Early changes of gene activity in developing seedlings of Arabidopsis hybrids relative to parents may contribute to hybrid vigour

Hybrid vigour (heterosis) has been used for decades in crop industries, especially in the production of maize and rice. Hybrid varieties usually exceed their parents in plant biomass and seed yield. But the molecular basis of hybrid vigour is not fully understood. In this project, we studied heterosis at early stages of seedling development in Arabidopsis hybrids derived from crossing Ler and C24 accessions. We found that early heterosis is associated with non‐additive gene expression that resulted from earlier changes in gene expression in the hybrids relative to the parents. The non‐additively expressed genes are involved in metabolic pathways, including photosynthesis, critical for plant growth. The early increased expression levels of genes involved in energy production in hybrids is associated with heterosis in the young seedlings that could be essential for biomass heterosis at later developmental stages of the plant.     

TCRJ and BCRJ gene segments contain 5′ D-segment sequences that contribute to repertoire diversity

T cell receptor (TCR) and B cell receptors (BCR) junctions, also known as the CDR3, are where the V, D, and J gene segments converge, coding for a loop structure important for contacting ligands. J segments contribute to the formation of the CDR3 loop through their 5′ ends that vary in length and show high sequence variability. The 5′ ends of J segments of TCRα genes show nucleotide sequence similarities to TCRDδ segments as high as 89% and show a preponderance of murine TCRDδ2 or human TCRDδ3 amino acid sequence similarities. Surprisingly, most of the 5′ ends of TCRJγ segments show nucleotide and amino acid sequence similarities with TCRDβ segments. All murine and human BCRJH segments and most TCRJδ segments contain amino acid sequences at their 5′ ends that resemble their own D segments, a finding that is not seen with TCRJβ segments. TCRα and TCRγ genes thus make up for their lack of separate D segments with distinct D-like segments that are built into the 5′ ends of their J segments. Additionally, in some cases, TCR and BCR genes that utilize separate D segments also receive additional D-like contributions though the 5′ ends of their J segments to add additional diversity to their CDR3 loops.     

Mimicry: developmental genes that contribute to speciation

Despite renewed interest in the role of natural selection as a catalyst for the origin of species, the developmental and genetic basis of speciation remains poorly understood. Here we describe the genetics of Müllerian mimicry in Heliconius cydno and H. melpomene (Lepidoptera: Nymphalidae), sister species that recently diverged to mimic other Heliconius. This mimetic shift was a key step in their speciation, leading to pre- and postmating isolation. We identify 10 autosomal loci, half of which have major effects. At least eight appear to be homologous with genes known to control pattern differences within each species. Dominance has evolved under the influence of identifiable "modifier" loci rather than being a fixed characteristic of each locus. Epistasis is found at many levels: phenotypic interaction between specific pairs of genes, developmental canalization due to polygenic modifiers so that patterns are less sharply defined in hybrids, and overall fitness through ecological selection against nonmimetic hybrid genotypes. Most of the loci are clustered into two genomic regions or "supergenes," suggesting color pattern evolution is constrained by preexisting linked elements that may have arisen via tandem duplication rather than having been assembled by natural selection. Linkage, modifiers, and epistasis affect the strength of mimicry as a barrier to gene flow between these naturally hybridizing species and may permit introgression in genomic regions unlinked to those under disruptive selection. Müllerian mimics in Heliconius use different genetic architectures to achieve the same mimetic patterns, implying few developmental constraints. Therefore, although developmental and genomic constraints undoubtedly influence the evolutionary process, their effects are probably not strong in comparison with natural selection.     

Structures that contribute to middle-ear admittance in chinchilla

We describe measurements of middle-ear input admittance in chinchillas (Chinchilla lanigera) before and after various manipulations that define the contributions of different middle-ear components to function. The chinchilla's middle-ear air spaces have a large effect on the low-frequency compliance of the middle ear, and removing the influences of these spaces reveals a highly admittant tympanic membrane and ossicular chain. Measurements of the admittance of the air spaces reveal that the high-degree of segmentation of these spaces has only a small effect on the admittance. Draining the cochlea further increases the middle-ear admittance at low frequencies and removes a low-frequency (less than 300 Hz) level dependence in the admittance. Spontaneous or sound-driven contractions of the middle-ear muscles in deeply anesthetized animals were associated with significant changes in middle-ear admittance.     

Cloning of wild-type Pseudomonas solanacearum phcA, a gene that when mutated alters expression of multiple traits that contribute to virulence.

