Project description:This SuperSeries is composed of the SubSeries listed below. Refer to individual Series

Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:Evolution of a transcriptional regulator from a transmembrane nucleoporin

Project description:Cystic fibrosis, the most commonly inherited lethal pulmonary disorder in Caucasians, is caused by mutations in the cystic fibrosis transmembrane conductance regulator gene (CFTR). To identify genomic responses to the presence or absence of CFTR in pulmonary tissues in vivo, microarray analyses of lung mRNAs were performed on whole lung tissue from mice lacking (CFTR(-)) or expressing mouse CFTR (CFTR(+)). Whereas the histology of lungs from CFTR(-) and CFTR(+) mice was indistinguishable, statistically significant increases in the relative abundance of 29 and decreases in 25 RNAs were identified by RNA microarray analysis. Of RNAs whose expression was consistently altered by the absence of CFTR, functional classes of genes influencing gene transcription, inflammation, intracellular trafficking, signal transduction, and ion transport were identified. RNAs encoding the transcription factor CCAAT enhancer-binding protein (CEBP) delta and interleukin (IL) 1beta, both known to regulate CFTR expression, were induced, perhaps indicating adaptation to the lack of CFTR. RNAs mediating lung inflammation including calgranulin-S100 family members, IL-1beta and IL-4, were increased. Likewise, expression of several membrane transport proteins that interact directly with CFTR were increased, suggesting that CFTR-protein complexes initiate genomic responses. Absence of CFTR influenced the expression of genes modulating diverse pulmonary cell functions that may ameliorate or contribute to the pathogenesis of CF. Keywords: Genotype comparison

Project description:The Cystic Fibrosis Transmembrane Conductance Regulator protein (CFTR) is a member of the ABC transporter superfamily. CFTR is distinguished from all other members of this superfamily by its status as an ion channel as well as the presence of its unique regulatory (R) domain. We investigated the origin and subsequent evolution of the R domain along the CFTR evolutionary lineage. The R domain protein coding sequence originated via the loss of a splice donor site at the 3' end of exon 14, leading to the subsequent read-through and capture of formerly intronic sequence as novel coding sequence. Inclusion of the remaining part of the R domain coding sequence in the CFTR transcript involved a lineage-specific gain of exonic sequence with no homology to protein coding sequences outside of CFTR and loss of two exons conserved among ABC family members. These events occurred at the base of the Gnathostome evolutionary lineage ~550-650 million years ago. The apparent origination of the R domain de novo from previously non-coding sequence is consistent with its lack of sequence similarity to other domains as well as its intrinsically disordered structure, which has important implications for its function. In particular, this lack of structure may provide for a dynamic and inducible regulatory activity based on transient physical interactions with more structured domains of the protein. Since its acquisition along the CFTR evolutionary lineage, the R domain has evolved more rapidly than any other CFTR domain; however, there is no evidence for positive (adaptive) selection in the evolution of the domain. The R domain does show a distinct pattern of relative evolutionary rates compared to other CFTR domains, which sheds additional light on the connection between its function and evolution. The regulatory function of the R domain is dependent upon a fairly small number of sites that are subject to phosphorylation, and these sites were fixed very early in R domain evolution and have remained largely invariant since that time. In contrast, the rest of the R domain has been free to drift in sequence space leading to a more star-like phylogeny than seen for the other CFTR domains. The case of the R domain suggests that domain acquisition via the de novo creation of coding sequence, and the novel functional utility that such an event would seemingly entail, can be one route by which neo-functionalization is favored to occur.

Project description:Yeasts serve as hosts to several types of genetic parasites. Few studies have addressed the evolutionary trajectory of yeast genes that control the stable co-existence of these parasites with their host cell. In Saccharomyces yeasts, the retrovirus-like Ty retrotransposons must access the nucleus. We show that several genes encoding components of the yeast nuclear pore complex have experienced natural selection for substitutions that change the encoded protein sequence. By replacing these S. cerevisiae genes with orthologs from other Saccharomyces species, we discovered that natural sequence changes have affected the mobility of Ty retrotransposons. Specifically, changing the genetic sequence of NUP84 or NUP82 to match that of other Saccharomyces species alters the mobility of S. cerevisiae Ty1 and Ty3. Importantly, all tested housekeeping functions of NUP84 and NUP82 remained equivalent across species. Signatures of natural selection, resulting in altered interactions with viruses and parasitic genetic elements, are common in host defense proteins. Yet, few instances have been documented in essential housekeeping proteins. The nuclear pore complex is the gatekeeper of the nucleus. This study shows how the evolution of this large, ubiquitous eukaryotic complex can alter the replication of a molecular parasite, but concurrently maintain essential host functionalities regarding nucleocytoplasmic trafficking.

