On the importance of skewed offspring distributions and background selection in virus population genetics.

Many features of virus populations make them excellent candidates for population genetic study, including a very high rate of mutation, high levels of nucleotide diversity, exceptionally large census population sizes, and frequent positive selection. However, these attributes also mean that special care must be taken in population genetic inference. For example, highly skewed offspring distributions, frequent and severe population bottleneck events associated with infection and compartmentalization, and strong purifying selection all affect the distribution of genetic variation but are often not taken into account. Here, we draw particular attention to multiple-merger coalescent events and background selection, discuss potential misinference associated with these processes, and highlight potential avenues for better incorporating them into future population genetic analyses.

Evolution of uni- and bifactorial sexual compatibility systems in fungi.

Mating systems, that is, whether organisms give rise to progeny by selfing, inbreeding or outcrossing, strongly affect important ecological and evolutionary processes. Large variations in mating systems exist in fungi, allowing the study of their origin and consequences. In fungi, sexual incompatibility is determined by molecular recognition mechanisms, controlled by a single mating-type locus in most unifactorial fungi. In Basidiomycete fungi, however, which include rusts, smuts and mushrooms, a system has evolved in which incompatibility is controlled by two unlinked loci. This bifactorial system probably evolved from a unifactorial system. Multiple independent transitions back to a unifactorial system occurred. It is still unclear what force drove evolution and maintenance of these contrasting inheritance patterns that determine mating compatibility. Here, we give an overview of the evolutionary factors that might have driven the evolution of bifactoriality from a unifactorial system and the transitions back to unifactoriality. Bifactoriality most likely evolved for selfing avoidance. Subsequently, multiallelism at mating-type loci evolved through negative frequency-dependent selection by increasing the chance to find a compatible mate. Unifactoriality then evolved back in some species, possibly because either selfing was favoured or for increasing the chance to find a compatible mate in species with few alleles. Owing to the existence of closely related unifactorial and bifactorial species and the increasing knowledge of the genetic systems of the different mechanisms, Basidiomycetes provide an excellent model for studying the different forces that shape breeding systems.

Evolution in heterogeneous populations: from migration models to fixation probabilities.

Although dispersal is recognized as a key issue in several fields of population biology (such as behavioral ecology, population genetics, metapopulation dynamics or evolutionary modeling), these disciplines focus on different aspects of the concept and often make different implicit assumptions regarding migration models. Using simulations, we investigate how such assumptions translate into effective gene flow and fixation probability of selected alleles. Assumptions regarding migration type (e.g. source-sink, resident pre-emption, or balanced dispersal) and patterns (e.g. stepping-stone versus island dispersal) have large impacts when demes differ in sizes or selective pressures. The effects of fragmentation, as well as the spatial localization of newly arising mutations, also strongly depend on migration type and patterns. Migration rate also matters: depending on the migration type, fixation probabilities at an intermediate migration rate may lie outside the range defined by the low- and high-migration limits when demes differ in sizes. Given the extreme sensitivity of fixation probability to characteristics of dispersal, we underline the importance of making explicit (and documenting empirically) the crucial ecological/ behavioral assumptions underlying migration models.

Patients with severe slipped capital femoral epiphysis treated by the modified Dunn procedure have low rates of avascular necrosis, good outcomes, and little osteoarthritis at long-term follow-up.

