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Record W2884957789 · doi:10.1093/eep/dvy012

Transgenerational epigenetic inheritance: from biology to society—Summary Latsis Symposium Aug 28–30, 2017, Zürich, Switzerland

2018· article· en· W2884957789 on OpenAlexaboutno aff
Johannes Bohacek, Olivia Engmann, Pierre‐Luc Germain, Silvia Schelbert, Isabelle M. Mansuy

Bibliographic record

VenueCurrent Zoology · 2018
Typearticle
Languageen
FieldBiochemistry, Genetics and Molecular Biology
TopicEpigenetics and DNA Methylation
Canadian institutionsnot available
FundersJohn S. Latsis Public Benefit Foundation
KeywordsInheritance (genetic algorithm)EpigeneticsTransgenerational epigeneticsBiologyGeneticsHeredityNon-Mendelian inheritanceGeneEvolutionary biology

Abstract

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In biology, inheritance is a process that ensures the transfer of features and traits from parent to offspring. The most classic view of parental inheritance is that it is genetic and is embedded in genes contained in the genome in germ cells. However, genetic inheritance is now known to contribute to only a part of what an individual can transmit to its progeny. Thus, further to innate traits that each individual receives from its parents, acquired traits, which are traits acquired upon exposure to environmental factors or personal experiences, can also be inherited. This form of inheritance is not encoded in the sequence of genes but is mediated by mechanisms and processes elicited by the environment that modify the activity of the genome persistently across generations. Because it is not encoded in DNA sequences, it is called epigenetic or non-genetic. These mechanisms establish a link between the genome and the environment. They relate to the extremely important question of nature versus nurture namely, how much our own make-up is genetically or epigenetically determined, a question that remains unresolved. In August 2017, an international symposium was organized in Zürich, Switzerland to address the question of epigenetic inheritance. The Latsis symposium 2017 on “Transgenerational epigenetic inheritance: from biology to society” held at the ETH Zürich gathered international leaders in the field and focused on major questions and current challenges raised by the concept of epigenetic inheritance. The symposium was one of the first fully dedicated to the theme of epigenetic inheritance and covered scientific aspects from invertebrates to humans, and from behavior to metabolism in humans and animal models, mental health and epidemiology, bioinformatics and ethics. The symposium lasted 2.5 days and was attended by about 150 people from different countries. The program was structured in sessions of 3–3 h 30 min each (total of five sessions) including invited talks and short oral presentations. This summary provides an overview of the speakers’ presentations and focuses on four major topics: (i) evidence and challenges for epigenetic inheritance in humans, (ii) new insight and major questions raised by work in animal models, (iii) methodologies in epigenetics and (iv) evolution, societal impact and broader considerations. The first session focused on clinical epigenetics, and was started by Marcus Pembrey (University College London) with a review of his long-standing work in epigenetic epidemiology, in particular related to food deprivation and smoking. He presented new DNA methylation (DNAme) results shedding light on possible mechanisms of transmission. His talk touched a number of issues critical to the field, from the identification of exposure-sensitive developmental periods to the interpretation of underlying gene and phenotypic differences between the first generations, and the discrepancy between symptoms transmission and changes in DNAme. Markus Pembrey presented recent work on the Avon Longitudinal Study of Parents and Children (ALSPAC), showing that autism risk is higher in granddaughters if the maternal grandmother has smoked during pregnancy. Autism is one of many devastating neuropsychiatric disorders in which exposure of past generations is likely to play an important role in disease etiology. This is a vivid example demonstrating the importance of research in the field of epigenetic inheritance and the high stakes regarding implications for patients and families. Another question addressed by Pembrey was that of the sensitive period during which the germline is particularly responsive to environmental factors. He reviewed the seminal work he did with Lars Olov Bygren on the impact of food availability on health and mortality of grandoffspring in the Överkalix cohort where the concept of sensitive period and transgenerational programming was first introduced. He pointed out that the effects of scarce food supply is difficult to disentangle from the effects of stress resulting from unfavorable living conditions and famine. This work highlights that early life experiences of parents and ancestors contribute to population developmental variation beyond that due to social transmission. Adelheid Soubry (University Leuven) then discussed different studies on the impact of paternal diet and exposure to chemicals on sperm and offspring. She presented an update on several large human cohort studies and new work on the impact of organophosphate (OP) flame retardants. Measuring OP levels in men and correlating it to DNAme in sperm revealed OP-related changes in DNAme at imprinted genes. An interesting finding was that “cocktail exposure” to several OPs was associated with increased DNAme aberrancies in sperm. This highlights a particular sensitivity of imprinted genes to pre-conception environmental exposure, and a non-additive effect of combining multiple exposures, suggesting that broad DNAme measurements should be more systematically considered in such studies. But DNAme is variable in sperm and some maternally derived DNAme loci are less methylated than expected, suggesting that great care is needed in comparative studies. Her ongoing research highlights an exciting new approach in human studies that includes analysis of sperm samples used for IVF and subsequent analysis of fertilized embryos (those not used for implantation). This resembles attempts made in mice and holds promise to unravel mechanistic links between sperm and embryo, a key challenge in basic research. Pursuing the theme of epigenetic changes induced by chemicals, Marisa Bartolemei (University of Pennsylvania, Philadelphia) presented her work on bisphenol A (BPA) exposure during pregnancy, showing that bile acids and tryptophan metabolism underlie metabolic disease induced in mother and male pups. New results show that these effects can be passed to descendants through the matriline, affecting male offspring. Beyond metabolism, skeletal health also