Pseudomonas solanacearum undergoes a spontaneous mutation that pleiotropically reduces extracellular polysaccharide (EPS) production, endoglucanase activity, and virulence and increases motility. We refer to the process that coordinately affects these traits as phenotype conversion (PC) and the resulting mutants as PC types. Previous research with the wild-type strain AW1 suggested that inactivation of a single locus could mimic phenotype conversion (T. P. Denny, F. W. Makini, and S. M. Brumbley, Mol. Plant-Microbe Interact. 1:215-223, 1988). Additional Tn5 mutagenesis of AW1 generated three more mutants (AW1-81, AW1-82, and AW1-84) that were indistinguishable from the PC type and one slightly leaky mutant (AW1-87); all four had single insertions in the same 4.0-kilobase (kb) EcoRI fragment that were responsible for the PC-like phenotype. Another insertion mutant, AW1-83, which lacks an insertion in this 4.0-kb fragment, resembled the PC type except that it was reversibly induced to produce wild-type levels of EPS when cultured adjacent to AW1. The wild-type region containing the gene that controls traits affected by phenotype conversion in AW1, designated phcA, was cloned on a 2.2-kb DNA fragment that restored all the phcA::Tn5 mutants and 11 independent spontaneous PC-type derivatives of AW1 to wild-type status. Homology with the phcA region was found in diverse wild-type strains of P. solanacearum, although restriction fragment length polymorphisms were seen. No major DNA alterations were observed in the phcA homologous region of PC types from strain AW1 or 82N. PC types from 7 of 11 conjugal strains of P. solanacearum were restored to EPS+ by phcA from AW1; however, only some PC types of strain K60 were restored, whereas others were not. We believe that a functional phcA gene is required to maintain the wild-type phenotype in P. solanacearum, and for most strains phenotype conversion results from a loss of phcA gene expression or the function of its gene product.     

Ranking the factors that contribute to protein beta-sheet folding

The formation of beta-sheet domains in proteins involves five energetically important factors: the formation of networks of hydrogen bonds and hydrophobic faces, and the residue propensities, or preferences, to be found at the edges of the beta-sheet, to adopt the extended conformation, and to make contact with other residues. These relative energy contributions define a potential energy function. Here, we show how optimizing this potential energy function reveals the formation of hydrophobic faces as the utmost factor. The potential energy function was optimized to minimize the Z-scores of the native topologies among the exhaustive sets of over 400 different beta-sheets. These results corroborate with experimental data that showed the environment of a protein is an important modulator of beta-sheet folding. The contact propensities were found to be the least important, which could explain the poor predictive power of beta-strand alignment methods based on pair-wise contact matrices.     

E-cadherin gene promoter hypermethylation may contribute to the risk of bladder cancer among Asian populations

There are increasing scientific evidences suggesting that E-cadherin gene promoter hypermethylation may contribute to the development and progression of bladder cancer, but existing studies have yielded inconclusive results. This meta-analysis aims to assess the role of E-cadherin promoter hypermethylation in bladder carcinogenesis. We conducted an extensive literature search for relevant studies on PubMed, Embase, Web of Science, Cochrane Library, and CBM databases from their inception through May 1st, 2013. This meta-analysis was performed using the STATA 12.0 software. Crude risk ratio (RR) with 95% confidence interval (CI) was calculated. Ten clinical studies were included in this meta-analysis with a total of 620 bladder cancer samples, 199 normal adjacent samples and 131 normal urothelium tissue. Our meta-analysis revealed that the methylation frequencies in bladder cancer tissues were obviously higher than those in normal control tissues (RR = 2.02, 95%CI: 1.00–4.12, P = 0.050). Subgroup analysis by ethnicity indicated that higher methylation frequencies were observed in bladder cancer tissues among Asian populations (RR = 2.35, 95%CI: 1.11–4.95, P = 0.025), but not among Caucasian populations (RR = 1.62, 95%CI: 0.48–5.53, P = 0.439). Univariate and multivariate meta-regression analyses showed that ethnicity may be the major source of heterogeneity (P < 0.05). No publication bias was detected in this meta-analysis (P = 0.358). The present meta-analysis indicates that E-cadherin gene promoter hypermethylation may contribute to increased risk of bladder cancer among Asian populations.     

Non-gamma-proteobacteria gene islands contribute to the Xanthomonas genome

Horizontal gene transfer, a process through which genomes acquire sequences from distantly related organisms, is believed to be a major source of genetic diversity in bacteria. A central question concerning the impact of gene transfer on bacterial genome evolution is the proportion of horizontally transferred sequences within genomes. Through BLAST search, we found that the genomes of two phytopathogens, Xanthomonas campestris pv. campestris and Xanthomonas axonopodis pv. citri, have close to 40% of the genes with the highest similarity to genes from phylogenetically distant organisms (non-gamma-proteobacteria). Most of these genes are found to be contiguous in the genome, forming genome islands, which may have been transferred from other organisms. Overall, the total number of genes within genome islands corresponds to almost one quarter of the entire xanthomonad genomes. Interestingly, many of the genes in these islands are functionally related to plant pathogenesis and virulence. Thus, these results suggest that horizontally transferred genes are clustered in the genome, and may facilitate fitness in new environments, as in the case of plant-bacteria interaction.     