AIMS: The modified Dunn procedure has the potential to restore the anatomy in hips with severe slipped capital femoral epiphyses (SCFE). However, there is a risk of developing avascular necrosis of the femoral head (AVN). In this paper, we report on clinical outcome, radiological outcome, AVN rate and complications, and the cumulative survivorship at long-term follow-up in patients undergoing the modified Dunn procedure for severe SCFE. PATIENTS AND METHODS: We performed a retrospective analysis involving 46 hips in 46 patients treated with a modified Dunn procedure for severe SCFE (slip angle > 60°) between 1999 and 2016. At nine-year-follow-up, 40 hips were available for clinical and radiological examination. Mean preoperative age was 13 years, and 14 hips (30%) presented with unstable slips. Mean preoperative slip angle was 64°. Kaplan-Meier survivorship was calculated. RESULTS: At the latest follow-up, the mean Merle d'Aubigné and Postel score was 17 points (14 to 18), mean modified Harris Hip Score was 94 points (66 to 100), and mean Hip Disability and Osteoarthritis Outcome Score was 91 points (67 to 100). Postoperative slip angle was 7° (1° to 16°). One hip (2%) had progression of osteoarthritis (OA). Two hips (5%) developed AVN of the femoral head and required further surgery. Three other hips (7%) underwent implant revision due to screw breakage or change of wires. Cumulative survivorship was 86% at ten-year follow-up. CONCLUSION: The modified Dunn procedure for severe SCFE resulted in a low rate of AVN, low risk of progression to OA, and high functional scores at long-term follow-up. The slip deformities were mainly corrected but secondary impingement deformities can develop in some hips and may require further surgical treatment. Cite this article: Bone Joint J 2019;101-B:403-414.

Indication of spatially random occurrence of Chlamydia-like organisms in Bufo bufo tadpoles from ponds located in the Geneva metropolitan area.

Occurrence of bacteria belonging to the order Chlamydiales was investigated for the first time in common toad (Bufo bufo) tadpole populations collected from 41 ponds in the Geneva metropolitan area, Switzerland. A Chlamydiales-specific real-time PCR was used to detect and amplify the Chlamydiales 16S ribosomal RNA-encoding gene from the tails of 375 tadpoles. We found the studied amphibian populations to host Chlamydia-like organisms (CLOs) attributable to the genera Similichlamydia, Neochlamydia, Protochlamydia and Parachlamydia (all belonging to the family Parachlamydiaceae), Simkania (family Simkaniaceae) and Estrella (family Criblamydiaceae); additionally, DNA from the genus Thermoanaerobacter (family Thermoanaerobacteriaceae) was detected. Global autocorrelation analysis did not reveal a spatial structure in the observed CLOs occurrence rates, and association tests involving land cover characteristics did not evidence any clear effect on CLOs occurrence rates in B. bufo. Although preliminary, these results suggest a random and ubiquitous distribution of CLOs in the environment, which would support the biogeographical expectation 'everything is everywhere' for the concerned microorganisms.

Dichloromethane biodegradation in multi-contaminated groundwater: Insights from biomolecular and compound-specific isotope analyses.

Dichloromethane (DCM) is a widespread and toxic industrial solvent which often co-occurs with chlorinated ethenes at polluted sites. Biodegradation of DCM occurs under both oxic and anoxic conditions in soils and aquifers. Here we investigated in situ and ex situ biodegradation of DCM in groundwater sampled from the industrial site of Themeroil (France), where DCM occurs as a major co-contaminant of chloroethenes. Carbon isotopic fractionation (εC) for DCM ranging from -46 to -22‰ were obtained under oxic or denitrifying conditions, in mineral medium or contaminated groundwater, and for laboratory cultures of Hyphomicrobium sp. strain GJ21 and two new DCM-degrading strains isolated from the contaminated groundwater. The extent of DCM biodegradation (B%) in the aquifer, as evaluated by compound-specific isotope analysis (δ13C), ranged from 1% to 85% applying DCM-specific εC derived from reference strains and those determined in this study. Laboratory groundwater microcosms under oxic conditions showed DCM biodegradation rates of up to 0.1 mM·day-1, with concomitant chloride release. Dehalogenase genes dcmA and dhlA involved in DCM biodegradation ranged from below 4 × 102 (boundary) to 1 × 107 (source zone) copies L-1 across the contamination plume. High-throughput sequencing on the 16S rrnA gene in groundwater samples showed that both contaminant level and terminal electron acceptor processes (TEAPs) influenced the distribution of genus-level taxa associated with DCM biodegradation. Taken together, our results demonstrate the potential of DCM biodegradation in multi-contaminated groundwater. This integrative approach may be applied to contaminated aquifers in the future, in order to identify microbial taxa and pathways associated with DCM biodegradation in relation to redox conditions and co-contamination levels.

