One-carbon metabolism and epigenetic programming of mammalian development

One-carbon (1C) metabolism comprises a series of integrated metabolic pathways, including the linked methionine-folate cycles, that provide methyl groups for the synthesis of biomolecules and the epigenetic regulation of gene expression via chromatin methylation. Most of the research investigating the function of 1C metabolism pertains to studies undertaken in the rodent liver. Comparatively little is known about the function of 1C metabolism in reproductive and embryonic cells, particularly in domestic ruminant species. Periconceptional dietary deficiencies in 1C substrates and cofactors are known to lead to epigenetic alterations in DNA methylation in genes that regulate key developmental processes in the embryo. Such modifications can have negative implications on the subsequent development, metabolism and health of offspring. This thesis sought to improve current understanding of the regulation of 1C metabolism in the ruminant liver, ovary and preimplantation embryo through in vivo and in vitro nutritional supplementation experiments coupled with metabolomic, transcriptomic and epigenetic analyses. The first part of this thesis (Chapter 2) assessed the metabolic consequences of dietary methyl deficiency using novel mass spectrometry–based methods that were developed for the quantification of B vitamins, folates and 1C-related amines in sheep liver. This study provided the first comparison of the relative abundance of bioactive 1C metabolites in liver harvested from methyl deficient sheep relative to a control study population of abattoir derived sheep. Relevant reductions in dietary methyl availability led to significant alterations in hepatic 1C metabolite concentrations. Large natural variations in the hepatic concentrations of individual metabolites in both sheep study populations reflected the dietary and genetic variation in our chosen outbred model species. These metabolomics platforms will be useful for investigating 1C metabolism and linked biochemical pathways in order to facilitate future dietary and genetic studies of metabolic health and epigenetic regulation of gene expression. Based on the absence of methionine cycle enzyme transcripts (e.g. MAT1A and BHMT) in the bovine ovary and preimplantation embryo, the second part of this thesis (Chapter 3 and Chapter 4) addressed the hypothesis that ruminant reproductive and embryonic cells are highly sensitive to methyl group availability and, therefore, epigenetic programming during the periconceptional period. Transcript analyses confirmed MAT2A expression in the bovine liver, ovary and at each stage of preimplantation embryo development assessed to Day 8. Transcripts for BHMT isoforms (BHMT and BHMT2) were detected in the bovine ovary but were weak or absent in embryos, highlighting a key difference in methionine metabolism between hepatic and reproductive cells. Bovine embryos were produced in vitro using custom-made media containing 0 (nonphysiological), 10 (low physiological), 50 (high physiological), and 500 µmol/L (supraphysiological) added methionine (Chapter 3). Gross morphological assessments of embryo stage, grade, cell lineage allocation and primary sex ratio revealed that culture in non- and supraphysiological methionine concentrations was detrimental for embryo development, whilst culture in the high physiological concentration appeared to be best. Reduced representation bisulphite sequencing (RRBS) of inner cell mass (ICM) and trophectoderm (TE) cells immunodissected from Day 8 blastocysts demonstrated that culturing embryos in low physiological methionine led to global hypomethylation within both cell lineages. Bioinformatic analyses of differentially methylated genes included gene set enrichment analyses (GSEA). Gene Ontology (GO) terms and Kyoto Encyclopedia of Genes and Genomes (KEGG) pathways that were enriched within the ICM were associated with protein catabolism and autophagy, and significant terms and pathways enriched within the TE were associated with cellular transport. Of particular biological interest was the loss of methylation within regulatory region (DMR2) of the paternally imprinted gene, IGF2R, in the TE following culture in low physiological methionine. Transcript analysis found no significant effect of methionine concentration on the expression of IGF2R or the antisense transcript, AIRN, in the primary cell lineages of the Day 8 bovine preimplantation embryo. Hypomethylation of IGF2R DMR2 has been associated with aberrant IGF2R expression and large offspring syndrome (LOS) in cattle and sheep that were subjected to embryo manipulation during assisted reproductive technology (ART) procedures, such as somatic cell nuclear transfer (SCNT) or non-physiological in vitro embryo culture environments. Chapter 5 sought to evaluate the effect of somatic donor cell type on epigenetic reprogramming via DNA methylation in hepatocytes isolated from cloned sheep. RRBS facilitated the comparison of methylation reprogramming between Finn Dorset (D) clone hepatocytes and their mammary epithelial (OP5) donor cell line; and, Lleyn (L) clone hepatocytes and their Lleyn fetal fibroblast (LFF4) donor cell line. Methylation was most closely correlated between D and L clone hepatocytes than between clones and their respective donor cell lines. In general, hepatocytes were hypomethylated relative to their somatic donor cell nuclei. GSEA identified genes that encoded transcription factor proteins enriched within the ‘Sequence-specific DNA binding’ term (GO:0043565) as differentially methylated between clone hepatocytes and their donor cell lines. In addition, imprinted genes, including IGF2R, were differentially methylated in clone hepatocytes relative to somatic cell nuclei. In summary, this thesis promotes and supports the importance of an optimal methyl balance to support periconceptional development in mammals. The experiments detailed herein provide an insight into the metabolic consequences of dietary methyl deficiency (and excess) in outbred populations of domestic ruminants, with a specific focus on the liver, ovary and preimplantation embryo. The results demonstrate that tissue- and species-specific features of 1C metabolism render ruminant embryonic cells sensitive to methionine inputs within a physiological range. The observation that in vitro embryo culture and manipulation techniques, such as somatic cell nuclear transfer, can cause epigenetic alterations to DNA methylation during preimplantation development provides a basis for further study into the safety and efficacy of emerging assisted reproductive technologies

