Genetic contributions to agricultural sustainability

The current tools of enquiry into the structure and operation of the plant genome have provided us with an understanding of plant development and function far beyond the state of knowledge that we had previously. We know about key genetic controls repressing or stimulating the cascades of gene expression that move a plant through stages in its life cycle, facilitating the morphogenesis of vegetative and reproductive tissues and organs. The new technologies are enabling the identification of key gene activity responses to the range of biotic and abiotic challenges experienced by plants. In the past, plant breeders produced new varieties with changes in the phases of development, modifications of plant architecture and improved levels of tolerance and resistance to environmental and biotic challenges by identifying the required phenotypes in a few plants among the large numbers of plants in a breeding population. Now our increased knowledge and powerful gene sequence-based diagnostics provide plant breeders with more precise selection objectives and assays to operate in rationally planned crop improvement programmes. We can expect yield potential to increase and harvested product quality portfolios to better fit an increasing diversity of market requirements. The new genetics will connect agriculture to sectors beyond the food, feed and fibre industries; agri-business will contribute to public health and will provide high-value products to the pharmaceutical industry as well as to industries previously based on petroleum feedstocks and chemical modification processes.     

Evaluating the role of natural selection in the evolution of gene regulation

Surveys of gene expression reveal extensive variability both within and between a wide range of species. Compelling cases have been made for adaptive changes in gene regulation, but the proportion of expression divergence attributable to natural selection remains unclear. Distinguishing adaptive changes driven by positive selection from neutral divergence resulting from mutation and genetic drift is critical for understanding the evolution of gene expression. Here, we review the various methods that have been used to test for signs of selection in genomic expression data. We also discuss properties of regulatory systems relevant to neutral models of gene expression. Despite some potential caveats, published studies provide considerable evidence for adaptive changes in gene expression. Future challenges for studies of regulatory evolution will be to quantify the frequency of adaptive changes, identify the genetic basis of expression divergence and associate changes in gene expression with specific organismal phenotypes.     

Contributions of the specialised DNA polymerases to replication of structured DNA

It is becoming increasingly clear that processive DNA replication is threatened not only by DNA damage but also by secondary structures that can form in the DNA template. Failure to resolve these structures promptly leads to both genetic instability, for instance DNA breaks and rearrangements, and to epigenetic instability, in which inaccurate propagation of the parental chromatin state leads to unscheduled changes in gene expression. Multiple overlapping mechanisms are needed to deal with the wide range of potential DNA structural challenges to replication. This review focuses on the emerging mechanisms by which specialised DNA polymerases, best known for their role in the replication of damaged DNA, contribute to the replication of undamaged but structured DNA, particularly G quadruplexes.     

Prospects for incorporation of epigenetic biomarkers in human health and environmental risk assessment of chemicals

Epigenetic mechanisms have gained relevance in human health and environmental studies, due to their pivotal role in disease, gene × environment interactions and adaptation to environmental change and/or contamination. Epigenetic mechanisms are highly responsive to external stimuli and a wide range of chemicals has been shown to determine specific epigenetic patterns in several organisms. Furthermore, the mitotic/meiotic inheritance of such epigenetic marks as well as the resulting changes in gene expression and cell/organismal phenotypes has now been demonstrated. Therefore, epigenetic signatures are interesting candidates for linking environmental exposures to disease as well as informing on past exposures to stressors. Accordingly, epigenetic biomarkers could be useful tools in both prospective and retrospective risk assessment but epigenetic endpoints are currently not yet incorporated into risk assessments. Achieving a better understanding on this apparent impasse, as well as identifying routes to promote the application of epigenetic biomarkers within environmental risk assessment frameworks are the objectives of this review. We first compile evidence from human health studies supporting the use of epigenetic exposure‐associated changes as reliable biomarkers of exposure. Then, specifically focusing on environmental science, we examine the potential and challenges of developing epigenetic biomarkers for environmental fields, and discuss useful organisms and appropriate sequencing techniques to foster their development in this context. Finally, we discuss the practical incorporation of epigenetic biomarkers in the environmental risk assessment of chemicals, highlighting critical data gaps and making key recommendations for future research within a regulatory context.     

Towards genetic markers in animal populations as biomonitors for human-induced environmental change

Genetic markers provide potentially sensitive indicators of changes in environmental conditions because the genetic constitution of populations is normally altered well before populations become extinct. Genetic indicators in populations include overall genetic diversity, genetic changes in traits measured at the phenotypic level, and evolution at specific loci under selection. While overall genetic diversity has rarely been successfully related to environmental conditions, genetically based changes in traits have now been linked to the presence of toxins and both local and global temperature shifts. Candidate loci for monitoring stressors are emerging from information on how specific genes influence traits, and from screens of random loci across environmental gradients. Drosophila research suggests that chromosomal regions under recent intense selection can be identified from patterns of molecular variation and a high frequency of transposable element insertions. Allele frequency changes at candidate loci have been linked to pesticides, pollutants and climate change. Nevertheless, there are challenges in interpreting allele frequencies in populations, particularly when a large number of loci control a trait and when interactions between alleles influence trait expression. To meet these challenges, population samples should be collected for longitudinal studies, and experimental programmes should be undertaken to link variation at candidate genes to ecological processes.     