A comparison of the pH, urea, and temperature-denatured states of barnase by heteronuclear NMR: implications for the initiation of protein folding.

The denatured states of barnase that are induced by urea, acid, and high temperature and acid have been assigned and characterised by high resolution heteronuclear NMR. The assignment was completed using a combination of triple-resonance and magnetisation-transfer methods. The latter was facilitated by selecting a suitable mutant of barnase (Ile-->Val51) which has an appropriate rate of interconversion between native and denatured states in urea. 3J NH-C alpha H coupling constants were determined for pH and urea-denatured barnase and intrinsic "random coil" coupling constants are shown to be different for different residue types. All the denatured states are highly unfolded. But, a consistent series of weak correlations in chemical shift, NOESY and coupling constant data provides evidence that the acid-denatured state has some residual structure in regions that form the first and second helices and the central strands of beta-sheet in the native protein. The acid/temperature-denatured states has less structure in these regions, and the urea-denatured state, less still. These observations may be combined with detailed analyses of the folding pathway of barnase from kinetic studies to illuminate the relevance of residual structure in the denatured states of proteins to the mechanism of protein folding. First, the folding of barnase is known to proceed in its later stages through structures in which the first helix and centre of the beta-sheet are extensively formed. Thus, embryonic initiation sites for these do exist in the denatured states and so could well develop into true nuclei. Second, it has been clearly established that the second helix is unfolded in these later states, and so residual structure in this region of the protein is non-productive. These data fit a model of protein folding in which local nucleation sites are latent in the denatured state and develop only when they make interactions elsewhere in the protein that stabilise them during the folding process. Thus, studies of the structure of denatured states pinpoint where nucleation sites may be, and the kinetic and protein engineering studies show which ones are productive.

Worldwide production of high-fructose syrup and crystalline fructose.

High-fructose syrups (HFS) are now manufactured and used in many countries throughout the world. They are produced from a variety of starch raw materials including corn, rice, tapioca, wheat, cassava, and sugar beet pulp. Production of HFS is highly dependent on local sucrose and economics of agricultural raw materials. HFS is produced and consumed in the largest quantity in the United States by using corn starch as the raw material. Eastern Europe, the former Soviet Union, and Asia are major growth areas for HFS production. Crystalline fructose is now being used in a growing number of food applications but its production represents a small percentage of total fructose sweeteners.

[Site-directed mutagenesis of the dichloromethane dehalogenase gene from Methylophilus sp. strain DM11].

In order to investigate the role of different residues of Methylophilus sp. strain DM11 dichloromethane dehalogenase for substrate binding, glutathione affinity, and catalytic activity, site-directed mutagenesis studies of the gene encoding the enzyme were carried out. The conserved tryptophane residue at 103 region was respectively substituted by phenylalanine, valine or asparagine. The conserved arginine residue at 109 region was substituted by leucine. The conserved tryptophane residue at 117 region was respectively substituted by tyrosine or phenylalanine. Six mutant enzymes were produced. Among them three possess lower activities, other three do not possess activity. The properties of the mutant enzyme W117Y are very different from wild-type enzyme.

Bacterial communities in batch and continuous-flow wetlands treating the herbicide S-metolachlor.

