Identification of a chromosome-specific probe that maps within the Ph1 deletions in common and durum wheat

 The Ph1 (pairing homoeologous) gene is the major factor that determines the diploid-like chromosome behavior of polyploid wheat. This gene, which is located on the long arm of chromosome 5B (5BL), suppresses homoeologous pairing at meiosis while allowing exclusive homologous pairing. In an effort to tag the specific chromosomal region where this gene is located, we have previously microdissected chromosome arm 5BL from bread wheat and produced a plasmid library by random PCR amplification and cloning. In this work we isolated from this library a 5BL-specific probe, WPG90, and mapped it within the interstitial deleted chromosome fragments carrying Ph1 in common and durum wheat. A PCR assay of Ph1 based on WPG90 was developed that allows an easy identification of homozygous genotypes deficient for this gene. Received: 19 June 1996 / Accepted: 18 October 1996     

Targeted mapping of ESTs linked to the adult plant resistance gene Lr46 in wheat using synteny with rice

The gene Lr46 has provided slow-rusting resistance to leaf rust caused by Puccinia triticina in wheat (Triticum aestivum), which has remained durable for almost 30 years. Using linked markers and wheat deletion stocks, we located Lr46 in the deletion bin 1BL (0.84–0.89) comprising 5% of the 1BL arm. The distal part of chromosome 1BL of wheat is syntenic to chromosome 5L of rice. Wheat expressed sequence tags (ESTs) mapping in the terminal 15% of chromosome 1BL with significant homology to sequences from the terminal region of chromosome 5L of rice were chosen for sequence-tagged site (STS) primer design and were mapped physically and genetically. In addition, sequences from two rice bacterial artificial chromosome clones covering the targeted syntenic region were used to identify additional linked wheat ESTs. Fourteen new markers potentially linked to Lr46 were developed; eight were mapped in a segregating population. Markers flanking (2.2 cM proximal and 2.2 cM distal) and cosegregating with Lr46 were identified. The physical location of Lr46 was narrowed to a submicroscopic region between the breakpoints of deletion lines 1BL-13 [fraction length (FL)=0.89–1] and 1BL-10 (FL=0.89–3). We are now developing a high-resolution mapping population for the positional cloning of Lr46.     

Molecular Markers of Ph1 Gene in Chinese Spring and Development of Winter Wheat New Line Harboring ph1b Gene

he genomic DNA of common wheat (Triticum aestivum L.) “Chinese Spring” (CS) and its ph1b mutant were analyzed by using 19 sequence tagged site PCR (STS-PCR) primers, which derived from RFLP probes from barley (Hordeum vulgare L.) chromosome 5H. One marker was identified on wheat chromosome 5BL, which is 5.7 cM (centiMorgan) proximal to Ph1 gene, using the CS homoeologous group 5 nullisomic-tetrasomic, ditelosomic 5BL line and an F2 population from CS×ph1b mutant. This linked PCR marker was converted into a more specific sequence characterized amplified region (SCAR) marker. To obtain a new winter wheat line containing ph1b gene, the authors used a nullisomic 5B line of “Abbodanza”as a bridge parent and crossed respectively with the CS ph1b mutant (donor) and a winter wheat variety, “Jing 411” (recipient). The meiotic chromosome pairing was checked in the progeny of each cross, as well as using the marker-assistant selection of the SCAR marker identified for ph1b gene. After three inter-crossing and one selfing, a relatively stable ph1b substitution line of winter wheat with “Jing 411” background was obtained.     

Genotypic variation in tetraploid wheat affecting homoeologous pairing in hybrids with Aegilops peregrina.