Anti-angiogenesis: making the tumor vulnerable to the immune system

Ongoing angiogenesis has been shown to possess immune suppressive activity through several mechanisms. One of these mechanisms is the suppression of adhesion receptors, such as intercellular adhesion molecule-1, vascular cell adhesion molecule-1 and E-selectin—adhesion molecules involved in leukocyte interactions—on the vascular endothelium. This phenomenon, when happening to the tumor endothelium, supports tumor growth due to escape from immunity. Since angiogenesis has this immune suppressive effect, it has been hypothesized that inhibition of angiogenesis may circumvent this problem. In vitro and in vivo data now show that several angiogenesis inhibitors are able to normalize endothelial adhesion molecule expression in tumor blood vessels, restore leukocyte vessel wall interactions, and enhance the inflammatory infiltrate in tumors. It is suggested that such angiogenesis inhibitors can make tumors more vulnerable for the immune system and may therefore be applied to facilitate immunotherapy approaches for the treatment of cancer

Characteristics of people living with undiagnosed dementia: findings from the CFAS Wales study

This is the final version. Available from BMC via the DOI in this record. The CFAS Wales datasets analysed during the current study are deposited with the UK Data Service, http://doi.org/10.5255/UKDA-SN-8281-1Abstract Background: Many people living with dementia remain undiagnosed, with diagnosis usually occurring long after signs and symptoms are present. A timely diagnosis is important for the wellbeing of the person living with dementia and the family, allowing them to plan and have access to support services sooner. The aim of this study was to identify demographic characteristics and neuropsychiatric symptoms associated with being undiagnosed, which may help clinicians be more aware of signs that could be indicative of early-stage or undetected dementia. Methods: This cross-sectional study uses data from waves 1 and 2 (two years apart) of the Cognitive Function and Ageing Studies Wales (CFAS Wales). CFAS Wales participants were included who had a study assessment of dementia, as determined by the Automated Geriatric Examination for Computer Assisted Taxonomy (AGECAT) algorithm and by expert assessment, and who had had their primary care records checked for a clinical diagnosis of dementia. We identifed 19 people with a diagnosis of dementia and 105 people living with undiagnosed dementia, and explored demographic characteristics and the presence or absence of a range of neuropsychiatric symptoms in the undiagnosed population using logistic regression. Results: Findings suggest that people living with dementia who have better cognition, have more years of education, or live in more deprived areas are less likely to have a diagnosis. In terms of neuropsychiatric symptoms, depression and sleep problems were associated with being undiagnosed. Apathy was common across all people living with dementia, but those with a diagnosis were more likely to have severe apathy. Conclusions: This study has clinical practice implications as the fndings may help clinicians be more aware of characteristics and symptoms of people who are undiagnosed or who are at greater risk of remaining undiagnosed, enabling them to be more vigilant in picking up signs of dementia at an earlier stage.Economic and Social Research Council (ESRC)UKR

