The RAD51 and DMC1 homoeologous genes of bread wheat: cloning, molecular characterization and expression analysis

<p>Abstract</p> <p>Background</p> <p>Meiotic recombination in eukaryotes requires two homologues of the <it>E. coli </it>RecA proteins: Rad51 and Dmc1. Both proteins play important roles in the binding of single stranded DNA, homology search, strand invasion and strand exchange. Meiotic recombination has been well studied in Arabidopsis, rice, maize and the orthologues of <it>RAD51 </it>and <it>DMC1 </it>have been characterized. However genetic analysis of the <it>RAD51 </it>and <it>DMC1 </it>genes in bread wheat has been hampered due to the absence of complete sequence information and because of the existence of multiple copies of each gene in the hexaploid wheat genome.</p> <p>Findings</p> <p>In this study we have identified that <it>TaRAD51 </it>and <it>TaDMC1 </it>homoeologues are located on group 7 and group 5 chromosomes of hexaploid wheat, respectively. Comparative sequence analysis of cDNA derived from the <it>TaRAD51 </it>and <it>TaDMC1 </it>homoeologues revealed limited sequence divergence at both the nucleotide and the amino acid level. Indeed, comparisons between the predicted amino acid sequences of <it>TaRAD51 </it>and <it>TaDMC1 </it>and those of other eukaryotes reveal a high degree of evolutionary conservation. Despite the high degree of sequence conservation at the nucleotide level, genome-specific primers for cDNAs of <it>TaRAD51 </it>and <it>TaDMC1 </it>were developed to evaluate expression patterns of individual homoeologues during meiosis. QRT-PCR analysis showed that expression of the <it>TaRAD51 </it>and <it>TaDMC1 </it>cDNA homoeologues was largely restricted to meiotic tissue, with elevated levels observed during the stages of prophase I when meiotic recombination occurs. All three homoeologues of both strand-exchange proteins (<it>TaRAD51 </it>and <it>TaDMC1</it>) are expressed in wheat.</p> <p>Conclusions</p> <p>Bread wheat contains three expressed copies of each of the <it>TaRAD51 </it>and <it>TaDMC1 </it>homoeologues. While differences were detected between the three cDNA homoeologues of <it>TaRAD51 </it>as well as the three homoeologues of <it>TaDMC1</it>, it is unlikely that the predicted amino acid substitutions would have an effect on the protein structure, based on our three-dimensional structure prediction analyses. There are differences in the levels of expression of the three homoeologues of <it>TaRAD51 </it>and <it>TaDMC1 </it>as determined by QRT-PCR and if these differences are reflected at the protein level, bread wheat may be more dependent upon a particular homoeologue to achieve full fertility than all three equally.</p

Fin whale (Balaenoptera physalus) mitogenomics: A cautionary tale of defining sub-species from mitochondrial sequence monophyly

The advent of massive parallel sequencing technologies has resulted in an increase of studies based upon complete mitochondrial genome DNA sequences that revisit the taxonomic status within and among species. Spatially distinct monophyly in such mitogenomic genealogies, i.e., the sharing of a recent common ancestor among con-specific samples collected in the same region has been viewed as evidence for subspecies. Several recent studies in cetaceans have employed this criterion to suggest subsequent intraspecific taxonomic revisions. We reason that employing intra-specific, spatially distinct monophyly at non-recombining, clonally inherited genomes is an unsatisfactory criterion for defining subspecies based upon theoretical (genetic drift) and practical (sampling effort) arguments. This point was illustrated by a re-analysis of a global mitogenomic assessment of fin whales, Balaenoptera physalus spp., published by Archer et al. (2013), which proposed to further subdivide the Northern Hemisphere fin whale subspecies, B. p. physalus. The proposed revision was based upon the detection of spatially distinct monophyly among North Atlantic and North Pacific fin whales in a genealogy based upon complete mitochondrial genome DNA sequences. The extended analysis conducted in this study (1676 mitochondrial control region, 162 complete mitochondrial genome DNA sequences and 20 microsatellite loci genotyped in 380 samples) revealed that the apparent monophyly among North Atlantic fin whales reported by Archer et al. (2013) to be due to low sample sizes. In conclusion, defining sub-species from monophyly (i.e., the absence of para- or polyphyly) can lead to erroneous conclusions due to relatively 'trivial' aspects, such as sampling. Basic population genetic processes (i.e., genetic drift and migration) also affect the time to the most recent common ancestor and hence the probability that individuals in a sample are monophyletic

Psychology and aggression

Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/68264/2/10.1177_002200275900300301.pd

Terman Life Cycle Study of Children with High Ability, 1922-1986

This study began by comparing a group of children with high intelligence quotients with groups of children typical of the general population, to discover similarities and differences. Research was continued from the initial collection date of 1922 through the present, with follow-ups at approximately 5-year intervals, to explore long-term development of these children. Through a process of teacher nomination and intelligence testing, 1,470 children in California with an IQ of 135 or above, were selected. In 1927-28, 58 siblings of the participants were added as a comparison group. Of the 1,528 participants in the study, 856 were male and 672 were female. The average date of birth for the sample was 1910. In 1922, parents filled out an extensive questionnaire describing the child's birth and previous health, educational and social experiences, interests, and conduct. The children's teachers filled out a similar questionnaire. The children took a battery of intelligence, achievement, and personality tests and answered questionnaires about their interests in and knowledge of many matters. Several of these procedures were repeated in 1928. In 1936, the primary source of data was questionnaires filled out by the participants and their spouses. The 1940 follow-up covered development of personality and temperament, and included an elaborate study of marital relationships. In 1950, a similar follow-up added a lengthy biographical data questionnaire. The 1945, 1955, and 1960 follow-ups were more modest, with the 1945 follow-up focusing on the effects of the WWII military effort on the participants. In 1972, 1977, and 1982, the follow-ups were oriented to problems of aging, such as life satisfactions, retirement, living arrangements, and health and vitality. The data collected in 1986 included questions about changes in well-being, time use, importance of religion, perspectives on life accomplishments, changes in family relationships, concerns and goals. The Murray Archive holds additional analogue materials for this study (microfiche copies of original record paper questionnaires from waves one through 12). Researchers seeking to access this material must apply to use the data