The Ph1 gene has long been considered the main factor responsible for the diploid-like meiotic behavior of polyploid wheat. This dominant gene, located on the long arm of chromosome 5B (5BL), suppresses pairing of homoeologous chromosomes in polyploid wheat and in their hybrids with related species. Here we report on the discovery of genotypic variation among tetraploid wheats in the control of homoeologous pairing. Compared with the level of homoeologous pairing in hybrids between Aegilops peregrina and the bread wheat cultivar Chinese Spring (CS), significantly higher levels of homoeologous pairing were obtained in hybrids between Ae. peregrina and CS substitution lines in which chromosome 5B of CS was replaced by either 5B of Triticum turgidum ssp. dicoccoides line 09 (TTD09) or 5G of Triticum timopheevii ssp. timopheevii line 01 (TIMO1). Similarly, a higher level of homoeologous pairing was found in the hybrid between Ae. peregrina and a substitution line of CS in which chromosome arm 5BL of line TTD140 substituted for 5BL of CS. It appears that the observed effect on the level of pairing is exerted by chromosome arm 5BL of T turgidum ssp. dicoccoides, most probably by an allele of Ph1. Searching for variation in the control of homoeologous pairing among lines of wild tetraploid wheat, either T turgidum ssp. dicoccoides or T timopheevii ssp. armeniacum, showed that hybrids between Ae. peregrina and lines of these two wild wheats exhibited three different levels of homoeologous pairing: low, low intermediate, and high intermediate. The low-intermediate and high-intermediate genotypes may possess weak alleles of Ph1. The three different T turgidum ssp. dicoccoides pairing genotypes were collected from different geographical regions in Israel, indicating that this trait may have an adaptive value. The availability of allelic variation at the Ph1 locus may facilitate the mapping, tagging, and eventually the isolation of this important gene.     

Centromere association is an unlikely mechanism by which the wheat Ph1 locus regulates metaphase I chromosome pairing between homoeologous chromosomes

Chiasmate pairing between homoeologous chromosomes at metaphase I (MI) of meiosis in wheat is prevented by the activity of the Ph1 locus on chromosome 5B. Several hypotheses have been proposed sharing the assumption that Ph1 regulates MI chromosome pairing by regulating centromere-mediated chromosome alignment before the onset of meiosis. To test the relevance of the putative predetermination of chromosome pairing at MI by the centromere-mediated chromosome association prior to meiosis, a 2BL.2RL homoeoisochromosome was constructed and its MI pairing was assessed in the presence and absence of the Ph1 locus. Although the 2BL and 2RL arms of the homoeoisochromosome paired with each other at MI in the absence of Ph1, they never paired with each other at MI in the presence of Ph1. Since the two arms were permanently associated in the homoeoisochromosome via a common centromere, it is unlikely that Ph1 predetermines MI pairing between homoeologous chromosomes solely by controlling premeiotic association of centromeres. These findings are consistent with the idea that Ph1 determines the chromosome pairing pattern at MI by scrutinizing homology across the entire chromosome.     

Origin, structure, and behavior of a highly rearranged deletion chromosome 1BS-4 in wheat.

Wheat (Triticum aestivum L.) deletion (del) stocks are valuable tools for the physical mapping of molecular markers and genes to chromosome bins delineated by 2 adjacent deletion breakpoints. The wheat deletion stocks were produced by using gametocidal genes derived from related Aegilops species. Here, we report on the origin, structure, and behavior of a highly rearranged chromosome 1BS-4. The cytogenetic and molecular marker analyses suggest that 1BS-4 resulted from 2 breakpoints in the 1BS arm and 1 breakpoint in the 1BL arm. The distal segment from 1BS, except for a small deleted part, is translocated to the long arm. Cytologically, chromosome 1BS-4 is highly stable, but shows a unique meiotic pairing behavior. The short arm of 1BS-4 fails to pair with a normal 1BS arm because of lack of homology at the distal ends. The long arm of 1BS-4 only pairs with a normal 1BS arm within the distal region translocated from 1BS. Therefore, using the 1BS-4 deletion stock for physical mapping will result in the false allocation of molecular markers and genes proximal to the breakpoint of 1BS-4.     

Linkage of amelogenin (Amel) to the distal portion of the mouse X chromosome.