Semi-Quantification of Total Campylobacter and Salmonella During Egg Incubations Using a Combination of 16S rDNA and Specific Pathogen Primers for qPCR

Rapid molecular techniques that evaluate eggs for the presence of foodborne pathogens is an essential component to poultry food safety monitoring. Interestingly, it is not just table eggs that contribute to outbreaks of foodborne disease. Broiler layer production actively contributes to sustaining of foodborne pathogens within a flock. The surface contamination of production eggs with invasive pathogens such as Salmonella enterica, Campylobacter jejuni, and Listeria monocytogenes during embryogenesis results in gastrointestinal tract (GIT) colonization. Pathogens that secure a niche within the GIT during embryonic development are nearly impossible to eradicate from the food chain. Therefore, current monitoring paradigms are not comprehensive because they fail to capture the presence of invasive pathogens within the embryonic GIT rapidly. By developing tools to recognize the pathogens’ presence in the GIT during embryogenesis, producers are then able to spot evaluate broiler eggs for their potential risk as carriers of foodborne pathogens. In this study a novel qPCR assay was developed to semi-quantify pathogen load relative to total bacterial burden. Eggs sampled from three independent production broiler flocks of different ages were assayed for S. enterica (invA), C. jejuni (HipO), and L. monocytogenes (HlyA) against total microbial load (16s). The eggs were sampled at 1-day post-set within each flock, 2 weeks post-set, after vaccination (at 2.5 weeks) and 1-day post-hatch. The eggs were washed, and the yolk and embryonic chick GIT were collected. The DNA was extracted and subjected to a qPCR assay. The results confirm a novel technique for pathogen monitoring relative to total bacterial load and a unique method for monitoring the dynamics of foodborne pathogen invasion throughout broiler egg production

Impacts of organic and conventional crop management on diversity and activity of free-living nitrogen fixing bacteria and total bacteria are subsidiary to temporal effects

A three year field study (2007-2009) of the diversity and numbers of the total and metabolically active free-living diazotophic bacteria and total bacterial communities in organic and conventionally managed agricultural soil was conducted at the Nafferton Factorial Systems Comparison (NFSC) study, in northeast England. The result demonstrated that there was no consistent effect of either organic or conventional soil management across the three years on the diversity or quantity of either diazotrophic or total bacterial communities. However, ordination analyses carried out on data from each individual year showed that factors associated with the different fertility management measures including availability of nitrogen species, organic carbon and pH, did exert significant effects on the structure of both diazotrophic and total bacterial communities. It appeared that the dominant drivers of qualitative and quantitative changes in both communities were annual and seasonal effects. Moreover, regression analyses showed activity of both communities was significantly affected by soil temperature and climatic conditions. The diazotrophic community showed no significant change in diversity across the three years, however, the total bacterial community significantly increased in diversity year on year. Diversity was always greatest during March for both diazotrophic and total bacterial communities. Quantitative analyses using qPCR of each community indicated that metabolically active diazotrophs were highest in year 1 but the population significantly declined in year 2 before recovering somewhat in the final year. The total bacterial population in contrast increased significantly each year. Seasonal effects were less consistent in this quantitative study

