Deep Whole-Genome Sequencing of 100 Southeast Asian Malays

Whole-genome sequencing across multiple samples in a population provides an unprecedented opportunity for comprehensively characterizing the polymorphic variants in the population. Although the 1000 Genomes Project (1KGP) has offered brief insights into the value of population-level sequencing, the low coverage has compromised the ability to confidently detect rare and low-frequency variants. In addition, the composition of populations in the 1KGP is not complete, despite the fact that the study design has been extended to more than 2,500 samples from more than 20 population groups. The Malays are one of the Austronesian groups predominantly present in Southeast Asia and Oceania, and the Singapore Sequencing Malay Project (SSMP) aims to perform deep whole-genome sequencing of 100 healthy Malays. By sequencing at a minimum of 30× coverage, we have illustrated the higher sensitivity at detecting low-frequency and rare variants and the ability to investigate the presence of hotspots of functional mutations. Compared to the low-pass sequencing in the 1KGP, the deeper coverage allows more functional variants to be identified for each person. A comparison of the fidelity of genotype imputation of Malays indicated that a population-specific reference panel, such as the SSMP, outperforms a cosmopolitan panel with larger number of individuals for common SNPs. For lower-frequency (<5%) markers, a larger number of individuals might have to be whole-genome sequenced so that the accuracy currently afforded by the 1KGP can be achieved. The SSMP data are expected to be the benchmark for evaluating the value of deep population-level sequencing versus low-pass sequencing, especially in populations that are poorly represented in population-genetics studies.     

Enhancer blocking and transvection at the Drosophila apterous locus

Intra- and interchromosomal interactions have been implicated in a number of genetic phenomena in diverse organisms, suggesting that the higher-order structural organization of chromosomes in the nucleus can have a profound impact on gene regulation. In Drosophila, homologous chromosomes remain paired in somatic tissues, allowing for trans interactions between genes and regulatory elements on the two homologs. One consequence of homolog pairing is the phenomenon of transvection, in which regulatory elements on one homolog can affect the expression of a gene in trans. We report a new instance of transvection at the Drosophila apterous (ap) locus. Two different insertions of boundary elements in the ap regulatory region were identified. The boundaries are inserted between the ap wing enhancer and the ap promoter and have highly penetrant wing defects typical of mutants in ap. When crossed to an ap promoter deletion, both boundary inserts exhibit the interallelic complementation characteristic of transvection. To confirm that transvection occurs at ap, we generated a deletion of the ap wing enhancer by FRT-mediated recombination. When the wing-enhancer deletion is crossed to the ap promoter deletion, strong transvection is observed. Interestingly, the two boundary elements, which are inserted ~10 kb apart, fail to block enhancer action when they are present in trans to one another. We demonstrate that this is unlikely to be due to insulator bypass. The transvection effects described here may provide insight into the role that boundary element pairing plays in enhancer blocking both in cis and in trans.     

Site-directed mutagenesis of the yeast PRP20/1SRM1 gene reveals distinct activity domains in the protein product

Prp20/Srm1, a homolog of the mammalian protein RCC1 in Saccharomyces cerevisiae, binds to double-stranded DNA (dsDNA) through a multicomponent complex in vitro. This dsDNA-binding capability of the Prp20 complex has been shown to be cell-cycle dependent; affinity for dsDNA is lost during DNA replication. By analyzing a number of temperature sensitive (ts) prp20 alleles produced in vivo and in vitro, as well as site-directed mutations in highly conserved positions in the imperfect repeats that make up the protein, we have determined a relationship between the residues at these positions, cell viability, and the dsDNA-binding abilities of the Prp20 complex. These data reveal that the essential residues for Prp20 function are located mainly in the second and the third repeats at the amino-terminus and the last two repeats, the seventh and eighth, at the carboxyl-terminus of Prp20. Carboxyl-terminal mutations in Prp20 differ from amino-terminal mutations in showing loss of dsDNA binding: their conditional lethal phenotype and the loss of dsDNA binding affinity are both suppressible by overproduction of Gsp1, a GTP-binding constituent of the Prp20 complex, homologous to the mammalian protein TC4/Ran. Although wild-type Prp20 does not bind to dsDNA on its own, two mutations in conserved residues were found that caused the isolated protein to bind dsDNA. These data imply that, in situ, the other components of the Prp20 complex regulate the conformation of Prp20 and thus its affinity for dsDNA. Gsp1 not only influences the dsDNA-binding ability of Prp20 but it also regulates other essential function(s) of the Prp20 complex. Overproduction of Gsp1 also suppresses the lethality of two conditional mutations in the penultimate carboxyl-terminal repeat of Prp20, even though these mutations do not eliminate the dsDNA binding activity of the Prp20 complex. Other site-directed mutants reveal that internal and carboxyl-terminal regions of Prp20 that lack homology to RCC1 are dispensable for dsDNA binding and growth.     