Knowledge of wetland bacterial communities in the context of pesticide contamination and hydrological regime is scarce. We investigated the bacterial composition in constructed wetlands receiving Mercantor Gold(®) contaminated water (960 g L(-1) of the herbicide S-metolachlor, >80% of the S-enantiomer) operated under continuous-flow or batch modes to evaluate the impact of the hydraulic regime. In the continuous-flow wetland, S-metolachlor mass removal was >40%, whereas in the batch wetland, almost complete removal of S-metolachlor (93-97%) was observed. Detection of ethanesulfonic and oxanilic acid degradation products further indicated S-metolachlor biodegradation in the two wetlands. The dominant bacterial populations were characterised by terminal restriction fragment length polymorphism (T-RFLP) and 454 pyrosequencing. The bacterial profiles evolved during the first 35 days of the experiment, starting from a composition similar to that of inlet water, with the use of nitrate and to a lesser extent sulphate and manganese as terminal electron acceptors for microbial metabolism. Proteobacteria were the most abundant phylum, with Beta-, Alpha- and Gammaproteobacteria representing 26%, 19% and 17% respectively of total bacterial abundance. Bacterial composition in wetland water changed gradually over time in continuous-flow wetland and more abruptly in the batch wetland. Differences in overall bacterial water structure in the two systems were modest but significant (p=0.008), and S-metolachlor, nitrate, and total inorganic carbon concentrations correlated with changes in the bacterial profiles. Together, the results highlight that bacterial composition profiles and their dynamics may be used as bioindicators of herbicide exposure and hydraulic disturbances in wetland systems.

Using compound-specific isotope analysis to assess the degradation of chloroacetanilide herbicides in lab-scale wetlands.

Compound-specific isotope analysis (CSIA) is a promising tool to study the environmental fate of a wide range of contaminants including pesticides. In this study, a novel CSIA method was developed to analyse the stable carbon isotope signatures of widely used chloroacetanilide herbicides. The developed method was applied in combination with herbicide concentration and hydrochemical analyses to investigate in situ biodegradation of metolachlor, acetochlor and alachlor during their transport in lab-scale wetlands. Two distinct redox zones were identified in the wetlands. Oxic conditions prevailed close to the inlet of the four wetlands (oxygen concentration of 212±24µM), and anoxic conditions (oxygen concentrations of 28±41µM) prevailed towards the outlet, where dissipation of herbicides mainly occurred. Removal of acetochlor and alachlor from inlet to outlet of wetlands was 56% and 51%, whereas metolachlor was more persistent (23% of load dissipation). CSIA of chloroacetanilides at the inlet and outlet of the wetlands revealed carbon isotope fractionation of alachlor (εbulk=-2.0±0.3‰) and acetochlor (εbulk=-3.4±0.5‰), indicating that biodegradation contributes to the dissipation of both herbicides. This study is a first step towards the application of CSIA to evaluate the transport and degradation of chloroacetanilide herbicides in the environment.

Highly efficient methane biocatalysis revealed in a methanotrophic bacterium.

Methane is an essential component of the global carbon cycle and one of the most powerful greenhouse gases, yet it is also a promising alternative source of carbon for the biological production of value-added chemicals. Aerobic methane-consuming bacteria (methanotrophs) represent a potential biological platform for methane-based biocatalysis. Here we use a multi-pronged systems-level approach to reassess the metabolic functions for methane utilization in a promising bacterial biocatalyst. We demonstrate that methane assimilation is coupled with a highly efficient pyrophosphate-mediated glycolytic pathway, which under oxygen limitation participates in a novel form of fermentation-based methanotrophy. This surprising discovery suggests a novel mode of methane utilization in oxygen-limited environments, and opens new opportunities for a modular approach towards producing a variety of excreted chemical products using methane as a feedstock.

Invasion and fixation of sex-reversal genes.

We simulated a meta-population with random dispersal among demes but local mating within demes to investigate conditions under which a dominant female-determining gene W, with no individual selection advantage, can invade and become fixed in females, changing the population from male to female heterogamety. Starting with one mutant W in a single deme, the interaction of sex ratio selection and random genetic drift causes W to be fixed among females more often than a comparable neutral mutation with no influence on sex determination, even when YY males have slightly reduced viability. Meta-population structure and interdeme selection can also favour the fixation of W. The reverse transition from female to male heterogamety can also occur with higher probability than for a comparable neutral mutation. These results help to explain the involvement of sex-determining genes in the evolution of sex chromosomes and in sexual selection and speciation.