seems to be affected by BPA treatment, which fits with the fact that ovarian hormones play a key role in bone health and points to research needs on the broad effects of chemicals and endocrine disruptors. But although compounds such as BPA, dichlorodiphenyltrichloroethane (DDT) or vinclozolin have long been at the center of studies on epigenetic inheritance, it is still unclear how they, or any environmental factors for that matter, can influence the germline. One possibility is that chemicals can interfere with endogenous factors that can bind directly to receptors expressed in/on germ cells. Indeed, Marine Baptissart (North Carolina State University, Raleigh) presented interesting work from her doctoral studies in the lab of David Volle, showing that a diet fortified with bile acids impacts sperm cells through the G protein-coupled bile acid receptor Tgr5, which is expressed in the germ cell lineage. Her latest data suggest that this effect can be transmitted and impacts DNA condensation due to altered histone/protamine transition, and DNAme in sperm, suggesting that a bile acid receptor in the germline could mediate epigenetic inheritance. To testify the importance of research in the field of epigenetic inheritance in human, Jill Escher (San Jose, CA), a philanthropist and mother of two children with non-verbal autism, presented a moving and personal account linking the tragic story of her family and many other families, with environmental risk factors. Ms Escher urged scientists to study the potential effects of environmental exposure on germ cells in utero and the neurodevelopmental outcomes, and presented the activities of her foundation, the Escher Fund for Autism, in support of such research. Moshe Szyf (McGill University, Montreal) discussed his work on how social stimuli, e.g. licking in rodents, rearing conditions or social rank in primates, and stress affect the epigenome in T cells and germ cells, and stress response in the offspring. He discussed the results of a prospective longitudinal study following the impact of an ice storm in Quebec in 1998, which left millions of Canadians without heat and at winter temperatures. Immune system changes and DNAme levels in T cells of teenage offspring were associated with mother’s exposure to the event during pregnancy. Noting that sperm contains glucocorticoid receptors (GR), he hypothesized that GR may be a link between germ cells and the metabolic and psychological uptake of stressful environments, and provided preliminary evidence for this. Other forms of population trauma and their consequences over generations were discussed by Rachel Yehuda (Mount Sinai Hospital, New York). She described the long-term consequences (up to over 50 years) of traumatically stressful experiences such as the Holocaust and 9/11, on survivors and their offspring, and the development of post-traumatic stress disorder (PTSD) and mood or affective disorders. She highlighted sex- and age-specific effects on cortisol levels and sensitivity, associated with changes in the methylation of key genes in related pathways, such as FKBP5, that can be opposite in exposed parents and offspring. In the search for resilience mechanisms, she proposed to “harness epigenetics for positive resilience building.” Of all environmental exposures that affect individuals and their offspring, diet is probably one of the most critical and much work has been done on its impact across generations in animals. Building on the notion in humans that the risk for obesity/diabetes can be transmitted, Josep Jimenez-Chillarón (Hospital Sant Joan de Deu, Barcelona) described a mouse model of adiposity based on increased milk intake during postnatal development achieved by reducing litter size. This manipulation leads to metabolic symptoms such as liver-mediated increase in adiposity and altered glucose tolerance, which persist for at least two generations, and are associated with changes in DNAme in sperm of exposed males and liver of the offspring. The metabolic phenotypes appear complex and differ across generations, consistent with the notion of differences between direct and transmitted effects (see below). An enrichment in tRNA fragments (tRFs) was also observed in the testes of exposed males, in line with previous findings that tRFs in sperm are altered by a nutritional insult. In search for underlying mechanisms, Vardhman Rakyan (Blizard Institute, London) presented results on the effects of protein restriction in mice in utero, showing a decrease in offspring weight specifically when switching from protein restriction to normal diet after weaning. This suggested here too that the effect results from a mismatch between early and late environment. This was associated with differential methylation and copy number alteration of a DNA locus with a specific genetic variant (A instead of C). Notably, the relative number of A variants determined the degree of DNAme upon exposure to protein restriction, suggesting an important mechanism for genotype–environment interaction. Considering the long-term consequences of environmental factors on a much larger time scale, Carlos Guerrero-Bosagna (Linköping University) exploited different breeds of domesticated chicken and their only living ancestor, the red jungle fowl, to analyze DNAme. Such analyzes revealed the possibility to accurately reconstruct chicken phylogeny. Preliminary results suggest that, likely through mechanisms of deamination, DNAme may impact the genome by leading to single-nucleotide polymorphisms (SNPs) or copy number variation (CNV). Interestingly, the probability of DNAme correlated with phylogenetic distance, and although the exact causal link is not yet established, these results suggest that environmentally-induced epimutations may drive genomic evolution, a concept he and Michael Skinner already proposed in Darwin finches. Dating back to the pioneering work of Michael Skinner indeed, endocrine disruptors and chemicals/pollutants have been another key focus of the field of epigenetic inheritance. At the symposium, Skinner gave a broad overview of almost two decades of research from his lab, detailing, cataloging and comparing the transgenerational impact of various compounds on physiological and cellular functions. His latest work comprehensively assessed changes in different epigenetic factors after exposure to the insecticide DDT. He showed that not only DNAme in differentially methylated regions (DMRs), but also short and long non-coding RNAs, and histone retention are altered in sperm after DDT exposure, and are passed to the following generation in a complex pattern, with little direct overlap between individual changes across generations. As one of the main contributors to the field who had long emphasized the important role of DNAme, he summarized the current state