Convergent evolution of RFX transcription factors and ciliary genes predated the origin of metazoans

<p>Abstract</p> <p>Background</p> <p>Intraflagellar transport (IFT) genes, which are critical for the development and function of cilia and flagella in metazoans, are tightly regulated by the Regulatory Factor X (RFX) transcription factors (TFs). However, how and when their evolutionary relationship was established remains unknown.</p> <p>Results</p> <p>We have identified evidence suggesting that RFX TFs and IFT genes evolved independently and their evolution converged before the first appearance of metazoans. Both ciliary genes and RFX TFs exist in all metazoans as well as some unicellular eukaryotes. However, while RFX TFs and IFT genes are found simultaneously in all sequenced metazoan genomes, RFX TFs do not co-exist with IFT genes in most pre-metazoans and thus do not regulate them in these organisms. For example, neither the budding yeast nor the fission yeast possesses cilia although both have well-defined RFX TFs. Conversely, most unicellular eukaryotes, including the green alga <it>Chlamydomonas reinhardtii</it>, have typical cilia and well conserved IFT genes but lack RFX TFs. Outside of metazoans, RFX TFs and IFT genes co-exist only in choanoflagellates including <it>M. brevicollis</it>, and only one fungus <it>Allomyces macrogynus </it>of the 51 sequenced fungus genomes. <it>M. brevicollis </it>has two putative RFX genes and a full complement of ciliary genes.</p> <p>Conclusions</p> <p>The evolution of RFX TFs and IFT genes were independent in pre-metazoans. We propose that their convergence in evolution, or the acquired transcriptional regulation of IFT genes by RFX TFs, played a pivotal role in the establishment of metazoan.</p

Functional Characterization in Caenorhabditis Elegans of Transmembrane Worm-Human Orthologs

Background: The complete genome sequences for human and the nematode Caenorhabditiselegans offer an opportunity to learn more about human gene function through functionalcharacterization of orthologs in the worm. Based on a previous genome-wide analysis of wormhumanorthologous transmembrane proteins, we selected seventeen genes to exploreexperimentally in C. elegans. These genes were selected on the basis that they all have highconfidence candidate human orthologs and that their function is unknown. We first analyzed theirphylogeny, membrane topology and domain organization. Then gene functions were studiedexperimentally in the worm by using RNA interference and transcriptional gfp reporter genefusions.Results: The experiments gave functional insights for twelve of the genes studied. For example,C36B1.12, the worm ortholog of three presenilin-like genes, was almost exclusively expressed inhead neurons, suggesting an ancient conserved role important to neuronal function. We proposea new transmembrane topology for the presenilin-like protein family. sft-4, the worm ortholog ofsurfeit locus gene Surf-4, proved to be an essential gene required for development during the larvalstages of the worm. R155.1, whose human ortholog is entirely uncharacterized, was implicated inbody size control and other developmental processes.Conclusions: By combining bioinformatics and C. elegans experiments on orthologs, we providefunctional insights on twelve previously uncharacterized human genes

The ABC transporter gene family of Caenorhabditis elegans has implications for the evolutionary dynamics of multidrug resistance in eukaryotes

BACKGROUND: Many drugs of natural origin are hydrophobic and can pass through cell membranes. Hydrophobic molecules must be susceptible to active efflux systems if they are to be maintained at lower concentrations in cells than in their environment. Multi-drug resistance (MDR), often mediated by intrinsic membrane proteins that couple energy to drug efflux, provides this function. All eukaryotic genomes encode several gene families capable of encoding MDR functions, among which the ABC transporters are the largest. The number of candidate MDR genes means that study of the drug-resistance properties of an organism cannot be effectively carried out without taking a genomic perspective. RESULTS: We have annotated sequences for all 60 ABC transporters from the Caenorhabditis elegans genome, and performed a phylogenetic analysis of these along with the 49 human, 30 yeast, and 57 fly ABC transporters currently available in GenBank. Classification according to a unified nomenclature is presented. Comparison between genomes reveals much gene duplication and loss, and surprisingly little orthology among analogous genes. Proteins capable of conferring MDR are found in several distinct subfamilies and are likely to have arisen independently multiple times. CONCLUSIONS: ABC transporter evolution fits a pattern expected from a process termed 'dynamic-coherence'. This is an unusual result for such a highly conserved gene family as this one, present in all domains of cellular life. Mechanistically, this may result from the broad substrate specificity of some ABC proteins, which both reduces selection against gene loss, and leads to the facile sorting of functions among paralogs following gene duplication

Spindle assembly checkpoint genes reveal distinct as well as overlapping expression that implicates MDF-2/Mad2 in postembryonic seam cell proliferation in Caenorhabditis elegans