Design and validation of a partial-genome microarray for transcriptional profiling of the Bradyrhizobium japonicum symbiotic gene region.

The design and use of a pilot microarray for transcriptome analysis of the symbiotic, nitrogen-fixing Bradyrhizobium japonicum is reported here. The custom-synthesized chip (Affymetrix GeneChip) features 738 genes, more than half of which belong to a 400-kb chromosomal segment strongly associated with symbiosis-related functions. RNA was isolated following an optimized protocol from wild-type cells grown aerobically and microaerobically, and from cells of aerobically grown regR mutant and microaerobically grown nifA mutant. Comparative microarray analyses thus revealed genes that are transcribed in either a RegR- or a NifA-dependent manner plus genes whose expression depends on the cellular oxygen status. Several genes were newly identified as members of the RegR and NifA regulons, beyond genes, which had been known from previous work. A comprehensive transcription analysis was performed with one of the new RegR-controlled genes (id880). Expression levels determined by microarray analysis of selected NifA- and RegR-controlled genes corresponded well with quantitative real-time PCR data, demonstrating the high complementarity of microarray analysis to classical methods of gene expression analysis in B. japonicum. Nevertheless, several previously established members of the NifA regulon were not detected as transcribed genes by microarray analysis, confirming the potential pitfalls of this approach also observed by other authors. By and large, this pilot study has paved the way towards the genome-wide transcriptome analysis of the 9.1-Mb B. japonicum genome.

Protein engineering studies of dichloromethane dehalogenase/glutathione S-transferase from Methylophilus sp. strain DM11. Ser12 but not Tyr6 is required for enzyme activity.

The structural gene for dichloromethane dehalogenase/glutathione S-transferase (GST, EC 2.5.1.18) from Methylophilus sp. strain DM11 was subcloned into a multicopy plasmid under the control of the T7 polymerase promoter, allowing expression in Escherichia coli and easy purification of the enzyme in good yield. Several point mutations leading to amino acid changes at residues Tyr6, His8 and Ser12 of the protein were introduced in this gene. Mutations at Tyr6, the N-terminal tyrosine known to be essential for enzymatic activity in glutathione S-transferases of the alpha, mu, and pi classes, had little effect on the activity of dichloromethane dehalogenase. The same applied for mutations at residue His8, which from multiple alignments of GST sequences may also correspond to the conserved N-terminal tyrosine residue of GST enzymes. The higher turnover rate of the wild-type enzyme with dibromomethane compared with dichloromethane was lost in mutants with amino acid replacements at residue His8, but retained in mutant proteins at Tyr6. Mutations at Ser12 led to mutants with drastically reduced enzymatic activity, pinpointing this residue as an essential determinant of catalytic efficiency.

The elusive roles of bacterial glutathione S-transferases: new lessons from genomes.

Glutathione S-transferases constitute a large family of enzymes which catalyze the addition of glutathione to endogenous or xenobiotic, often toxic electrophilic chemicals. Eukaryotic glutathione S-transferases usually promote the inactivation, degradation or excretion of a wide range of compounds by formation of the corresponding glutathione conjugates. In bacteria, by contrast, the few glutathione S-transferases for which substrates are known, such as dichloromethane dehalogenase, 1,2-dichloroepoxyethane epoxidase and tetrachlorohydroquinone reductase, are catabolic enzymes with an essential role for growth on recalcitrant chemicals. Glutathione S-transferase genes have also been found in bacterial operons and gene clusters involved in the degradation of aromatic compounds. Information from bacterial genome sequencing projects now suggests that glutathione S-transferases are present in large numbers in proteobacteria. In particular, the genomes of three Pseudomonas species each include at least ten different glutathione S-transferase genes. Several of the corresponding proteins define new classes of the glutathione S-transferase family and may also have novel functions that remain to be elucidated.

Synthetic peptide and template-assembled synthetic protein models of the hen egg white lysozyme 87-97 helix: importance of a protein-like framework for conformational stability in a short peptide sequence.