Univariate Community Assembly Analysis (UniCAA): Combining hierarchical models with null models to test the influence of spatially restricted dispersal,environmental filtering,and stochasticity on community assembly

Identifying the influence of stochastic processes and of deterministic processes, such as dispersal of individuals of different species and trait‐based environmental filtering, has long been a challenge in studies of community assembly. Here, we present the Univariate Community Assembly Analysis (UniCAA) and test its ability to address three hypotheses: species occurrences within communities are (a) limited by spatially restricted dispersal; (b) environmentally filtered; or (c) the outcome of stochasticity—so that as community size decreases—species that are common outside a local community have a disproportionately higher probability of occurrence than rare species. The comparison with a null model allows assessing if the influence of each of the three processes differs from what one would expect under a purely stochastic distribution of species. We tested the framework by simulating “empirical” metacommunities under 15 scenarios that differed with respect to the strengths of spatially restricted dispersal (restricted vs. not restricted); habitat isolation (low, intermediate, and high immigration rates); and environmental filtering (strong, intermediate, and no filtering). Through these tests, we found that UniCAA rarely produced false positives for the influence of the three processes, yielding a type‐I error rate ≤5%. The type‐II error rate, that is, production of false negatives, was also acceptable and within the typical cutoff (20%). We demonstrate that the UniCAA provides a flexible framework for retrieving the processes behind community assembly and propose avenues for future developments of the framework.     

Brca1 and differentiation

Breast cancer is one of the most frequent malignancies affecting women. The human breast cancer gene 1 (BRCA1) gene is mutated in a distinct proportion of hereditary breast and ovarian cancers. Tumourigenesis in individuals with germline BRCA1 mutations requires somatic inactivation of the remaining wild-type allelle. Although, this evidence supports a role for BRCA1 as a tumour suppressor, the mechanisms through which its loss leads to tumourigenesis remain to be determined. Neither the expression pattern nor the described functions of human BRCA1 and murine breast cancer gene 1 (Brca1) can explain the specific association of mutations in this gene with the development of breast and ovarian cancer. Investigation of the role of Brca1 in normal cell differentiation processes might provide the basis to understand the tissue-restricted properties.     

Distribution, expression, and motif variability of ankyrin domain genes in Wolbachia pipientis

The endosymbiotic bacterium Wolbachia pipientis infects a wide range of arthropods, in which it induces a variety of reproductive phenotypes, including cytoplasmic incompatibility (CI), parthenogenesis, male killing, and reversal of genetic sex determination. The recent sequencing and annotation of the first Wolbachia genome revealed an unusually high number of genes encoding ankyrin domain (ANK) repeats. These ANK genes are likely to be important in mediating the Wolbachia-host interaction. In this work we determined the distribution and expression of the different ANK genes found in the sequenced Wolbachia wMel genome in nine Wolbachia strains that induce different phenotypic effects in their hosts. A comparison of the ANK genes of wMel and the non-CI-inducing wAu Wolbachia strain revealed significant differences between the strains. This was reflected in sequence variability in shared genes that could result in alterations in the encoded proteins, such as motif deletions, amino acid insertions, and in some cases disruptions due to insertion of transposable elements and premature stops. In addition, one wMel ANK gene, which is part of an operon, was absent in the wAu genome. These variations are likely to affect the affinity, function, and cellular location of the predicted proteins encoded by these genes.     

