A Single Amino Acid Substitution in a Segment of the CA Protein within Gag That Has Similarity to Human Immunodeficiency Virus Type 1 Blocks Infectivity of a Human Endogenous Retrovirus K Provirus in the Human Genome

Human endogenous retrovirus K (HERV-K) is the most intact retrovirus in the human genome. However, no single HERV-K provirus in the human genome today appears to be infectious. Since the Gag protein is the central component for the production of retrovirus particles, we investigated the abilities of Gag from two HERV-K proviruses to support production of virus-like particles and viral infectivity. HERV-K113 has full-length open reading frames for all viral proteins, while HERV-K101 has a full-length gag open reading frame and is expressed in human male germ cell tumors. The Gag of HERV-K101 allowed production of viral particles and infectivity, although at lower levels than observed with a consensus sequence Gag. Thus, including HERV-K109, at least two HERV-K proviruses in human genome today have functional Gag proteins. In contrast, HERV-K113 Gag supported only very low levels of particle production, and no infectivity was detectable due to a single amino acid substitution (I516M) near the extreme C terminus of the CA protein within Gag. The sequence of this portion of HERV-K CA showed similarities to that of human immunodeficiency virus type 1 and other primate immunodeficiency viruses. The extreme C terminus of CA may be a general determinant of retrovirus particle production. In addition, precise mapping of the defects in HERV-K proviruses as was done here identifies the key polymorphisms that need to be analyzed to assess the possible existence of infectious HERV-K alleles within the human population.Approximately 8% of the human genome comprises endogenous retroviruses (ERVs) (33, 59). These viruses infect germ lineage cells and thereby enter the genome of the host species. Thus, endogenous proviruses (the integrated form of retroviral DNA) are transmitted from parents to offspring in genomic DNA. If ERV genomes are intact, viral particles may be generated that can reinfect the germ line and form proviruses at new positions in the host genome. However, ERVs are subject to the same mutagenic processes over evolutionary time as any cellular gene. In the absence of selective pressure on the host to maintain intact viral genomes, endogenous retroviral proviruses accrue mutations over evolutionary time that inactivate viral infectivity. Most of the ERVs in the human genome have converted to solo long terminal repeats (solo LTRs), which are the product of homologous recombination between LTRs at the ends of the complete viral genome. Other types of mutations, such as nucleotide substitutions, insertions, and deletions, can also affect ERV proviruses, and many of the retroviral proviruses in the human genome have been inactivated by such mutations, which created premature stop codons or frameshifts in viral open reading frames (ORFs). The vast majority of the ERVs present in humans today (and perhaps all of them) have incurred mutations that inactivated viral infectivity.One provirus that exists in the genome of approximately 20% of humans, human ERV K113 (HERV-K113, referred to here as K113), has full-length ORFs for all viral proteins (8, 63). However, this provirus does not appear to be infectious, as the pol and env genes of K113 do not support infectivity (9, 19, 20). K113 belongs to a subset of HERV-K called HML-2 (43). Since the human and chimpanzee lineages diverged about 6 million years ago (52), the only proviruses that entered the genome of the human lineage belong to this subgroup, although other members of this subgroup entered the germ line prior to the divergence of the human and chimpanzee lineages (8, 27, 44, 63). The human-specific proviruses of this subgroup are the most intact retroviruses in the human genome. Infectious HERV-K particles have been generated using two different approaches based on their DNA sequences. HERV-KCON (K-CON) was constructed based on the consensus sequence of human-specific HERV-K proviruses (34). Infectious HERV-K particles were also generated by combining pieces from three separate proviruses, HERV-K109 (K109) gag-pro, HERV-K115 pol, and HERV-K108 (K108) env (20). Thus, it may be that no single provirus is infectious, but recombination and/or genetic complementation among multiple genomic proviruses may be required to produce infectious HERV-K particles. This raises the questions of whether multiple functional HERV-K components exist in the human genome today and how close these components are to being able to form a functional viral genome that might be capable of reinfecting human cells.To begin addressing these issues, we examined two of the full-length HERV-K gag genes that exist in the human genome today. Like all retroviruses, HERV-K contains the four genes necessary for viral replication: gag, pro, pol, and env. The human-specific HERV-K proviruses exist in two forms, type I and type II (38, 39). The type II proviruses contain gag, pro, pol, and env plus an accessory gene, rec, that encodes a protein (Rec) that functions in nuclear export of unspliced viral RNA in a manner analogous to that of human immunodeficiency virus type 1 (HIV-1) Rev (12, 40, 41, 65, 66). In type I proviruses, the pol and env genes are fused in frame by a 292-bp deletion that includes the first coding exon of rec, and the viruses encode an additional protein called Np9 (5, 48). The gag genes are relevant to whether HERV-K components in the human genome today might form an infectious virus, as the Gag protein is sufficient to produce virus-like particles (VLPs) in the absence of other viral proteins (4). Formation of such particles is an essential step for subsequent viral replication. Therefore, we decided to investigate whether Gag proteins from K113 and a second provirus, HERV-K101 (K101), are active in functional assays.     

