Your search keyword '"Morgan W. Kelly"' showing total 48 results

1. Comparative Transcriptomic Analyses Reveal Differences in the Responses of Diploid and Triploid Eastern Oysters to Environmental Stress

Author

Rujuta V. Vaidya, Sarah Bodenstein, Dildorakhon Rasulova, Jerome F. La Peyre, and Morgan W. Kelly

Subjects

Crassostrea virginica, gene expression, Gulf of Mexico, mortality, ploidy, salinity, Evolution, QH359-425

Abstract

ABSTRACT Triploid oysters are commonly used as the basis for production in the aquaculture of eastern oysters along the USA East and Gulf of Mexico coasts. While they are valued for their rapid growth, incidents of triploid mortality during summer months have been well documented in eastern oysters, especially at low salinity sites. We compared global transcriptomic responses of diploid and triploid oysters bred from the same three maternal source populations at two different hatcheries and outplanted to a high (annual mean salinity = 19.4 ± 6.7) and low (annual mean salinity = 9.3 ± 5.0) salinity site. Oysters were sampled for gene expression at the onset of a mortality event in the summer of 2021 to identify triploid‐specific gene expression patterns associated with low salinity sites, which ultimately experienced greater triploid mortality. We also examined chromosome‐specific gene expression to test for instances of aneuploidy in experimental triploid oyster lines, another possible contributor to elevated mortality in triploids. We observed a strong effect of hatchery conditions (cohort) on triploid‐specific mortality (field data) and a strong interactive effect of hatchery, ploidy, and outplant site on gene expression. At the low salinity site where triploid oysters experienced high mortality, we observed downregulation of transcripts related to calcium signaling, ciliary activity, and cell cycle checkpoints in triploids relative to diploids. These transcripts suggest dampening of the salinity stress response and problems during cell division as key cellular processes associated with elevated mortality risk in triploid oysters. No instances of aneuploidy were detected in our triploid oyster lines. Our results suggest that triploid oysters may be fundamentally less tolerant of rapid decreases in salinity, indicating that oyster farmers may need to limit the use of triploid oysters to sites with more stable salinity conditions.

Published

2024

2. Transcriptomic responses to hypoxia in two populations of eastern oyster with differing tolerance

Author

Emma L. Crable, Heather Rodriguez, Rujuta V. Vaidya, Nicholas Coxe, Jerome F. La Peyre, and Morgan W. Kelly

Subjects

hypoxia, climate change, Crassostrea virginica, transcriptomics, gene expression, local adaptation, Science, General. Including nature conservation, geographical distribution, QH1-199.5

Abstract

The eastern oyster, Crassostrea virginica, is a keystone species native to the Gulf of Mexico and Atlantic coasts of the United States and Canada. It provides habitat for other marine organisms and makes up the majority of oyster production in the United States. Despite its tolerance to hypoxic conditions, C. virginica is threatened by anthropogenic climate change, which is increasing both average temperature and the frequency and severity of hypoxic events. In this study, we explore the differences in hypoxia-transcriptional response between two populations of eastern oysters with known differences in hypoxia tolerance at three time points over the course of a 5-day hypoxia treatment. We identified sets of genes involved in the hypoxia response and found differences in both the timing and baseline expression of hypoxia-responsive genes between tolerant and sensitive populations, consistent with a scenario of local adaptation. Analysis of differential gene expression between the two populations and conditions revealed two gene modules with higher baseline expression of hypoxia-sensitive genes in the more hypoxia tolerant population. Key GO terms for genes corresponding to differences between populations include DNA repair, ribosome biogenesis, and ribonucleotide binding. Our results imply that differences in hypoxia tolerance between populations could be due to genetic frontloading of hypoxia response pathways in the more tolerant population.

Published

2024

3. Population epigenetic divergence exceeds genetic divergence in the Eastern oyster Crassostrea virginica in the Northern Gulf of Mexico

Author

Kevin M. Johnson and Morgan W. Kelly

Subjects

Crassostrea virginica, DNA methylation, epigenetics, oyster, reduced representation bisulfite sequencing, salinity, Evolution, QH359-425