2-Cysteine Peroxiredoxins and Thylakoid Ascorbate Peroxidase Create a Water-Water Cycle That Is Essential to Protect the Photosynthetic Apparatus under High Light Stress Conditions

Different peroxidases, including 2-cysteine (2-Cys) peroxiredoxins (PRXs) and thylakoid ascorbate peroxidase (tAPX), have been proposed to be involved in the water-water cycle (WWC) and hydrogen peroxide (H₂O₂)-mediated signaling in plastids. We generated an Arabidopsis (Arabidopsis thaliana) double-mutant line deficient in the two plastid 2-Cys PRXs (2-Cys PRX A and B, 2cpa 2cpb) and a triple mutant deficient in 2-Cys PRXs and tAPX (2cpa 2cpb tapx). In contrast to wild-type and tapx single-knockout plants, 2cpa 2cpb double-knockout plants showed an impairment of photosynthetic efficiency and became photobleached under high light (HL) growth conditions. In addition, double-mutant plants also generated elevated levels of superoxide anion radicals, H₂O₂, and carbonylated proteins but lacked anthocyanin accumulation under HL stress conditions. Under HL conditions, 2-Cys PRXs seem to be essential in maintaining the WWC, whereas tAPX is dispensable. By comparison, this HL-sensitive phenotype was more severe in 2cpa 2cpb tapx triple-mutant plants, indicating that tAPX partially compensates for the loss of functional 2-Cys PRXs by mutation or inactivation by overoxidation. In response to HL, H₂O₂- and photooxidative stress-responsive marker genes were found to be dramatically up-regulated in 2cpa 2cpb tapx but not 2cpa 2cpb mutant plants, suggesting that HL-induced plastid to nucleus retrograde photooxidative stress signaling takes place after loss or inactivation of the WWC enzymes 2-Cys PRX A, 2-Cys PRX B, and tAPX.Plants are frequently exposed to different abiotic stresses, including high light (HL), UV irradiation, heat, cold, and drought. A component common to these stresses is the rapid formation of reactive oxygen species (ROS) as the result of metabolic dysbalances. A major ROS produced under moderate light (ML) and, in particular, HL photooxidative stress conditions was shown to be singlet oxygen, ¹O₂, that is produced in illuminated chloroplasts predominantly at the PSII (Triantaphylidès et al., 2008). Most of the singlet oxygen is quenched by carotenoids and tocopherols or reacts with galactolipids in thylakoid membranes, yielding galactolipid hydroperoxides (Zoeller et al., 2012; Farmer and Mueller, 2013). In addition, superoxide radicals, O₂·⁻, are produced predominantly at the PSI and rapidly dismutate to hydrogen peroxide (H₂O₂) either spontaneously or because of being catalyzed by superoxide dismutase. Hence, lipid peroxides and H₂O₂ are produced close to the photosystems and may damage thylakoid proteins. In this context, 2-Cys peroxiredoxin (PRX) enzymes have been implicated in the reductive detoxification of lipid peroxides and H₂O₂ (König et al., 2002).During photosynthesis, light energy absorbed by PSII is used to split water molecules, and the electrons are channeled from PSII through PSI to ferredoxin (Fd). As a result, electrons flow from water to Fd. The main electron sink reaction is the Fd NADP oxidoreductase-catalyzed production of NADPH that functions as an electron donor to reduce carbon dioxide to sugars. Under HL conditions, excessive excitation energy is dissipated into heat, which was indicated by nonphotochemical quenching of chlorophyll fluorescence. In addition, excessive photosynthetic electrons can be donated from PSI to O₂, yielding O₂·⁻ (Miyake, 2010). This process, the Mehler reaction, creates an alternative electron sink and electron flow. Superoxide anion radicals, O₂·⁻, can be dismutated to O₂ and H₂O₂ by a thylakoid-attached copper/zinc superoxide dismutase (Cu/ZnSOD; Rizhsky et al., 2003). H₂O₂ can then be reduced to water by peroxidases. As a result, O₂ molecules originating from the water-splitting process at PSII are reduced to water by electrons originating from PSI. This process is termed the water-water cycle (WWC) that is thought to protect the photosynthetic apparatus from excessive light and alleviate photoinhibition.In the classical WWC, the Mehler-ascorbate peroxidase (MAP) pathway, ascorbate peroxidases (APXs) have been considered as key enzymes in the reductive detoxification of H₂O₂ in chloroplasts (Kangasjärvi et al., 