Project description:HIV-1 hijacks host classical cargo nuclear transportation, or nonclassical pathways by directly interacting with importin-β family proteins or nucleoporins for efficient pre-integration complex (PIC) nuclear import. Recently, an N-terminal truncated form of nucleoporin Pom121c (601-987 aa) was reported to inhibit HIV-1 replication. In contrast, we found that HIV-1 replication was significantly decreased in 293T and TZM-b1 cells with siRNA-mediated Pom121 knockdown. Quantitative PCR indicated that viral replication was impaired at the step of cDNA nuclear import. Furthermore, we found that karyopherin-β1 (KPNB1), which belongs to the importin-β family, interacts with Pom121 and is involved in Pom121-mediated PIC nuclear import. Rescue experiment indicated that the FG-repeats and the following α-helix in Pom121 are required for its role in HIV-1 PIC nuclear import. Taken together, our results showed that full-length Pom121 enables efficient PIC nuclear import, and suggested that this process may rely on KPNB1 dependent classical cargo nuclear transportation way.

Project description:Cystic fibrosis (CF) is the most common genetic disease among Caucasians, and accordingly the cystic fibrosis transmembrane conductance regulator (CFTR) protein has perhaps the best characterized disease mutation spectrum with more than 1,500 causative mutations having been identified. In this study, we took advantage of that wealth of mutational information in an effort to relate site-specific evolutionary parameters with the propensity and severity of CFTR disease-causing mutations. To do this, we devised a scoring scheme for known CFTR disease-causing mutations based on the Grantham amino acid chemical difference matrix. CFTR site-specific evolutionary constraint values were then computed for seven different evolutionary metrics across a range of increasing evolutionary depths. The CFTR mutational scores and the various site-specific evolutionary constraint values were compared in order to evaluate which evolutionary measures best reflect the disease-causing mutation spectrum. Site-specific evolutionary constraint values from the widely used comparative method PolyPhen2 show the best correlation with the CFTR mutation score spectrum, whereas more straightforward conservation based measures (ConSurf and ScoreCons) show the greatest ability to predict individual CFTR disease-causing mutations. While far greater than could be expected by chance alone, the fraction of the variability in mutation scores explained by the PolyPhen2 metric (3.6%), along with the best set of paired sensitivity (58%) and specificity (60%) values for the prediction of disease-causing residues, were marginal. These data indicate that evolutionary constraint levels are informative but far from determinant with respect to disease-causing mutations in CFTR. Nevertheless, this work shows that, when combined with additional lines of evidence, information on site-specific evolutionary conservation can and should be used to guide site-directed mutagenesis experiments by more narrowly defining the set of target residues, resulting in a potential savings of both time and money.

Project description:The transcriptional regulator DntR, which previously has been isolated from bacterial strains capable of degrading 2,4-dinitrotoluene (DNT), was engineered in order to improve the ability to detect DNT. A directed evolution strategy was employed, where sequence diversity first was created by random mutagenesis in three subsequent rounds, followed by recombination of previously selected mutants. A gfp gene was used as a reporter for transcriptional activity mediated by DntR and cells with higher GFP expression after addition of DNT were sorted out using fluorescence-activated cell sorting (FACS). A DntR mutant, which displayed 10 times higher induction levels than wild-type DntR in response to DNT was isolated. This mutant still maintained low levels of gfp expression in the absence of DNT. The detection limit was ∼10 µM, a 25-fold improvement compared to wild-type DntR. The functional role of some substitutions found in this clone is discussed in the framework of the structural changes observed when comparing the recently determined structures of DntR with and without bound inducer ligand.

Project description:Structural studies of the cystic fibrosis transmembrane conductance regulator (CFTR) are reviewed. Like many membrane proteins, full-length CFTR has proven to be difficult to express and purify, hence much of the structural data available is for the more tractable, independently expressed soluble domains. Therefore, this chapter covers structural data for individual CFTR domains in addition to the sparser data available for the full-length protein. To set the context for these studies, we will start by reviewing structural information on model proteins from the ATP-binding cassette (ABC) transporter superfamily, to which CFTR belongs.