322 research outputs found
Chromosome and DNA methylation dynamics during meiosis in autotetraploid Arabidopsis arenosa
Variation in chromosome number due to
polyploidy can seriously compromise meiotic stability. In
autopolyploids, the presence of more than two homologous
chromosomes may result in complex pairing patterns
and subsequent anomalous chromosome
segregation. In this context, chromocenter, centromeric,
telomeric and ribosomal DNA locus topology and DNA
methylation patterns were investigated in the natural
autotetraploid, Arabidopsis arenosa. The data show that
homologous chromosome recognition and association
initiates at telomeric domains in premeiotic interphase,
followed by quadrivalent pairing of ribosomal 45S RNA
gene loci (known as NORs) at leptotene. On the other hand, centromeric regions at early leptotene show pairwise
associations rather than associations in fours. These
pairwise associations are maintained throughout prophase
I, and therefore likely to be related to the diploid-like
behavior of A. arenosa chromosomes at metaphase I,
where only bivalents are observed. In anthers, both cells
at somatic interphase as well as at premeiotic interphase
show 5-methylcytosine (5-mC) dispersed throughout the
nucleus, contrasting with a preferential co-localization
with chromocenters observed in vegetative nuclei. These
results show for the first time that nuclear distribution
patterns of 5-mC are simultaneously reshuffled in meiocytes
and anther somatic cells. During prophase I, 5-mC
is detected in extended chromatin fibers and chromocenters
but interestingly is excluded from the NORs what
correlates with the pairing patter
Linkage map construction involving a reciprocal translocation
This paper is concerned with a novel statistical–genetic approach for the construction of linkage maps in populations obtained from reciprocal translocation heterozygotes of barley (Hordeum vulgare L.). Using standard linkage analysis, translocations usually lead to ‘pseudo-linkage’: the mixing up of markers from the chromosomes involved in the translocation into a single linkage group. Close to the translocation breakpoints recombination is severely suppressed and, as a consequence, ordering markers in those regions is not feasible. The novel strategy presented in this paper is based on (1) disentangling the “pseudo-linkage” using principal coordinate analysis, (2) separating individuals into translocated types and normal types and (3) separating markers into those close to and those more distant from the translocation breakpoints. The methods make use of a consensus map of the species involved. The final product consists of integrated linkage maps of the distal parts of the chromosomes involved in the translocation
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