The entire mitochondrial genome was sequenced in a prostriate tick, Ixodes
hexagonus, and a metastriate tick, Rhipicephalus sanguineus. Both genomes
encode 22 tRNAs, 13 proteins, and two ribosomal RNAs. Prostriate ticks are
basal members of Ixodidae and have the same gene order as Limulus
polyphemus. In contrast, in R. sanguineus, a block of genes encoding NADH
dehydrogenase subunit 1 (ND1), tRNA(Leu)(UUR), tRNA(Leu)(CUN), 16S rDNA,
tRNA(Val), 12S rDNA, the control region, and the tRNA(Ile) and tRNA(Gln)
have translocated to a position between the tRNA(Glu) and tRNA(Phe) genes.
The tRNA(Cys) gene has translocated between the control region and the
tRNA(Met) gene, and the tRNA(Leu)(CUN) gene has translocated between the
tRNA(Ser)(UCN) gene and the control region. Furthermore, the control region
is duplicated, and both copies undergo concerted evolution. Primers that
flank these rearrangements confirm that this gene order is conserved in all
metastriate ticks examined. Correspondence analysis of amino acid and codon
use in the two ticks and in nine other arthropod mitochondrial genomes
indicate a strong bias in R. sanguineus towards amino acids encoded by
AT-rich codons.
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Using the strictly neutral model as a null hypothesis, we tested for
deviations from expected levels of nucleotide polymorphism at the alcohol
dehydrogenase locus (Adh-1) within and among four species of pocket gophers
(Geomys bursarius major, G. knoxjonesi, G. texensis llanensis, and G.
attwateri). The complete protein-encoding region was examined, and 10
unique alleles, representing both electromorphic and cryptic alleles, were
used to test hypotheses (e.g., the neutral model) concerning the
maintenance of genetic variation. Nineteen variable sites were identified
among the 10 alleles examined, including 9 segregating sites occurring in
synonymous positions and 10 that were nonsynonymous. Several statistical
methods, including those that test for within-species variation as well as
those that examine variation within and among species, failed to reject the
null hypothesis that variation (both within and between species of Geomys)
at the Adh locus is consistent with the neutral theory. However, there was
significant heterogeneity in the ratio of polymorphism to divergence across
the gene, with polymorphisms clustered in the first half of the coding
region and fixed differences clustered in the second half of the gene. Two
alternative hypotheses are discussed as possible explanations for this
heterogeneity: an old balanced polymorphism in the first half of the gene
or a recent selective sweep in the second half of the gene.
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We have initiated an investigation of the de novo purine nucleotide biosynthetic pathway in the plant Arabidopsis thaliana. Functional suppression of Escherichia coli auxotrophs allowed the direct isolation of expressed Arabidopsis leaf cDNAs. Using this approach we have successfully suppressed mutants in 4 of the 12 genes in this pathway. One of these cDNA clones, encoding 5'-phosphoribosyl-5-aminoimidazole (AIR) synthetase (PUR5) has been characterized in detail. Analysis of genomic DNA suggests that the Arabidopsis genome contains a single AIR synthetase gene. Analysis of the cDNA sequence and mRNA size suggests that this enzyme activity is encoded by a monofunctional polypeptide, similar to that of bacteria and unlike other eukaryotes. The Arabidopsis AIR synthetase contains a basic hydrophobic transit peptide consistent with transport into chloroplasts. Comparison of both the predicted amino acid and nucleotide sequence from Arabidopsis to those of eight other distant organisms suggests that the plant sequence is more similar to the bacterial sequences than to other eukaryotic sequences. This study provides the groundwork for future investigations into the regulation of de novo purine biosynthesis in plants. Additionally, we have demonstrated that functional suppression of bacterial mutants may provide a useful method for cloning a variety of plant genes. 相似文献
