Characterization of T-DNA insertions in transgenic grapevines obtained by Agrobacterium-mediated transformation

T-DNA integration patterns in 49 transgenic grapevines produced via Agrobacterium-mediated transformation were analyzed. Inverse PCR (iPCR) was performed to identify T-DNA/plant junctions. Sequence comparison revealed several deletions in the T-DNA right border (RB) and left border (LB), and filler DNA and duplications or deletions of grapevine DNA at the T-DNA insertion loci. In 20 T-DNA/grapevine genome junctions microsimilarities were found associated with the joining points and in all grapevine lines microsimilarities were present near the breaking points along the 30 bases of T-DNA adjacent to the two borders. Analysis of target site preferences of T-DNA insertions indicated a non-random distribution of the T-DNA, with a bias toward the intron regions of the grapevine genes. Compositional analysis of grapevine DNA around the T-DNA insertion sites revealed an inverse relationship between the CG and AT-skews and AT rich sequences present at 300–500 bp upstream the insertion points, near the RB of the T-DNA. PCR assays showed that vector backbone sequences were integrated in 28.6% of the transgenic plants analyzed and multiple T-DNAs frequently integrated at the same position in the plant genome, resulting in the formation of tandem and inverted repeats.     

Chromosome and blood marker studies in families of patients affected by xeroderma pigmentosum and trichothiodystrophy

Chromosome and blood marker studies were performed in the families of 4 patients in which the association of 2 rare recessive Mendelian disorders, xeroderma pigmentosum (XP-D) and trichothiodystrophy (TTD), was present. Blood genotypes did not indicate any linkage with the pathologic condition, nor any segregation anomaly. Cytogenetic analysis using high-resolution banding techniques showed a normal karyotype both in the heterozygous and in the homozygous individuals. These findings lead us to exclude a cytologically detectable chromosome rearrangement, such as a microdeletion, as a possible cause of the association of XP-D and TTD in our patients.     

<Emphasis Type="Italic">Phylo-mLogo</Emphasis>: an interactive and hierarchical multiple-logo visualization tool for alignment of many sequences

Background  

When aligning several hundreds or thousands of sequences, such as epidemic virus sequences or homologous/orthologous sequences of some big gene families, to reconstruct the epidemiological history or their phylogenies, how to analyze and visualize the alignment results of many sequences has become a new challenge for computational biologists. Although there are several tools available for visualization of very long sequence alignments, few of them are applicable to the alignments of many sequences.     

Lack of involvement of known DNA methyltransferases in familial hydatidiform mole implies the involvement of other factors in establishment of imprinting in the human female germline

Background  

Differential methylation of the two alleles is a hallmark of imprinted genes. Correspondingly, loss of DNA methyltransferase function results in aberrant imprinting and abnormal post-fertilization development. In the mouse, mutations of the oocyte-specific isoform of the DNA methyltransferase Dnmt1 (Dnmt1o) and of the methyltransferase-like Dnmt3L gene result in specific failures of imprint establishment or maintenance, at multiple loci. We have previously shown in humans that an analogous inherited failure to establish imprinting at multiple loci in the female germline underlies a rare phenotype of recurrent hydatidiform mole.     

The efficiency of functional mitochondrial replacement in Saccharomyces species has directional character

Optimal interactions among nuclear and mitochondria-coded proteins are required to assemble functional complexes of mitochondrial oxidative phosphorylation. The communication between the nuclear and mitochondrial genomes has been studied by transplacement of mitochondria from related species into mutants devoid of mitochondrial DNA (rho0). Recently we have reported that the mitochondria transferred from Saccharomyces paradoxus restored partially the respiration in Saccharomyces cerevisiae rho0 mutants. Here we present evidence that the S. cerevisiae mitochondria completely salvage from respiration deficiency, not only in conspecific isolates but also in S. paradoxus. The respiratory capacity in less-related species can be recovered exclusively in the presence of S. cerevisiae chromosomes. The efficiency of the re-established oxidative phosphorylation did not rely on the presence of introns in the S. cerevisiae mitochondrial DNA. Our results suggest that, apart from evolutionary distance, the direction of mitochondrial replacement could play a significant role in installing the complete (wild-type-like) interaction between mitochondria and nuclei from different species.     

