared with Old World species: chromosomes 8+29 and 20+36. Consequently, these two groups of species have 35 and 34 heterologous chromosomes, respectively. Overall, these results show that large-scale chromosomal rearrangements occurred during the evolution of the genus Leishmania, and that the three main groups of pathogenic species are characterized by different chromosome numbers. Nevertheless, translocations seem particularly rare, and the conservation of the major linkage groups should be an essential feature for the compared genetics between species of this parasite.     

Evolutionary conservatism in arrangement of genetic material

The diploid number of the Rhesus macaque, Macaca mulatta, is 42. All chromosomes are biarmed and all constitutive heterochromatins are centromeric. The diploid number of the African Green monkey, Cercopithecus aethiops, is 60. Again all chromosomes are biarmed, but seven pairs possess very short second arms which are heterochromatic. The heterochromatins of remaining chromosomes are centromeric. Using G-banding and deleting the heterochromatic short arms, the chromosomes of the African Green monkey can be artificially fused to reconstruct a karyotype of the Rhesus with only one pair of unmatched small metacentrics. In addition to the Robertsonian type of translocations, several sets of centromere-telomere translocations were found. The latter type of translocation reduced three arms into two. Thus the fundamental number can be changed by two mechanisms: growing extra heterochromatic arms and the centromere-telomere fusions.     

Independent Origins of New Sex-Linked Chromosomes in the <Emphasis Type="Italic">melanica</Emphasis> and <Emphasis Type="Italic">robusta</Emphasis> Species Groups of <Emphasis Type="Italic">Drosophila</Emphasis>

Background  

Recent translocations of autosomal regions to the sex chromosomes represent important systems for identifying the evolutionary forces affecting convergent patterns of sex-chromosome heteromorphism. Additions to the sex chromosomes have been reported in the melanica and robusta species groups, two sister clades of Drosophila. The close relationship between these two species groups and the similarity of their rearranged karyotypes motivates this test of alternative hypotheses; the rearranged sex chromosomes in both groups are derived through a common origin, or the rearrangements are derived through at least two independent origins. Here we examine chromosomal arrangement in representatives of the melanica and the robusta species groups and test these alternative hypotheses using a phylogenetic approach.