23 research outputs found
Potential efficacy of mitochondrial genes for animal DNA barcoding: a case study using eutherian mammals
<p>Abstract</p> <p>Background</p> <p>A well-informed choice of genetic locus is central to the efficacy of DNA barcoding. Current DNA barcoding in animals involves the use of the 5' half of the mitochondrial cytochrome oxidase 1 gene (<it>CO1</it>) to diagnose and delimit species. However, there is no compelling <it>a priori </it>reason for the exclusive focus on this region, and it has been shown that it performs poorly for certain animal groups. To explore alternative mitochondrial barcoding regions, we compared the efficacy of the universal <it>CO1 </it>barcoding region with the other mitochondrial protein-coding genes in eutherian mammals. Four criteria were used for this comparison: the number of recovered species, sequence variability within and between species, resolution to taxonomic levels above that of species, and the degree of mutational saturation.</p> <p>Results</p> <p>Based on 1,179 mitochondrial genomes of eutherians, we found that the universal <it>CO1 </it>barcoding region is a good representative of mitochondrial genes as a whole because the high species-recovery rate (> 90%) was similar to that of other mitochondrial genes, and there were no significant differences in intra- or interspecific variability among genes. However, an overlap between intra- and interspecific variability was still problematic for all mitochondrial genes. Our results also demonstrated that any choice of mitochondrial gene for DNA barcoding failed to offer significant resolution at higher taxonomic levels.</p> <p>Conclusions</p> <p>We suggest that the <it>CO1 </it>barcoding region, the universal DNA barcode, is preferred among the mitochondrial protein-coding genes as a molecular diagnostic at least for eutherian species identification. Nevertheless, DNA barcoding with this marker may still be problematic for certain eutherian taxa and our approach can be used to test potential barcoding loci for such groups.</p
Differential impact of LPG-and PG-deficient Leishmania major mutants on the immune response of human dendritic cells
<div><p>Background</p><p><i>Leishmania major</i> infection induces robust interleukin-12 (IL12) production in human dendritic cells (hDC), ultimately resulting in Th1-mediated immunity and clinical resolution. The surface of <i>Leishmania</i> parasites is covered in a dense glycocalyx consisting of primarily lipophosphoglycan (LPG) and other phosphoglycan-containing molecules (PGs), making these glycoconjugates the likely pathogen-associated molecular patterns (PAMPS) responsible for IL12 induction.</p><p>Methodology/Principal Findings</p><p>Here we explored the role of parasite glycoconjugates on the hDC IL12 response by generating <i>L</i>. <i>major</i> Friedlin V1 mutants defective in LPG alone, (FV1 <i>lpg1-</i>), or generally deficient for all PGs, (FV1 <i>lpg2-</i>). Infection with metacyclic, infective stage, <i>L</i>. <i>major</i> or purified LPG induced high levels of <i>IL12B</i> subunit gene transcripts in hDCs, which was abrogated with FV1 <i>lpg1-</i> infections. In contrast, hDC infections with FV1 <i>lpg2-</i> displayed increased <i>IL12B</i> expression, suggesting other PG-related/<i>LPG2</i> dependent molecules may act to dampen the immune response. Global transcriptional profiling comparing WT, FV1 <i>lpg1-</i>, FV1 <i>lpg2-</i> infections revealed that FV1 <i>lpg1-</i> mutants entered hDCs in a silent fashion as indicated by repression of gene expression. Transcription factor binding site analysis suggests that LPG recognition by hDCs induces IL-12 in a signaling cascade resulting in Nuclear Factor κ B (NFκB) and Interferon Regulatory Factor (IRF) mediated transcription.</p><p>Conclusions/Significance</p><p>These data suggest that <i>L</i>. <i>major</i> LPG is a major PAMP recognized by hDC to induce IL12-mediated protective immunity and that there is a complex interplay between PG-baring <i>Leishmania</i> surface glycoconjugates that result in modulation of host cellular IL12.</p></div
Lserrata_19-20
Alignment of Litoria serrata sequences less than 200 base pairs long at locus MVZ19/MVZ20 Myosin Light Chain (Intron 6)
Lserrata_CRYBA
Alignment of Litoria serrata sequences less than 200 base pairs long at locus Cryb1LS/Cryb2LS beta-crystallin
Ljungguy_39-40
Alignment of Litoria jungguy sequences less than 200 base pairs long at locus MVZ39/MVZ40 X. laevis MGC82783 protein (Intron2)
Comparative multi-locus phylogeography confirms multiple vicariance events in co-distributed rainforest frogs
Though Pleistocene refugia are frequently cited as drivers of species diversification, comparisons of molecular divergence among sister species typically indicate a continuum of divergence times from the Late Miocene, rather than a clear pulse of speciation events at the Last Glacial Maximum. Community-scale inference methods that explicitly test for multiple vicariance events, and account for differences in ancestral effective population size and gene flow, are well suited for detecting heterogeneity of species' responses to past climate fluctuations. We apply this approach to multi-locus sequence data from five co-distributed frog species endemic to the Wet Tropics rainforests of northeast Australia. Our results demonstrate at least two episodes of vicariance owing to climate-driven forest contractions: one in the Early Pleistocene and the other considerably older. Understanding how repeated cycles of rainforest contraction and expansion differentially affected lineage divergence among co-distributed species provides a framework for identifying evolutionary processes that underlie population divergence and speciation
Lrheocola_39-40
Alignment of Litoria rheocola sequences less than 200 base pairs long at locus MVZ39/MVZ40 X. laevis MGC82783 protein (Intron2)
Ldayi_39-40
Alignment for Litoria dayi sequences less than 200 base pairs long at locus MVZ 39/40 X. laevis MGC82783 protein (Intron2)
Lserrata_29-30
Alignment of Litoria serrata sequences less than 200 base pairs long at locus MVZ29/MVZ30 Y Box Binding (Intron 1)
Lnannotis_19-20
Alignment of Litoria nannotis sequences less than 200 base pairs long at locus MVZ19/MVZ20 Myosin Light Chain (Intron 6)