Amelogenins are hydrophobic, proline-rich proteins that are the primary biosynthetic products of ameloblasts. These cells are responsible for the formation of tooth enamel, and amelogenins play an important role in the process of biomineralization. A cDNA, corresponding to the mouse 26-kDa amelogenin, has been molecularly cloned and sequenced. Southern blot analysis of genomic DNA from the mouse using this cDNA as a probe indicates that there is only one mouse amelogenin (Amel) gene. This paper describes restriction site variation for the Amel gene that we have identified between C57BL/6 and M. spretus and the segregation of that variation as an X-chromosome gene. The position of the amelogenin locus (Amel) relative to the loci for alpha-galactosidase (Ags), proteolipoprotein (Plp), and the random genomic probe DXWas31 has been determined. Amel is established as: (1) the most distal locus in the genetic map of the mouse X chromosome, (2) lying proximal to the X:Y pairing region, and (3) being restricted to the mouse X chromosome.     

Pairing competition between identical and homologous chromosomes in autotetraploid rye heterozygous for interstitial C-bands

Pairing competition between identical and homologous non-identical chromosomes is analysed in autotetraploid metaphase I cells of rye where one pair of identical partners bears an interstitial C-band in the long arm of chromosome 6R whereas the other pair of identical partners lacks such a C-band. This makes it possible to study pairing preferences in two distinct regions of the same chromosome arm. A significant excess of associations involving homologous partners is always observed in the proximal segment (from the centromere to the C-band), whereas a good fit with the expected random ratio, or else identical pairing preferences, is found in the distal segment (from the C-band to the telomere). Differences in the processes of pairing and chiasma formation in 6RL, and/or a readjustment in the pattern of chiasma distribution due to heterozygosity for the interstitial C-band as a result of homologous nonidentical pairing, may be responsible for the different behaviour detected in the two regions of the marked arm.     

Use of RAPD- and STS-analysis for marking genes of a homeologic group from chromosome 5 of common wheat

The search for STS (sequence-tagged site) and RAPD (random amplified polymorphic DNA) markers tightly linked to some genes of homeologous group 5 chromosomes of common wheat Triticum aestivum L., more specifically, awns inhibitor genes (B1), vernalization response gene (Vrn1), and homeologous chromosome pairing gene (Ph1), was conducted. To estimate the linkage of the gene with the marker, wheat lines marked with recessive alleles b1 and vrn1 were used. RELP (restriction fragment length polymorphism) and SSR (simple sequence repeat) analyses of isogenic wheat lines were conducted to characterize the chromosomal region transferred to the isogenic line from the donor parent. In RAPD analysis of isogenic wheat lines marked with recessive alleles b1 and vrn1, 95 arbitrary primers were used. To develop STS markers, analysis of the primary structure of RELP markers Xpsr426 and Xcdo504, tightly linked to the Vrn1 gene, and the Xpsr1201 marker, located at the Ph1 locus, was carried out. Two markers that are tightly linked to the Vrn1 gene (5AL)--RAPD marker Xr405 and STS marker Xsts426--were obtained in this work. In addition, there is every reason to believe that Xsts426 can be used as a PCR marker of genes Vrn2 (5BL) and Vrn3 (5DL), while Xsts1201, of the gene Ph1 (5BL).     

Mouse paracentric inversion In(3)55Rk mutates the urate oxidase gene

The paracentric inversion In(3)55Rk on mouse Chromosome 3 (Chr 3) was induced by cesium irradiation. Genetic crosses indicate the proximal breakpoint cosegregates with D3Mit324 and D3Mit92; the distal breakpoint cosegregates with D3Mit127, D3Mit160, and D3Mit200. Giemsa-banded chromosomes show the inversion spans approximately 80% of Chr 3. The proximal breakpoint occurs within band 3A2, not 3B as reported previously; the distal breakpoint occurs within band 3H3. Mice homozygous for the inversion exhibit nephropathy indicative of uricase deficiency. Southern blot analyses of urate oxidase, Uox, show two RFLPs of genomic mutant DNA: an EcoRI site between exons 4-8 and a BamHI site 3' to exon 6. Mutant cDNA fails to amplify downstream of base 844 at the 3' end of exon 7. FISH analysis of chromosomes from inversion heterozygotes, using a cosmid clone containing genomic wild-type DNA for Uox exons 2-4, shows that a 5' segment of the mutated Uox allele on the inverted chromosome has been transposed from the distal breakpoint region to the proximal breakpoint region. Clinical, histopathological, and Northern analyses indicate that our radiation-induced mutation, uox(In), is a putative null.     