In the native structure of hen egg white lysozyme (HEL), the amino acid sequence 87-97 (HEL 87-97) forms an amphiphilic helix, with hydrophilic residues in the sequence directed toward the solvent. A synthetic version of the HEL 87-97 sequence (with the cysteine corresponding to position 94 of HEL replaced by alanine) displays conformational features in solution typical of an unordered structure as judged by CD. However, various modifications in the sequence result in increased helix-forming potential of the HEL 87-97 analogues. Further stabilization of the helical conformation in the most helical analogue of the HEL 87-97 sequence is obtained when 4 copies of this peptide sequence are coupled on a peptide carrier molecule following the template-assembled synthetic protein (TASP) approach [M. Mutter and S. Vuilleumier (1989) Angew. Chem. Int. Ed. Engl., Vol. 28, pp. 535-554 "A Chemical Approach to Protein Design-Template-Assembled Synthetic Proteins (TASP)." This suggests that long-range interactions of the peptide with its environment contribute to conformational stability in short peptide sequences. TASP molecules may prove useful for the study of the factors that determine secondary structure formation in short peptides by providing a protein-like framework.

Identification of a novel determinant of glutathione affinity in dichloromethane dehalogenases/glutathione S-transferases.

Bacterial dichloromethane dehalogenases catalyze the glutathione-dependent hydrolysis of dichloromethane to formaldehyde and are members of the enzyme superfamily of glutathione S-transferases involved in the detoxification of electrophilic compounds. Numerous protein engineering studies have addressed questions pertaining to the substrate specificity, the reaction mechanism, and the kinetic pathway of glutathione S-transferases. In contrast, the molecular determinants for binding of the glutathione cofactor have been less well investigated. Dichloromethane dehalogenases from Hyphomicrobium sp. DM2 and Methylobacterium sp. DM4 displayed significantly different affinities for glutathione, but not for the dichloromethane substrate. The sequence of dcmA, the dichloromethane dehalogenase gene from strain DM2, was determined and featured a single base difference from the previously determined sequence of dcmA from strain DM4. This base change resulted in a single amino acid difference in the corresponding proteins at sequence position 27. Site-directed variants of the homologous dichloromethane dehalogenase from Methylophilus sp. DM11 (56% amino acid identity) at the corresponding residue in the protein sequence provided further evidence that this residue selectively modulated the dependence of dichloromethane dehalogenase activity on glutathione.

Insertion in barnase of a loop sequence from ribonuclease T1. Investigating sequence and structure alignments by protein engineering.

Barnase was mutated by inserting into its active site loop sequences found in the related enzyme ribonuclease T1 (RNase T1), according to either structural or sequential similarity alignments. The barnase/RNase T1 hybrid corresponding to the structural alignment of the two proteins, endo-[RNaseT1-(93-99)]102abarnase, contains RNase T1 residues at positions 93-99 inserted between residues at positions 102 and 103 of barnase. The other constructed mutant, endo-[RNaseT1-(95-98)]104abarnase, has RNase T1 residues at positions 95-98 inserted between residues at positions 104 and 105 in barnase, corresponding to published sequence alignments of the two proteins in this region. The mutants were characterized by absorbance, fluorescence and CD spectroscopy; the stability, folding and unfolding kinetics, and catalytic activity were measured and compared with the wild-type enzyme. Endo-[RNaseT1-(93-99)]102abarnase, the mutant protein corresponding to the structural alignment of barnase with ribonuclease T1, shows a slightly higher stability (approximately 5 kJ/mol) towards urea and heat denaturation than the mutant endo-[RNaseT1-(95-98)]104abarnase, designed according to a sequence alignment between the two enzymes. Both mutants have very low catalytic activity, although the effect of mutation is almost entirely limited to kcat in the case of the mutant corresponding to the structural alignment between barnase and ribonuclease T1, while both kcat and Km are affected in the mutant corresponding to the sequence alignment between the two enzymes. Thus, the superiority of structural over sequential alignments cannot be supported conclusively by direct experiment in the present case.