DNA supercoiling is differentially regulated by environmental factors and FIS in Escherichia coli and Salmonella enterica

Although Escherichia coli and Salmonella enterica inhabit similar niches and employ similar genetic regulatory programmes, we find that they differ significantly in their DNA supercoiling responses to environmental and antibiotic challenges. Whereas E. coli demonstrates large dynamic transitions in supercoiling in response to growth phase, osmotic pressure and novobiocin treatment, supercoiling levels are much less variable in S. enterica. The FIS protein is a global regulator of supercoiling in E. coli, but it was found to have less influence over supercoiling control in S. enterica. These inter-species differences fine-tune gene promoters to endogenous supercoiling and FIS levels. Transferring a Salmonella virulence gene promoter (P(ssrA) ) into a new enteric host (E. coli) caused aberrant expression in response to stimulatory signals. Reciprocal horizontal transfer of topA promoters, which control expression of topoisomerase I, between E. coli and S. enterica revealed how these orthologous promoters have evolved to respond differentially to FIS and supercoiling levels in their cognate species. This also identified a previously unrecognized osmoregulation of topA expression that is independent of FIS and supercoiling in both E. coli and S. enterica. These findings suggest that E. coli and S. enterica may be unexpectedly divergent in their global regulation of cellular physiology.     

Changes in gene expression as biochemical adaptations to environmental change: a tribute to Peter Hochachka

Changes in gene expression are likely to play a critical role in both acclimation and adaptation to a changing environment. There is a rapidly growing body of literature implicating quantitative changes in gene expression during acclimation to environmental change, but less is known about the role of qualitative changes in gene expression, such as switching between alternative isoforms. Alternative isoforms can arise via gene duplication, alternative splicing, or alternative promoter usage. Organisms that have undergone recent genome duplication events may make use of environment-specific isoforms coded by multiple genes, but their role in other organisms is less well known. However, recent data suggest that isoforms arising from alternative splicing may be an under-appreciated source of physiological variation. The role of changes in gene expression during evolutionary adaptation has received comparatively limited attention, but novel approaches to addressing the adaptive significance of changes in gene expression have been applied to a few cases of differences in gene expression among taxa. Recent advances in genomics, including microarray technology, knock-out and knock-down approaches, and the wealth of data coming from large-scale sequencing projects have provided (and will continue to provide at ever increasing rates) new insights into these classic questions in comparative biochemistry.     

Specific proteomic adaptation to distinct environments in Vibrio parahaemolyticus includes significant fluctuations in expression of essential proteins

Bacteria constantly experience changes to their external milieu and need to adapt accordingly to ensure their survival. Certain bacteria adapt by means of cellular differentiation, resulting in the development of a specific cell type that is specialized for life in a distinct environment. Furthermore, to understand how bacteria adapt, it is essential to appreciate the significant changes that occur at the proteomic level. By analysing the proteome of our model organism Vibrio parahaemolyticus from distinct environmental conditions and cellular differential states, we demonstrate that the proteomic expression profile is highly flexible, which likely allows it to adapt to life in different environmental conditions and habitats. We show that, even within the same swarm colony, there are specific zones of cells with distinct expression profiles. Furthermore, our data indicate that cell surface attachment and swarmer cell differentiation are distinct programmes that require specific proteomic expression profiles. This likely allows V. parahaemolyticus to adapt to life in different environmental conditions and habitats. Finally, our analyses reveal that the expression profile of the essential protein pool is highly fluid, with significant fluctuations that dependent on the specific life-style, environment and differentiation state of the bacterium.     

Parallel genetic changes and nonparallel gene-environment interactions characterize the evolution of drug resistance in yeast

Beneficial mutations are required for adaptation to novel environments, yet the range of mutational pathways that are available to a population has been poorly characterized, particularly in eukaryotes. We assessed the genetic changes of the first mutations acquired during adaptation to a novel environment (exposure to the fungicide, nystatin) in 35 haploid lines of Saccharomyces cerevisiae. Through whole-genome resequencing we found that the genomic scope for adaptation was narrow; all adapted lines acquired a mutation in one of four late-acting genes in the ergosterol biosynthesis pathway, with very few other mutations found. Lines that acquired different ergosterol mutations in the same gene exhibited very similar tolerance to nystatin. All lines were found to have a cost relative to wild type in an unstressful environment; the level of this cost was also strongly correlated with the ergosterol gene bearing the mutation. Interestingly, we uncovered both positive and negative effects on tolerance to other harsh environments for mutations in the different ergosterol genes, indicating that these beneficial mutations have effects that differ in sign among environmental challenges. These results demonstrate that although the genomic target was narrow, different adaptive mutations can lead populations down different evolutionary pathways, with respect to their ability to tolerate (or succumb to) other environmental challenges.     

Challenges in applying microarrays to environmental studies

Although DNA microarray technology has been used successfully to analyze global gene expression in pure cultures, it has not been rigorously tested and evaluated within the context of complex environmental samples. Adapting microarray hybridization for use in environmental studies faces several challenges associated with specificity, sensitivity and quantitation.