Electron competition process in respiratory chain: Regulatory mechanisms and physiological functions

In mitochondria isolated from the yeast Saccharomyces cerevisiae, under non-phosphorylating conditions, we have previously shown that there is a right of way for electrons coming from the external NADH dehydrogenase, Nde1p. In this work, we show that the electron competition process is identical under more physiological conditions i.e. oxidative phosphorylation. Such a competition generates a priority for cytosolic NADH reoxidation. Furthermore, this electron competition process is associated with an energy wastage (the “active leak”) that allows an increase in redox equivalent oxidation when the redox pressure increases. When this redox pressure is decreased, i.e. under phosphorylating conditions, most of this energy wastage is alleviated. By studying mutant strains affected either in respiratory chain supramolecular organization or in electron competition activity, we show that the respiratory chain supramolecular organization is not responsible for the electron competition processes. Moreover, we show two distinct relationships between the respiratory rate and the quinone redox state that seem to indicate two quinone pools that are involved in the electron right of way. Indeed, the more reduced pool would be associated to the electron right of way for the external dehydrogenases whereas the less reduced pool would be associated to the electron right of way for the internal dehydrogenases.     

Novel Assay To Assess Permissiveness of a Soil Microbial Community toward Receipt of Mobile Genetic Elements

There is a wealth of evidence indicating that mobile genetic elements can spread in natural microbial communities. However, little is known regarding the fraction of the community that actually engages in this behavior. Here we report on a new approach to quantify the fraction of a bacterial community that is able to receive and maintain an exogenous conjugal plasmid termed community permissiveness. Conjugal transfer of a broad-host-range plasmid labeled with a zygotically inducible green fluorescent protein (RP4::gfp) from a donor strain (Pseudomonas putida) to a soil bacterial suspension was examined. The mixture of cells was incubated on membrane filters supported by different solid media. Plasmid transfer was scored by in situ visualization of green fluorescent transconjugant microcolonies, and host range was determined by traditional plating or microcolony isolation by using a micromanipulator. Among the conditions tested, the highest plasmid transfer incidence (approximately 1 transfer per 10⁴ soil bacteria) was measured after 48 h of incubation on either a 10% soil extract or a 10-fold diluted R2A medium. Stereomicroscopy combined with image analysis allowed easy examination and enumeration of green fluorescent microcolonies. In all experiments, however, stereomicroscopy consistently underestimated the number of conjugation events (approximately 10-fold) in comparison to confocal laser scanning microscopy. The plasmid host range was broad and included bacteria belonging to the Alphaproteobacteria, Betaproteobacteria, and Gammaproteobacteria classes of proteobacteria. The isolation of transconjugant microcolonies by micromanipulation greatly extended the estimated plasmid host range among soil bacteria. The new approach can be applied to examine the permissiveness of various communities toward receipt of different mobile elements.Horizontal gene transfer (HGT) among bacterial populations may provide microbial communities with genetic variability to adapt to environmental changes. Conjugation, which consists of the transfer of bacterial mobile genetic elements (e.g., plasmids, conjugative transposons, etc.), is often believed to be the most important process for short-term microbial adaptation (27). The extent of conjugal exchange of genetic elements among environmental bacteria depends on various biotic and abiotic factors (13, 23, 31), including bacterial relatedness (15), plasmid host type (5), and conjugative element type (4). The capacity and diversity of bacteria in a microbial community taking part in exchange of mobile genetic elements are poorly understood, primarily due to the traditional use of biased cultivation-based methods (25, 30).Recently, methods relying on fluorescent reporter genes (e.g., gfp) in combination with confocal microscopy and flow cytometry have been developed, allowing for in situ visualization and quantification of plasmid transfer (7, 20) and host range examination (17) in indigenous microbial communities. These methods allow, for the first time, detection of HGT in indigenous organisms with unknown phenotypes, reducing the cultivation bias. However, they will mainly detect transfer to the most abundant recipients and are further biased when transconjugant division is possible. Therefore, the actual fraction of a microbial community that is actively engaged in uptake and exchange of a mobile genetic element is typically not measured.We have developed a new approach to quantify the fraction of a soil microbial community that is able to receive an exogenous conjugal plasmid termed soil community permissiveness. Transfer and maintenance of a green fluorescence reporter gene (gfp)-tagged plasmid to indigenous soil bacteria are examined in solid-surface matings. Conjugation events and recipient morphology are visualized in situ and quantified by minimal-cultivation methods, confocal laser scanning microscopy (CLSM), and stereomicroscopy (SM), and the phylogeny of isolated transconjugant bacteria was determined.     