The mRNA encoding the soybean rbcS gene, SRS4, is degraded into a set of discrete lower-molecular-weight products in light-grown soybean seedlings and in transgenic petunia leaves. The 5'-proximal products have intact 5' ends, lack poly(A) tails, lack various amounts of 3'-end sequences, and are found at higher concentrations in the polysomal fraction. To study the mechanisms of SRS4 mRNA decay more closely, we developed a cell-free RNA degradation system based on a polysomal fraction isolated from soybean seedlings or mature petunia leaves. In the soybean in vitro degradation system, endogenous SRS4 mRNA and proximal product levels decreased over a 6-h time course. When full-length in vitro-synthesized SRS4 RNAs were added to either in vitro degradation system, the RNAs were degraded into the expected set of proximal products, such as those observed for total endogenous RNA samples. When exogenously added SRS4 RNAs already truncated at their 3' ends were added to either system, they too were degraded into the expected subset of proximal products. A set of distal fragments containing intact 3' ends and lacking various portions of 5'-end sequences were identified in vivo when the heterogeneous 3' ends of the SRS4 RNAs were removed by oligonucleotide-directed RNase H cleavage. Significant amounts of distal fragments which comigrated with the in vivo products were also observed when exogenous SRS4 RNAs were degraded in either in vitro system. These proximal and distal products lacking various portions of their 3' and 5' sequences, respectively, were generated in essentially a random order, a result supporting a nonprocessive mechanism. Tagging of the in vitro-synthesized RNAs on their 5' and 3' ends with plasmid vector sequences or truncation of the 3' end had no apparent effect on the degradation pattern. Therefore, RNA sequences and/or structures in the immediate vicinity of each 3' end point may be important in the degradation machinery. Together, these data suggest that SRS4 mRNA is degraded by a stochastic mechanism and that endonucleolytic cleavage may be the initial event. These plant in vitro systems should be useful in identifying the cis- and trans-acting factors involved in the degradation of mRNAs. 相似文献
Plants have many natural properties that make them ideally suited to clean up polluted soil, water, and air, in a process called phytoremediation. We are in the early stages of testing genetic engineering-based phytoremediation strategies for elemental pollutants like mercury and arsenic using the model plant Arabidopsis. The long-term goal is to develop and test vigorous, field-adapted plant species that can prevent elemental pollutants from entering the food-chain by extracting them to aboveground tissues, where they can be managed. To achieve this goal for arsenic and mercury, and pave the way for the remediation of other challenging elemental pollutants like lead or radionucleides, research and development on native hyperaccumulators and engineered model plants needs to proceed in at least eight focus areas: (1) Plant tolerance to toxic elementals is essential if plant roots are to penetrate and extract pollutants efficiently from heterogeneous contaminated soils. Only the roots of mercury- and arsenic-tolerant plants efficiently contact substrates heavily contaminated with these elements. (2) Plants alter their rhizosphere by secreting various enzymes and small molecules, and by adjusting pH in order to enhance extraction of both essential nutrients and toxic elements. Acidification favors greater mobility and uptake of mercury and arsenic. (3) Short distance transport systems for nutrients in roots and root hairs requires numerous endogenous transporters. It is likely that root plasma membrane transporters for iron, copper, zinc, and phosphate take up ionic mercuric ions and arsenate. (4) The electrochemical state and chemical speciation of elemental pollutants can enhance their mobility from roots up to shoots. Initial data suggest that elemental and ionic mercury and the oxyanion arsenate will be the most mobile species of these two toxic elements. (5) The long-distance transport of nutrients requires efficient xylem loading in roots, movement through the xylem up to leaves, and efficient xylem unloading aboveground. These systems can be enhanced for the movement of arsenic and mercury. (6) Aboveground control over the electrochemical state and chemical speciation of elemental pollutants will maximize their storage in leaves, stems, and vascular tissues. Our research suggests ionic Hg(II) and arsenite will be the best chemical species to trap aboveground. (7) Chemical sinks can increase the storage capacity for essential nutrients like iron, zinc, copper, sulfate, and phosphate. Organic acids and thiol-rich chelators are among the important chemical sinks that could trap maximal levels of mercury and arsenic aboveground. (8) Physical sinks such as subcellular vacuoles, epidermal trichome cells, and dead vascular elements have shown the evolutionary capacity to store large quantities of a few toxic pollutants aboveground in various native hyperaccumulators. Specific plant transporters may already recognize gluthione conjugates of Hg(II) or arsenite and pump them into vacuole.