Physical mapping of four RAPDs in the B chromosome of maize

 Four DNA fragments were amplified specifically from the B chromosome by PCR using random 10-base oligonucleotides as primers. The location of the fragments in the B chromosome was determined based on whether or not they were amplified from the hypo- ploid DNA generated by four B-A translocations, three of which break in the proximal euchromatic region and the fourth in the distal one-third of the heterochromatic region on the B long arm. Since the hypoploid DNA carries the portion of the B chromosome distal to the breakpoint of a translocation, the presence of a fragment in the hypoploid DNA, but not in the control (which is devoid of any B chromatin), indicates that the fragments is located in the B region distal to the breakpoint in the B long arm. Two fragments were mapped to the euchromatic region and two others to either the distal portion of the euchromatic region or the proximal two-thirds of the heterochromatic region. These fragments in turn mapped three B-A translocations whose breakpoints were located in the euchromatic region. Received: 22 May 1996 / Accepted: 30 August 1996     

A DNA Fragment Mapped within the Submicroscopic Deletion of Ph1, a Chromosome Pairing Regulator Gene in Polyploid Wheat

Bread wheat is an allohexaploid consisting of three genetically related (homoeologous) genomes. The homoeologous chromosomes are capable of pairing but strict homologous pairing is observed at metaphase 1. The diploid-like pairing is regulated predominantly by Ph1, a gene mapped on long arm of chromosome 5B. We report direct evidence that a mutant of the gene (ph1b) arose from a submicroscopic deletion. A probe (XksuS1-5) detects the same missing fragment in two independent mutants ph1b and ph1c and a higher intensity fragment in a duplication of the Ph1 gene. It is likely that XksuS1-5 lies adjacent to Ph1 on the same chromosome fragment that is deleted in ph1b and ph1c. XksuS1-5 can be used to tag Ph1 gene to facilitate incorporation of genetic material from homoeologous genomes of the Triticeae. It may also be a useful marker in cloning Ph1 gene by chromosome walking.     

Molecular analysis of the Adh region of the genome of Drosophila melanogaster

A small region of the genome of Drosophila melanogaster has been cloned in a series of overlapping phage. A length of 165 X 10(3) base-pairs of contiguous DNA that spans polytene chromosome region 35A4 to 35B1 and includes the structural gene for alcohol dehydrogenase (Adh) as well as at least two other genes, outspread (osp) and no-ocelli (noc), has been characterized by mapping chromosome aberrations to the DNA. The relationship between osp and Adh is surprising: of nine osp alleles associated with chromosome breakpoints, five map distal (i.e. 5') to Adh and four map proximal (i.e. 3') to this gene. None affects the expression of Adh. As defined by these and other breakpoints, the osp gene spans at least 52 X 10(3) base-pairs and overlaps the Adh gene. The noc gene, as defined by the mapping of nearly 30 breakpoints, is at least 50 X 10(3) base-pairs in size. Alleles of noc and noc- deletions show either of two kinds of interaction with the recessive lethality of l(2)br29ScoR+1, a lethal that maps immediately distal to noc. One class of noc allele is viable when heterozygous with ScoR+1, while the other class is lethal or semi-lethal. Both classes, however, are homozygous or hemizygous viable. The locations of these two classes of noc allele on the DNA fall into two clusters, with those that are viable with ScoR+1 located proximal to those that are not. The physical boundary between these classes lies at a site just distal to that of the breakpoint of the inversion associated with ScoR+1 itself.     