Proton NMR study of myoglobin reconstituted with 3, 7-diethyl-2, 8-dimethyl iron porphyrin: remarkable influence of peripheral substitution on heme rotation

The iron complex of 3,7-diethyl-2,8-dimethylporphyrin was incorporated into horse heart apomyoglobin to investigate the influence of peripheral substitution on artificial heme rotation. The hyperfine-shifted 1H NMR spectrum of the reconstituted deoxymyoglobin (rMb) revealed the proximal imidazole N-H resonance at 82.5 ppm to indicate the formation of the Fe--N (His93) bond. The pyrrole-protons of the hemin of myoglobin in the absence of external ligand appeared as four resonances between -10 and -18 ppm, indicating a mainly low-spin ferric hemin, with a ligated distal histidine (His64). This also indicates the lost of the symmetry of the hemin, according to an absence of free rotation of the prosthetic group. The 1H NMR spectrum of reconstituted rMbCO revealed a set of four pyrrole-protons and a set of four meso-protons. Accordingly, the prosthetic group without acid side chains interacts specifically with the surrounding globin showing a unique heme orientation in the 1H NMR time-scale, despite the presence of only four alkyl substituents on the porphine ring. This also suggests that two ethyl groups are large enough to avoid the free rotation movement of the heme.     

Production of Resveratrol in Recombinant Microorganisms

Resveratrol production in Saccharomyces cerevisiae was compared to that in Escherichia coli. In both systems, 4-coumarate:coenzyme A ligase from tobacco and stilbene synthase from grapes were expressed. When p-coumaric acid was used as the precursor, resveratrol accumulations in the culture medium were observed to be comparable in E. coli (16 mg/liter) and yeast (6 mg/liter).     

Development of selective inhibitors and substrate of matrix metalloproteinase-12

Four phosphinic peptide libraries with compounds having the general formula p-Br-Ph-(PO2-CH2)-Xaa'-Yaa'-Zaa'-NH2 have been prepared and screened against 10 matrix metalloproteinases (MMPs). We identified two phosphinic peptides with Ki values of 0.19 and 4.4 nM toward MMP-12 (macrophage elastase) that are more than 2-3 orders of magnitude less potent toward the other MMPs tested. These highly selective MMP-12 inhibitors contain a Glu-Glu motif in their Yaa'-Zaa' positions. Incorporation of this Glu-Glu motif into the sequence of a nonspecific fluorogenic peptide cleaved by MMPs provides a highly selective substrate for MMP-12. A model of one of these inhibitors interacting with MMP-12 suggests that the selectivity observed might be due, in part, to the presence of two unique polar residues in MMP-12, Thr239 and Lys177. These MMP-12-selective inhibitors may have important therapeutic applications to diseases in which MMP-12 has been suggested to play a key role, such as in emphysema, atherosclerosis, and aortic abdominal aneurysm.     

