Luis Aragón-Alcaide

A cereal centromeric sequence

We report the identification of a family of sequences located by in situ hybridisation to the centromeres of all theTriticeae chromosomes studied, including the supernumerary and midget chromosomes, the centromeres ofall maize chromosomes and the heterochromatic regions of rice chromosomes. This family of sequences, (CCS1), together with the cereal genome alignments, will allow the evolution of the cereal centromeres and their sites to be studied. The family of sequences also shows homology to the CENP-B box. The centromeres of the cereal species and the proteins that interact with them can now be characterised.

Association of homologous chromosomes during floral development

Reduction in chromosome number and genetic recombination during meiosis require the prior association of homologous chromosomes, and this has been assumed to be a central event in meiosis. Various studies have suggested, however, that while the reduction division of meiosis is a universally conserved process, the pre-meiotic association of homologues differs among organisms. In the fruit fly Drosophila melanogaster, some somatic tissues also show association of homologues [1,2]. In the budding yeast Saccharomyces cerevisiae, there is some evidence for homologue association during the interphase before meiotic division [3,4], and it has been argued that such associations lead directly to meiotic homologue pairing during prophase I [5]. The available evidence for mammals suggests that homologous chromosomes do not associate in germ cells prior to meiotic prophase [6]. To study the occurrence of homologue pairing in wheat, we have used vibratome tissue sections of wheat florets to determine the location of homologous chromosomes, centromeres and telomeres in different cell types of developing anthers. Fluorescence in situ hybridization followed by confocal microscopy demonstrated that homologous chromosomes associate pre-meiotically in meiocytes (germ-line cells). Surprisingly, association of homologues was observed simultaneously in all the surrounding somatic tapetum cells. Homologues failed to associate at equivalent stages in a homologue recognition mutant. These results demonstrate that the factors responsible for the recognition and association of homologues in wheat act before the onset of meiotic prophase. The observation of homologue association in somatic tapetum cells demonstrates that this process and meiotic division are separable.

A simple PCR-based method for scoring the ph1b deletion in wheat

The amplified fragment length polymorphism (AFLP) technique was used to isolate DNA sequences present in the euploid wheat Chinese Spring but not in the Chinese Spring ph1b mutant (which has a deletion of the Ph1 gene, a suppressor of homoeologous chromosome pairing). The polymorphic DNA fragments identified by AFLP were then cloned, sequenced, and used to design two primer pairs. These primers were used in a PCR-based assay to specifically amplify products from the Chinese Spring euploid but not from the ph1b mutant. This PCR assay can be carried out from extracted genomic DNA or directly from alkaline-treated wheat leaves, and the reaction products can be scored on a plus-minus basis, making the screening amenable to automation. The reliability of the assay was tested using a F1-derived doubled-haploid population of 55 lines which segregate for the ph1b deletion. This PCR-screening technique is less time and labour consuming, and more accurate and reliable, than cytologically based conventional methods.

Centromeric behaviour in wheat with high and low homoeologous chromosomal pairing

Abstract.Control of homoeologous chromosomal pairing in hexaploid wheat stems from a balance between a number of suppressor and promoter genes. This study used centromeric behaviour as a tool to investigate the mechanism. Fluorescent in situ hybridization employing centromeric and telomeric sequences as probes was applied to pollen mother cells of wheat and wheat/alien hybrids having different pairing gene combinations. It showed: association of centromeres during pre-meiotic interphase; decondensation of centromeric structure; sister chromatid disjunction of univalent chromosomes in homoeologous pairing situations at anaphase I; and centromeric stretching between univalent sister chromatids in wheat/rye hybrids deficient for pairing genes. The implications of these results are discussed.

Centromeric sites and cereal chromosome evolution

Comparative genome analysis enables the sites of centromeres, telomeres and nucleolar organiser regions to be aligned with borders that define the sets of linked genes conserved across the cereal genomes. This provides a basis for studying cereal genome evolution.