Cytochemical heterogeneity of the C-band in human chromosome 1

Summary The heterogeneity of the C-band of human chromosome 1 has been evaluated using several selective staining methods: C-banding (CBG), distamycin A plus 4-6-diamidino-2-phenylindole (DA/DAPI) and Giemsa G-11 pattern following the treatment with the restriction endonucleases AluI and HaeIII. The bands produced by each method are characteristic but not identical. The total C-band is resistant to AluI treatment. The bands induced by HaeIII and the one stained by DA/DAPI are markedly similar but smaller than the C-band. The G-11 technique stains yet smaller regions than those of HaeIII and DA/DAPI. Depending on the expression of staining properties, the C-band of chromosome 1 usually consists of three subdivisions: the proximal, intermediate and distal regions, suggesting an extremely heterogeneous nature. The staining variations between different regions are further substantiated by studies of a reciprocal translocation where the proximal region and the remaining C-band of chromosome 1 are separate.     

Duplication/deficiency mapping of situs inversus viscerum (iv), a gene that determines left-right asymmetry in the mouse.

A recessive mutation in the mouse, situs inversus viscerum (iv), results in randomization of organ position along the left-right body axis: approximately 50% of the progeny of homozygous matings exhibit situs solitus and 50% exhibit situs inversus. Recent studies have established genetic linkage between iv and the immunoglobulin heavy chain gene complex (Igh-C), located on distal mouse chromosome 12. In the present study, we have refined the genetic map location of iv relative to the breakpoint of a reciprocal translocation, T(5;12)31H, involving the telomeric region of chromosome 12 distal to Igh-C and the proximal region of chromosome 5. The translocation results in a large 12(5) derivative chromosome and a small 5(12) derivative chromosome. Because mice with either monosomy or tertiary trisomy for the 5(12) chromosomal region are viable, duplication/deficiency mapping is possible. Deficiency mapping was performed by mating iv/iv homozygotes and T31H heterozygotes. Two animals monosomic for distal mouse chromosome 12 were produced. One of the animals with cytogenetically confirmed monosomy for distal chromosome 12 exhibited situs inversus, indicating that the iv mutation is located at or distal to the T31H breakpoint. For duplication analysis, matings were initially carried out between iv/iv homozygotes and unbalanced T31H animals trisomic for distal chromosome 12. Cytogenetically verified tertiary trisomic progeny were identified and backcrossed with iv/iv homozygotes. The resulting trisomic progeny, 50% of which are expected to carry the iv mutation on both cytogenetically normal copies of chromosome 12, were scored for phenotype.(ABSTRACT TRUNCATED AT 250 WORDS)     

Regional mapping of two human immunoglobulin V lambda genes and analysis of the V lambda locus in chronic myeloid leukaemia.

The human immunoglobulin V lambda locus has been studied in relation to chromosomal translocations involving chromosome 22. DNA probes for two V lambda genes which belong to different subgroups and do not cross hybridize, were used to show that both V lambda genes are located on the Philadelphia chromosome in chronic myeloid leukaemia (CML). Both genes map in band 22q11 to a region that is bounded on the distal side by the breakpoints for CML 9:22 translocations and on the proximal side by the breakpoint for an X:22 translocation. We have found no evidence for rearrangements or amplification of either V lambda gene in CML, in either the chronic or acute phases of the disease. In K562 cells which are derived from the pleural effusion of a patient with Ph1-positive CML, there appears to be no rearrangement of the V lambda genes, but they are both amplified about four times. We have estimated that the minimum size for the amplification unit in K562 cells is 186 kb.     

Genetic and molecular mapping of the Hmt region of mouse.

We have mapped a new region of the mouse major histocompatibility complex (MHC) that contains the nuclear gene, Hmt, for the maternally transmitted antigen, Mta. The Hmt region of chromosome 17 lies between a recombinational breakpoint distal to Tla and another proximal to Tpx-1, thus including Pgk-2. A novel MHC class I gene fragment, R4B2, was cloned and mapped to this region as was another new class I gene, Thy19.4. Both lie proximal to Pgk-2, within the distal inversion in t-haplotypes. The presence of several other MHC class I genes in the Hmt region is predicted from analysis of the recombinants that define the region.