3D reconstruction and comparison of shapes of DNA minicircles observed by cryo-electron microscopy

We use cryo-electron microscopy to compare 3D shapes of 158 bp long DNA minicircles that differ only in the sequence within an 18 bp block containing either a TATA box or a catabolite activator protein binding site. We present a sorting algorithm that correlates the reconstructed shapes and groups them into distinct categories. We conclude that the presence of the TATA box sequence, which is believed to be easily bent, does not significantly affect the observed shapes.     

The Candida Genome Database: facilitating research on Candida albicans molecular biology

The Candida Genome Database (CGD; http://www.candidagenome.org) is a resource for information about the Candida albicans genomic sequence and the molecular biology of its encoded gene products. CGD collects and organizes data from the biological literature concerning C. albicans, and provides tools for viewing, searching, analysing, and downloading these data. CGD also serves as an organizing centre for the C. albicans research community, providing a gene-name registry, contact information, and research community news. This article describes the information contained in CGD and how to access it, either from the perspective of a bench scientist interested in the function of one or a few genes, or from the perspective of a biologist or bioinformatician interpreting large-scale functional genomic datasets.     

Disruption of POF1B binding to nonmuscle actin filaments is associated with premature ovarian failure

Premature ovarian failure (POF) is characterized by elevated gonadotropins and amenorrhea in women aged <40 years. In a Lebanese family with five sisters who received the diagnosis of POF, we established linkage to the long arm of the X chromosome (between Xq21.1 and Xq21.3.3), using whole-genome SNP typing and homozygosity-by-descent mapping. By sequencing one candidate gene within that region, POF1B, we identified a point mutation localized in exon 10. This substitution of a nucleotide (G-->A), at position 1123, results in an arginine-->glutamine mutation of the protein sequence at position 329 (mutation R329Q). All the affected family members were homozygous for the mutation, whereas the unaffected members were heterozygous. Because POF1B shares high homology with the tail portion of the human myosin, we assessed the ability of both wild-type and mutant POF1B proteins to bind nonmuscle actin filaments in vitro. We found that the capacity of the mutant protein to bind nonmuscle actin filaments was diminished fourfold compared with the wild type, suggesting a function of POF1B in germ-cell division. Our study suggests that a homozygous point mutation in POF1B influences the pathogenesis of POF by altering POF1B binding to nonmuscle actin filaments.     

Arbuscular mycorrhizal fungi assemblages in Chernozem great groups revealed by massively parallel pyrosequencing

The arbuscular mycorrhizal (AM) fungal resources present in wheat fields of the Canadian Prairie were explored using 454 pyrosequencing. Of the 33 dominant AM fungal operational taxonomic units (OTUs) found in the 76 wheat fields surveyed at anthesis in 2009, 14 clustered as Funneliformis - Rhizophagus, 16 as Claroideoglomus, and 3 as Diversisporales. An OTU of Funneliformis mosseae and one OTU of Diversisporales each accounted for approximately 16% of all AM fungal OTUs. The former was ubiquitous, and the latter was mainly restricted to the Black and Dark Brown Chernozems. AM fungal OTU community composition was better explained by the Chernozem great groups (P = 0.044) than by measured soil properties. Fifty-two percent of the AM fungal OTUs were unrelated to measured soil properties. Black Chernozems hosted the largest AM fungal OTU diversity and almost twice the number of AM fungal sequences seen in Dark Brown Chernozems, the great group ranking second for AM fungal sequence abundance. Brown Chernozems hosted the lowest AM fungal abundance and an AM fungal diversity as low as that seen in Gray soils. We concluded that Black Chernozems are most conducive to AM fungal proliferation. AM fungi are generally distributed according to Chernozem great groups in the Canadian Prairie, although some taxa are evenly distributed in all soil groups.