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Haploid Genome (haploid + genome)

Distribution by Scientific Domains
Life Sciences100%

Selected Abstracts

Isolation and molecular characterization of Musca domestica delta-9 desaturase sequences

INSECT MOLECULAR BIOLOGY, Issue 6 2002
A. L. Eigenheer
Abstract We have isolated fatty acyl-CoA desaturase cDNA (Mdomd9) and genomic sequences from the housefly, Musca domestica. Two ,1.66 kb cDNAs were recovered. They had identical coding regions and 3, untranslated regions (UTRs), but differed in their 5, UTRs. The open reading frame encodes a 380 amino acid (aa) protein with 82% identity to Drosophila melanogaster desat1, and significant (> 50%) identity with other insect delta-9 desaturases. Functional analyses in a yeast expression system confirmed the cDNA encodes a ,9 desaturase. Northern analysis indicated two transcripts of 1.7 and 2.9 kb that hybridized specifically to the open reading frame. PCR amplification of genomic templates revealed three intron sites that are conserved among other insect species. Southern analysis of genomic DNA indicated at least two desaturase gene copies per haploid genome. There is a high degree of polymorphism, most of which appears to be due to variable intron sequences; curiously, individual flies had varying morphs of intron II and intron III. Together, the data suggest that there are more ,9 desaturase alleles within the population studied than there are loci within the genome, and support other studies suggesting that insect fatty acyl-CoA desaturases are a dynamically evolving gene family. [source]

A uniquely high number of ftsZ genes in the moss Physcomitrella patens

PLANT BIOLOGY, Issue 5 2009
A. Martin
Abstract Plant FtsZ proteins are encoded by two small nuclear gene families (FtsZ1 and FtsZ2) and are involved in chloroplast division. From the moss Physcomitrella patens, four FtsZ proteins, two in each nuclear gene family, have been characterised and described so far. In the recently sequenced P. patens genome, we have now found a fifth ftsZ gene. This novel gene has a genomic structure similar to PpftsZ1-1. According to phylogenetic analysis, the encoded protein is a member of the FtsZ1 family, while PpFtsZ1-2, together with an orthologue from Selaginella moellendorffii, forms a separate clade. Further, this new gene is expressed in different gametophytic tissues and the encoded protein forms filamentous networks in chloroplasts, is found in stromules, and acts in plastid division. Based on all these results, we have renamed the PpFtsZ proteins of family 1 and suggest the existence of a third FtsZ family. No species is known to encode more FtsZ proteins per haploid genome than P. patens. [source]

The study of introgressive lines of Triticum aestivum × Aegilops speltoides by in situ and SSR analyses

PLANT BREEDING, Issue 3 2004
I. G. Adonina
Abstract Fluorescence in situ hybridization (FISH) with a genome-specific repeat, Spelt1, and wheat simple sequence repeat (SSR) markers were used to analyse the chromosome constitution of two Triticum aestivum×Aegilops speltoides introgressive lines. The lines 170/98i and 178/98i carried one and two subtelomeric regions of Ae. speltoides (per haploid genome), respectively, marked by Spelt1 repeats according to FISH data. SSR analysis detected homoeologous substitution of wheat chromosome 7D with Ae. speltoides chromosome 7S in the lines 178/98i and 170/98i as well as the assumed terminal translocation in the short arm of chromosome 3A in the line 178/98i. Anthocyanin pigmentation of the coleoptiles was found in the lines 170/98i and 178/98i and resulted from the 7S (7D) substitution. It was demonstrated that Spelt1 could be effectively used for the rapid identification (without DNA isolation) of terminal translocations of T. aestivum×Ae. speltoides introgressive lines as well as for further analysis of the stability of the hybrid plants. [source]

PROPOSAL OF ECTOCARPUS SILICULOSUS (ECTOCARPALES, PHAEOPHYCEAE) AS A MODEL ORGANISM FOR BROWN ALGAL GENETICS AND GENOMICS,

JOURNAL OF PHYCOLOGY, Issue 6 2004
Akira F. Peters
The emergence of model organisms that permit the application of a powerful combination of genomic and genetic approaches has been a major factor underlying the advances that have been made in the past decade in dissecting the molecular basis of a wide range of biological processes. However, the phylogenetic distance separating marine macroalgae from these model organisms, which are mostly from the animal, fungi, and higher plant lineages, limits the latters' applicability to problems specific to macroalgal biology. There is therefore a pressing need to develop similar models for the macroalgae. Here we describe a survey of potential model brown algae in which particular attention was paid to characteristics associated with a strong potential for genomic and genetic analysis, such as a small nuclear genome size, sexuality, and a short life cycle. Flow cytometry of nuclei isolated from zoids showed that species from the Ectocarpales possess smaller haploid genomes (127,290 Mbp) than current models among the Laminariales (580,720 Mbp) and Fucales (1095,1271 Mbp). Species of the Ectocarpales may complete their life histories in as little as 6 weeks in laboratory culture and are amenable to genetic analyses. Based on this study, we propose Ectocarpus siliculosus (Dillwyn) Lyngbye as an optimal choice for a general model organism for the molecular genetics of the brown algae. [source]