of research as follows: “All epigenetic processes are involved in epigenetic inheritance. We need to stop arguing which ones are or aren’t involved, they all seem to have different functions.” His systematic cross-generational analyzes brought new understanding that beyond epigenetic changes that are directly induced in germ cells of exposed individuals, other changes can emerge in the second or third generation, that do not necessarily match with those in the first generation. This points to a form of epigenetic dynamics across generations. Searching for direct overlap between changes in F1 and F3 might therefore not be that useful and informative. Regarding the mechanisms underlying epigenetic inheritance, a clear trend in the field is the focus on sperm RNAs as vectors of information transmission from father to offspring. Several speakers presented new data highlighting the involvement of RNA in epigenetic inheritance. Minoo Rassoulzadegan (University of Nice), who has pioneered the field of RNA-mediated epigenetic inheritance, introduced a new concept involving heritable RNAs. She showed how paternal telomere size, usually associated with lifespan, can be inherited. New data from her group suggest that telomeric repeat-containing RNAs (TERRAs), that bind to telomeres and regulate their length, are transmitted from sperm to oocyte upon fertilization. Indeed, telomere size is paternally inherited and associated with paternal lifespan, making these RNAs strong candidates for this transmission. Using a model of postnatal traumatic stress, Katharina Gapp (Sanger Institute, Cambridge) from the lab of Eric Miska then presented work on the causal involvement of sperm RNAs in epigenetic inheritance. She discussed new results highlighting that short and long non-coding RNAs must be considered together to understand their role in information transfer from sperm to oocyte/offspring. She showed that injection of long RNAs from the sperm of males exposed to traumatic stress in postnatal life into wild-type zygotes can recapitulate some of the phenotypes observed in directly exposed males, but short RNAs cannot or produce different effects, suggesting that long RNAs are also involved in transmission. A following talk on the same mouse model addressed the question of the potential vectors that alter the epigenome in germ cells. Before any substance can reach the germline and modify its epigenome, it needs to get to the testis and/or epididymis. This transport may occur through the bloodstream. Gretchen van Steenwyk from the lab of Isabelle Mansuy (University/ETH Zürich) showed that blood-borne factors are causally linked to the inheritance of phenotypes induced by postnatal trauma. Blood therefore appears as an important biological fluid, and highly relevant for translational approaches since it is easily accessible in humans. Further to humans and mice, several other animal models also provided mechanistic insight into epigenetic inheritance. Abhay Sharma (Delhi University) reported the transgenerational impact of high sugar diet on body weight and chromatin remodeling in Drosophila. Notably, an opposite phenotype is observed in F1 and F2, and the number and identity of affected genes are also different between females and males. A switching experimental design highlighted that it is not so much the diet itself, but rather the mismatch between parental and offspring diet that causes metabolic alterations. Eric Miska (University of Cambridge) discussed epigenetic inheritance in honey an interesting model system in which epigenetic mechanisms play a key role in the development of different of genetically He presented data on another of honey which is the to a RNA that can be in food and to a RNA data revealed that and RNA by a yet protein that and as a RNA to be into cells. Such system could be used to and other with University) from the lab of presented work on a in epigenetic inheritance research with a associated genetic She that the of epigenetic inheritance is by an This a which has been used to inheritance in after four generations. and challenges of studies were addressed during the discussed the of such as for epigenetic and the possibility to on the epigenetic of specific Such approach can a long-standing of epigenetics which has been its on and now for He the in and on and and discussed the potential of this such approaches are to in epigenetic more work is needed to and their To the and of epigenetic data by new of the of presented a of and approaches for in particular for the study of DNAme in He how epigenome can be used to the of of or for He also highlighted recent on cell and provided several important for and data and for epigenetic data on (University College London) discussed a of and insight in from analysis to and for epigenome in humans. 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(University of showed that has an only by and that is a in scientific studies the identification of epigenetic factors underlying or which a in the questions of then discussed critical issues in the the they and their studies showing the transmission of epigenetic associated with can be reported in that the and a of which is However, such results can also be by systematically the or of epigenetic and a more positive to is therefore critical to be of the social of the and the importance of the societal and impact of the concept and any related new in inheritance has as an extremely exciting field of with and study models and highly methodologies that are and The symposium was particularly in in the current and evidence in different experimental models and humans, and in current and important and about experimental and in the design of and human studies that are to research in the field in the Isabelle Mansuy We are extremely to the Latsis for the support and for the to the We also all other who provided support and the of and of the ETH Zürich for We are to the ETH Zürich for an for the event with and and the Zürich for We for with the for with and for the the and the This summary is a short account of the symposium to the major not associated with the or in are to or speakers were two sessions in the during which were presented by These sessions were extremely attended and a was to one at the of the The was sperm for experimental new in epigenetic and was presented by at the Institute, In to the Latsis symposium, a by Switzerland was organized at the of Zürich following the This the had four in the field of epigenetics, Isabelle Michael Skinner and Moshe Szyf questions from the The was attended by 30 A in environment and epigenetics changes the view on was presented by a scientific and This was for the and discussed the impact of the field on the with a on major societal was by an session during which the could talk to and get his is not by of