Speciation in the large-spored Metschnikowia clade and establishment of a new species, Metschnikowia borealis comb. nov

The reproductive boundaries among species in the large-spored Metschnikowia clade were studied by prototrophic recombinant selection, electrophoretic karyotyping, mitochondrial DNA restriction analysis, and DNA sequence analysis. Inviable ascospores arose from crosses between the two varieties of Metschnikowia continentalis, indicating that they should be recognized as separate species. Prototrophic recombinants were recovered from crosses between auxotrophic mutants of Metschnikowia borealis, M. continentalis, Metschnikowia lochheadii, Metschnikowia sp. UWO(PS)00-154.1, and Candida ipomoeae, showing that some genetic exchange is possible in spite of the sterility of the asci formed in interspecific crosses. Metschnikowia hawaiiensis, although capable of ascus formation when its h(-) mating type is crossed with the h(+) mating type of the other species, did not give rise to recombinants. In the other species, some recombinants acquired the ability to form asci directly from single cells. These often contained the chromosomes of both parents, suggesting formation of allodiploid hybrids. Other recombinants behaved as haploids and were similar to one parent except for having inherited the selectable wild-type allele from the other parent. In most, but not all cases, inheritance of the mitochondrial genome was uniparental and correlated with the inheritance of the nuclear chromosome complement. In some cases, what appeared to be a recombinant mitochondrial genome was observed. Phylogenies derived from the sequences of various DNA regions were not congruent, indicating that hybridization may have taken place in nature as the large-spored species diverged from their common ancestor. Further evidence that C. ipomoeae arose from a natural recombination event was obtained, but a pair of Metschnikowia species that might represent derived forms of the parents could not be identified conclusively. C. ipomoeae and most of its closely related Metschnikowia species contained a group-II intron in the mitochondrial small-subunit ribosomal gene. The intron was absent in M. borealis, M. hawaiiensis, and other species in the genus Metschnikowia.     

Genetic and environmental variation of seed weight in Trichloris species (Chloridoideae,Poaceae) and its association with seedling stress tolerance

Background: Seed weight is a key fitness-related trait associated with plant adaptation and is commonly targeted in plant breeding.

Aims: We evaluated seed weight variation within and between Trichloris crinita and Trichloris pluriflora across their geographical ranges in Argentina.

Methods: Genetic variation in seed weight was evaluated through a common garden experiment. To examine the possible role of such variation in local adaptation, we compared the seed weight of plants of populations raised in the common garden with seed weight variation and ecogeographical variables across their original habitats. We also evaluated experimentally the effects of seed weight variation upon osmotic stress tolerance at germination.

Results: Variation in seed weight existed in both species. Such variation had a genetic basis in T. crinita related to several ecogeographical variables. Larger seeds of T. crinita were associated with more stressful environments and produced larger seedlings under both osmotic stress and non-stress conditions.

Conclusions: Our results suggest that seed weight variation in T. crinita is likely adaptive, with large seed having an advantage during early developmental stages, particularly under stressful conditions. Such knowledge should prove helpful in selecting the most suitable populations for restoration and plant breeding.     

Andrenocorticotropin and β-lipotropin in the hypothalamus

Adrenocorticotropin and β-lipotropin (β-LPH) have been localized by immunoperoxidase methods in nerve cells and fibers of the hypothalamus and brain stem of the ewe. 6-μm sections were immunostained first for either ACTH or β-LPH. The reaction products and the antibody complexes were then eluted completely from the tissue, and the same section was immunostained for the second peptide. Absorption of the primary antisera with a variety of peptide fragments of ACTH and β-LPH demonstrated, immunocytochemically as well as by radioimmunoassay, that the ACTH and β-LPH antisera were directed to the COOH- and NH(2)-termini of the peptides, respectively. Neither antiserum recognized any portion of the heterologous peptide. In the sequential staining procedure on the same tissue section, preincubation of the antisera with the homologous peptide abolished the staining, whereas preincubation with the heterologous peptide did not affect it, regardless of the order followed. Every nerve cell in the arcuate nucleus that contained ACTH also contained β-LPH, but β-LPH cells appeared, probably falsely, to be twice as numerous as ACTH cells. β-LPH-positive fibers in and beyond the hypothalamus were also more numerous and stained more intensively than ACTH fibers. The salient exception was fibers in the infundibular zona externa, where the opposite was true. Our observations establish that ACTH and β-LPH are contained in the same nerve cells They stongly favor biosynthesis in brain, probably from a common precursor molecule, as has been demonstrated in the pituitary gland. The complexity of the cytologic distribution pattern described suggests that the two peptides are not processed in the same manner by the nerve cell.