2008). APXs reduce H₂O₂ to water and oxidize ascorbate to monodehydroascorbate radicals. NADPH functions as an electron donor to regenerate ascorbate by monodehydroascorbate radical reductase. There are two functional APX homologs in plastids: a 33-kD stromal ascorbate peroxidase (sAPX) and a 38-kD thylakoid ascorbate peroxidase (tAPX). The latter tAPX is thought to reside close to the site of H₂O₂ generation at PSI. Surprisingly, knockout-tAPX mutants as well as double mutants lacking both the tAPX and the sAPX exhibited no visible symptoms of stress after long-term (1–14 d) HL (1.000 µmol photons m⁻² s⁻¹) exposure (Giacomelli et al., 2007; Kangasjärvi et al., 2008; Maruta et al., 2010). Moreover, the photosynthetic efficiency of PSII (as judged by the maximum photochemical efficiency of PSII in the dark-adapted state [F_v/F_m]), H₂O₂ production, antioxidant levels (ascorbate, glutathione, and tocopherols), protein oxidation, and anthocyanin accumulation were similar between light-stressed mutant and wild-type plants. Hence, other H₂O₂ detoxification mechanisms can efficiently compensate for the lack of the sAPX and tAPX detoxification system.In addition to APX, glutathione peroxidases and PRXs may reduce H₂O₂ to water. It has been postulated that, in the chloroplast, two highly homologous thylakoid-associated 2-Cys peroxiredoxins (2CPs), 2CPA and 2CPB, can create an alternative ascorbate-independent WWC (Dietz et al., 2006). In support of this concept, HL stress-acclimated tapx sapx double-mutant plants showed increased levels of 2-Cys PRX compared with wild-type plants (Kangasjärvi et al., 2008). Because the two plastidial 2CPA and 2CPB dynamically interact with the stromal side of thylakoid membranes and are capable of reducing peroxides, 2-Cys PRX enzymes may be involved in both H₂O₂ detoxification and reduction of lipid peroxides in thylakoids (König et al., 2002).The reaction mechanism of 2-Cys PRX is highly conserved and involves a Cys residue, which becomes transiently oxidized to sulphenic acid (termed the peroxidatic Cys residue), thereby reducing H₂O₂ to water. The sulphenic acid is subsequently attacked by a second Cys residue, termed resolving Cys residue, yielding an intermolecular disulfide bridge and water (Dietz, 2011).At high peroxide concentrations, the peroxidase function of 2-Cys PRX becomes inactivated through overoxidation, and excess H₂O₂ may function as a redox signal (Puerto-Galán et al., 2013). It has been postulated that 2-Cys PRXs function as a floodgate that allows H₂O₂ signaling only under oxidative stress conditions (Wood et al., 2003; Dietz, 2011; Puerto-Galán et al., 2013). In addition to its function as peroxidase, 2-Cys PRX may also serve as proximity-based thiol oxidases and chaperones (König et al., 2013).The genome of Arabidopsis (Arabidopsis thaliana) contains two 2CP genes. To study 2-Cys PRX function, transgenic plants with reduced 2-Cys PRX levels were generated by antisense suppression (Baier et al., 2000) as well as crossing of transfer DNA (T-DNA) insertion mutants (Pulido et al., 2010). The T-DNA insertion double mutant was shown to contain less than 5% of the wild-type content of 2CPA and no 2CPB. Hence, full knockout lines lacking both 2-Cys PRXs have not yet been established. Under standard growth conditions, 2-Cys PRX double mutants (similar to plastid APX-deficient plants) also did not show a photooxidative stress phenotype that might be because of compensation by alternative H₂O₂ reduction systems (Pulido et al., 2010). Because of the lack of a clear phenotype of the 2-Cys PRX double-knockdown mutant under ML conditions, the physiological functions of 2CPA and 2CPB remain to be elucidated.The main aim of this study was to identify the physiological function of 2CPA and 2CPB under HL stress conditions, when the WWC is of particular importance in protecting the photosynthetic apparatus from photooxidative damage. We investigated mutants completely deficient in 2-Cys PRX (2cpa 2cpb) or tAPX (tapx) and in addition, 2cpa 2cpb tapx triple knockout plants to study the extent of the functional overlap between these enzymes. Results suggest that 2-Cys PRXs are involved in a 2-Cys PRX-dependent WWC that seems to be more important in protecting the photosynthetic apparatus than the tAPX-dependent WWC, the MAP cycle.