Fetched live from OpenAlex and de-inverted. Abstracts are not stored in this database: the inverted indexes are 8.6 GB of the frame’s 9.3 GB of text, and the host has 13 GB free.

How this classification was reachedexpand

Full frame distilled prediction

Teacher imitation

Not calibrated prevalence, not ground truth. Human validation pending. Learned from the 10,348 direct Codex labels and 10,348 direct Gemma labels. Candidate is the union of thresholded teacher heads; consensus is their intersection. These outputs are machine_predicted_unvalidated and are not human labels or direct frontier model labels.

metaresearch head score (Codex)0.000
metaresearch head score (Gemma)0.000
Version: codex-gemma-dda1882f352aValidation status: machine_predicted_unvalidated
Candidate categoriesMeta-epidemiology (narrow)
Consensus categoriesnone
DomainCandidate signal: none · Consensus signal: none
Study designCandidate signal: Bench or experimental · Consensus signal: none
GenreCandidate signal: Empirical · Consensus signal: Empirical
Teacher disagreement score0.521
Threshold uncertainty score1.000

Codex and Gemma teacher scores by category

CategoryCodexGemma
Metaresearch0.0000.000
Meta-epidemiology (narrow)0.0000.000
Meta-epidemiology (broad)0.0000.000
Bibliometrics0.0000.000
Science and technology studies0.0000.000
Scholarly communication0.0000.000
Open science0.0000.000
Research integrity0.0000.000
Insufficient payload (model declined to judge)0.0000.000

Machine scores (provisional)

The two teacher heads of the student model, read on this work. A score orders the frame for review; it never asserts a category, and the validation status ships verbatim with every row.

Baseline scores from an immature model (maturity gate not passed, 7 training rounds). Scores rank; they never assert a category.

Opus teacher head0.023
GPT teacher head0.303
Teacher spread0.279 · how far apart the two teachers sit on this one work
Validation statusscore_only:v0-immature-baseline · verbatim from the scoring run: score_only means the number may rank works, and no category label ships from it

Classification

machine, unvalidated

Machine predicted; a candidate call from one teacher head, not a consensus.

Study designBench or experimental
Domainnot available
GenreEmpirical

How this classification was reached, model by model and score by score, is at the end of the page under "How this classification was reached".

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Citations6
Published2018
Admission routes1
Has abstractyes

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