Sexual Display and Mate Choice in an Energetically Costly Environment

Sexual displays and mate choice often take place under the same set of environmental conditions and, as a consequence, may be exposed to the same set of environmental constraints. Surprisingly, however, very few studies consider the effects of environmental costs on sexual displays and mate choice simultaneously. We conducted an experiment, manipulating water flow in large flume tanks, to examine how an energetically costly environment might affect the sexual display and mate choice behavior of male and female guppies, Poecilia reticulata. We found that male guppies performed fewer sexual displays and became less choosy, with respect to female size, in the presence of a water current compared to those tested in still water. In contrast to males, female responsive to male displays did not differ between the water current treatments and females exhibited no mate preferences with respect to male size or coloration in either treatment. The results of our study underscore the importance of considering the simultaneous effects of environmental costs on the sexual behaviors of both sexes

Analysis of the functional conservation of ethylene receptors between maize and Arabidopsis

Ethylene, a regulator of plant growth and development, is perceived by specific receptors that act as negative regulators of the ethylene response. Five ethylene receptors, i.e., ETR1, ERS1, EIN4, ETR2, and ERS2, are present in Arabidopsis and dominant negative mutants of each that confer ethylene insensitivity have been reported. In contrast, maize contains just two types of ethylene receptors: ZmERS1, encoded by ZmERS1a and ZmERS1b, and ZmETR2, encoded by ZmETR2a and ZmETR2b. In this study, we introduced a Cys to Tyr mutation in the transmembrane domain of ZmERS1b and ZmETR2b that is present in the etr1-1 dominant negative mutant and expressed each protein in Arabidopsis. Mutant Zmers1b and Zmetr2b receptors conferred ethylene insensitivity and Arabidopsis expressing Zmers1b or Zmetr2b were larger and exhibited a delay in leaf senescence characteristic of ethylene insensitive Arabidopsis mutants. Zmers1b and Zmetr2b were dominant and functioned equally well in a hemizygous or homozygous state. Expression of the Zmers1b N-terminal transmembrane domain was sufficient to exert dominance over endogenous Arabidopsis ethylene receptors whereas the Zmetr2b N-terminal domain failed to do so. Neither Zmers1b nor Zmetr2b functioned in the absence of subfamily 1 ethylene receptors, i.e., ETR1 and ERS1. These results suggest that Cys65 in maize ZmERS1b and ZmETR2b plays the same role that it does in Arabidopsis receptors. Moreover, the results demonstrate that the mutant maize ethylene receptors are functionally dependent on subfamily 1 ethylene receptors in Arabidopsis, indicating substantial functional conservation between maize and Arabidopsis ethylene receptors despite their sequence divergence

Both Geography and Ecology Contribute to Mating Isolation in Guppies

Local adaptation to different environments can promote mating isolation – either as an incidental by-product of trait divergence, or as a result of selection to avoid maladaptive mating. Numerous recent empirical examples point to the common influence of divergent natural selection on speciation based largely on evidence of strong pre-mating isolation between populations from different habitat types. Accumulating evidence for natural selection's influence on speciation is therefore no longer a challenge. The difficulty, rather, is in determining the mechanisms involved in the progress of adaptive divergence to speciation once barriers to gene flow are already present. Here, we present results of both laboratory and field experiments with Trinidadian guppies (Poecilia reticulata) from different environments, who do not show complete reproductive isolation despite adaptive divergence. We investigate patterns of mating isolation between populations that do and do not exchange migrants and show evidence for both by-product and reinforcement mechanisms depending on female ecology. Specifically, low-predation females discriminate against all high-predation males thus implying a by-product mechanism, whereas high-predation females only discriminate against low-predation males from further upstream in the same river, implying selection to avoid maladaptive mating. Our study thus confirms that mechanisms of adaptive speciation are not necessarily mutually exclusive and uncovers the complex ecology-geography interactions that underlie the evolution of mating isolation in nature