Background: The spindle assembly checkpoint (SAC) delays anaphase onset by inhibiting the activity of theanaphase promoting complex/cyclosome (APC/C) until all of the kinetochores have properly attached to thespindle. The importance of SAC genes for genome stability is well established; however, the roles these genes play,during postembryonic development of a multicellular organism, remain largely unexplored.Results: We have used GFP fusions of 5’ upstream intergenic regulatory sequences to assay spatiotemporalexpression patterns of eight conserved genes implicated in the spindle assembly checkpoint function inCaenorhabditis elegans. We have shown that regulatory sequences for all of the SAC genes drive ubiquitous GFPexpression during early embryonic development. However, postembryonic spatial analysis revealed distinct, tissuespecificexpression of SAC genes with striking co-expression in seam cells, as well as in the gut. Additionally, weshow that the absence of MDF-2/Mad2 (one of the checkpoint genes) leads to aberrant number and alignment ofseam cell nuclei, defects mainly attributed to abnormal postembryonic cell proliferation. Furthermore, we showthat these defects are completely rescued by fzy-1(h1983)/CDC20, suggesting that regulation of the APC/CCDC20 bythe SAC component MDF-2 is important for proper postembryonic cell proliferation.Conclusion: Our results indicate that SAC genes display different tissue-specific expression patterns duringpostembryonic development in C. elegans with significant co-expression in hypodermal seam cells and gut cells,suggesting that these genes have distinct as well as overlapping roles in postembryonic development that may ormay not be related to their established roles in mitosis. Furthermore, we provide evidence, by monitoring seamcell lineage, that one of the checkpoint genes is required for proper postembryonic cell proliferation. Importantly,our research provides the first evidence that postembryonic cell division is more sensitive to SAC loss, in particularMDF-2 loss, than embryonic cell division

The RNA-binding protein SUP-12 controls muscle-specific splicing of the ADF/cofilin pre-mRNA in C. elegans

Tissue-specific alternative pre-mRNA splicing is essential for increasing diversity of functionally different gene products. In Caenorhabditis elegans, UNC-60A and UNC-60B, nonmuscle and muscle isoforms of actin depolymerizing factor (ADF)/cofilin, are expressed by alternative splicing of unc-60 and regulate distinct actin-dependent developmental processes. We report that SUP-12, a member of a new family of RNA recognition motif (RRM) proteins, including SEB-4, regulates muscle-specific splicing of unc-60. In sup-12 mutants, expression of UNC-60B is decreased, whereas UNC-60A is up-regulated in muscle. sup-12 mutations strongly suppress muscle defects in unc-60B mutants by allowing expression of UNC-60A in muscle that can substitute for UNC-60B, thus unmasking their functional redundancy. SUP-12 is expressed in muscle and localized to the nuclei in a speckled pattern. The RRM domain of SUP-12 binds to several sites of the unc-60 pre-mRNA including the UG repeats near the 3′-splice site in the first intron. Our results suggest that SUP-12 is a novel tissue-specific splicing factor and regulates functional redundancy among ADF/cofilin isoforms

Gene expression profiling of oxidative stress response of C. elegans aging defective AMPK mutants using massively parallel transcriptome sequencing

<p>Abstract</p> <p>Background</p> <p>A strong association between stress resistance and longevity in multicellular organisms has been established as many mutations that extend lifespan also show increased resistance to stress. AAK-2, the <it>C. elegans </it>homolog of an alpha subunit of AMP-activated protein kinase (AMPK) is an intracellular fuel sensor that regulates cellular energy homeostasis and functions in stress resistance and lifespan extension.</p> <p>Findings</p> <p>Here, we investigated global transcriptional responses of <it>aak-2 </it>mutants to oxidative stress and in turn identified potential downstream targets of AAK-2 involved in stress resistance in <it>C. elegans</it>. We employed massively parallel Illumina sequencing technology and performed comprehensive comparative transcriptome analysis. Specifically, we compared the transcriptomes of <it>aak-2 </it>and wild type animals under normal conditions and conditions of induced oxidative stress. This research has presented a snapshot of genome-wide transcriptional activities that take place in <it>C. elegans </it>in response to oxidative stress both in the presence and absence of AAK-2.</p> <p>Conclusions</p> <p>The analysis presented in this study has enabled us to identify potential genes involved in stress resistance that may be either directly or indirectly under the control of AAK-2. Furthermore, we have extended our current knowledge of general defense responses of <it>C. elegans </it>against oxidative stress supporting the function for AAK-2 in inhibition of biosynthetic processes, especially lipid synthesis, under oxidative stress and transcriptional regulation of genes involved in reproductive processes.</p