Metal transporters that contribute copper to metallochaperones in Saccharomyces cerevisiae

Copper metallochaperones represent a new family of soluble, low-molecular-weight proteins that function to deliver copper to specific sites within a cell. How the metallochaperones acquire their copper, however, is not known. In this study, we have conducted a survey of known metal ion transporters in bakers' yeast, Saccharomyces cerevisiae, to identify those that contribute copper to pathways involving the metallochaperones Atxlp and Lys7p. The results indicatethat, in addition to the well known Ctr1p and Ctr3p high-affinity copper transporters, the metallochaperones can acquire their copper through pathways involving the relatively non-specific divalent metal ion transporter Fet4p and the putative low-affinitycopper transporter Ctr2p. We have examined the localization of Ctr2p using an epitope tagged version of the protein and find that Ctr2p does not localize to the cell surface but may operate at the level of the vacuole to mobilize intracellular copper. Inaddition to Ctrlp, Ctr2p, Ctr3p and Fet4p, other metal transport systems can act as upstream donors of copper for the metallochaperones when copper availability in the medium is increased. Although the nature of these auxiliary systems is unknown, they do not appear to involve the yeast members of the Nramp family of divalent transporters, or uptake mechanisms that involve endocytosis. Since vastly different metal transporters located at either the cell surface or intracellular sites can all contribute copper to metallochaperones, it is unlikely that the metallochaperones directly interact with the metal transporters to obtain the metal.     

Identifying genes that contribute most to good classification in microarrays

Background  

The goal of most microarray studies is either the identification of genes that are most differentially expressed or the creation of a good classification rule. The disadvantage of the former is that it ignores the importance of gene interactions; the disadvantage of the latter is that it often does not provide a sufficient focus for further investigation because many genes may be included by chance. Our strategy is to search for classification rules that perform well with few genes and, if they are found, identify genes that occur relatively frequently under multiple random validation (random splits into training and test samples).     

Viral and host factors that contribute to pathogenicity of enterovirus 71

The single-stranded RNA virus enterovirus 71 (EV71), which belongs to the Picornaviridae family, has caused epidemics worldwide, particularly in the Asia-Pacific region. Most EV71 infections result in mild clinical symptoms, including herpangina and hand, foot and mouth disease. However, serious pathological complications have also been reported, especially for young children. The mechanisms of EV71 disease progression remain unclear. The pathogenesis of adverse clinical outcomes may relate to many factors, including cell tropism, cell death and host immune responses. This article reviews the recent advances in the identification of factors determining EV71 cell tropism, the associated mechanisms of viral infection-induced cell death and the interplay between EV71 and immunity.     

Juxtamembrane protein segments that contribute to recruitment of cholesterol into domains

We investigated the properties of several peptides with sequences related to LWYIK, a segment found in the gp41 protein of HIV and believed to play a role in sequestering this protein to a cholesterol-rich domain in the membrane. This segment fulfills the requirements to be classified as a CRAC motif that has been suggested to predict those proteins that will partition into cholesterol-rich regions of the membrane. All of the peptides were studied with the terminal amino and carboxyl groups blocked, i.e., as N-acetyl-peptide-amides. Effects of cholesterol on the intensity of W emission generally parallel DSC evidence of sequestration of cholesterol. Modeling studies indicate that all of these peptides tend to partition with their mass center at the membrane interface at the level of the hydroxyl of cholesterol. Interaction with cholesterol is dual: van der Waals interactions between mainly hydrophobic surfaces and electrostatic stabilization of the cholesterol OH group. Thus, both experiments and modeling studies indicate that the preference of CRAC motifs for cholesterol-rich domains might be related to a membrane interfacial preference of the motif, to a capacity to wrap and block the cholesterol polar OH group by H-bond interactions, and to a capacity for peptide aromatic side chains to stack with cholesterol. These results were supported by studies of single mutations in the gp41 protein of HIV-1, in which L(679) is replaced with I. Despite the similarity of the properties of these amino acid residues, this single substitution resulted in a marked attenuation of the ability of JC53-BL HeLa-based HIV-1 indicator cells to form syncytia.     

Defining the regions of Escherichia coli YidC that contribute to activity

The YidC/Oxa1/Alb3 family of proteins catalyzes membrane protein insertion in bacteria, mitochondria, and chloroplasts. In this study, we investigated which regions of the bacterial YidC protein are important for its function in membrane protein biogenesis. In Escherichia coli, YidC spans the membrane six times, with a large 319-residue periplasmic domain following the first transmembrane domain. We found that this large periplasmic domain is not required for YidC function and that the residues in the exposed hydrophilic loops or C-terminal tail are not critical for YidC activity. Rather, the five C-terminal transmembrane segments that contain the three consensus sequences in the YidC/Oxa1/Alb3 family are important for its function. However, by systematically replacing all the residues in transmembrane segment (TM) 2, TM3, and TM6 with serine and by swapping TM4 and TM5 with unrelated transmembrane segments, we show that the precise sequence of these transmembrane regions is not essential for in vivo YidC activity. Single serine mutations in TM2, TM3, and TM6 impaired the membrane insertion of the Sec-independent procoat-leader peptidase protein. We propose that the five C-terminal transmembrane segments of YidC function as a platform for the translocating substrate protein to support its insertion into the membrane.