Abstract

Abstract Populations may respond to environmental heterogeneity via evolutionary divergence or phenotypic plasticity. While evolutionary divergence occurs through DNA sequence differences among populations, plastic divergence among populations may be generated by changes in the epigenome. Here, we present the results of a genome‐wide comparison of DNA methylation patterns and genetic structure among four populations of Eastern oyster (Crassostrea virginica) in the northern Gulf of Mexico. We used a combination of restriction site‐associated DNA sequencing (RADseq) and reduced representation bisulfite sequencing (RRBS) to explore population structure, gene‐wide averages of FST, and DNA methylation differences between oysters inhabiting four estuaries with unique salinity profiles. This approach identified significant population structure despite a moderately low FST (0.02) across the freshwater boundary of the Mississippi river, a finding that may reflect recent efforts to restore oyster stock populations. Divergence between populations in CpG methylation was greater than for divergence in FST, likely reflecting environmental effects on DNA methylation patterns. Assessment of CpG methylation patterns across all populations identified that only 26% of methylated DNA was intergenic; and, only 17% of all differentially methylated regions (DMRs) were within these same regions. DMRs within gene bodies between sites were associated with genes known to be involved in DNA damage repair, ion transport, and reproductive timing. Finally, when assessing the correlation between genomic variation and DNA methylation between these populations, we observed population‐specific DNA methylation profiles that were not directly associated with single nucleotide polymorphisms or broader gene‐body mean FST trends. Our results suggest that C. virginica may use DNA methylation to generate environmentally responsive plastic phenotypes and that there is more divergence in methylation than divergence in allele frequencies.

Published

2020

4. Constitutive gene expression differs in three brain regions important for cognition in neophobic and non-neophobic house sparrows (Passer domesticus)

Author

Christine R. Lattin, Tosha R. Kelly, Morgan W. Kelly, and Kevin M. Johnson

Subjects

Medicine, Science

Abstract

Neophobia (aversion to new objects, food, and environments) is a personality trait that affects the ability of wildlife to adapt to new challenges and opportunities. Despite the ubiquity and importance of this trait, the molecular mechanisms underlying repeatable individual differences in neophobia in wild animals are poorly understood. We evaluated wild-caught house sparrows (Passer domesticus) for neophobia in the lab using novel object tests. We then selected a subset of neophobic and non-neophobic individuals (n = 3 of each, all females) and extracted RNA from four brain regions involved in learning, memory, threat perception, and executive function: striatum, caudal dorsomedial hippocampus, medial ventral arcopallium, and caudolateral nidopallium (NCL). Our analysis of differentially expressed genes (DEGs) used 11,889 gene regions annotated in the house sparrow reference genome for which we had an average of 25.7 million mapped reads/sample. PERMANOVA identified significant effects of brain region, phenotype (neophobic vs. non-neophobic), and a brain region by phenotype interaction. Comparing neophobic and non-neophobic birds revealed constitutive differences in DEGs in three of the four brain regions examined: hippocampus (12% of the transcriptome significantly differentially expressed), striatum (4%) and NCL (3%). DEGs included important known neuroendocrine mediators of learning, memory, executive function, and anxiety behavior, including serotonin receptor 5A, dopamine receptors 1, 2 and 5 (downregulated in neophobic birds), and estrogen receptor beta (upregulated in neophobic birds). These results suggest that some of the behavioral differences between phenotypes may be due to underlying gene expression differences in the brain. The large number of DEGs in neophobic and non-neophobic birds also implies that there are major differences in neural function between the two phenotypes that could affect a wide variety of behavioral traits beyond neophobia.

Published

2022

5. Characterizing the Epigenetic and Transcriptomic Responses to Perkinsus marinus Infection in the Eastern Oyster Crassostrea virginica

Author

Kevin M. Johnson, K. A. Sirovy, Sandra M. Casas, Jerome F. La Peyre, and Morgan W. Kelly

Subjects

DNA methylation, TagSeq, eastern oyster Crassostrea virginica, Perkinsus marinus disease, transcriptomics, weighted gene co-expression network analyses, Science, General. Including nature conservation, geographical distribution, QH1-199.5

Abstract

Eastern oysters in the northern Gulf of Mexico are routinely infected with the protistan parasite Perkinsus marinus, the cause of the disease commonly known as dermo. Recent experimental challenges among Atlantic coast populations have identified both resistant and susceptible genotypes using comparative transcriptomics. While controlled experimental challenges are essential first assessments, expanding this analysis to field reared individuals provides an opportunity to identify key genomic signatures of infection that appear both in the laboratory and in the field. In this study we combined reduced representation bisulfite sequencing with 3′ RNA sequencing (Tag-seq) to describe two molecular phenotypes associated with infection in oysters outplanted at a common garden field site. These combined approaches allowed us to examine changes in DNA methylation and gene expression for a large number of individuals (n = 40) that developed infections during the course of a common garden outplant experiment. Our epigenetic analysis of DNA methylation identified significant changes in gene body methylation associated with increasing infection intensity, across genes associated with immune responses. There was a smaller transcriptomic response to increasing infection intensities with 32 genes showing differential expression; however, only 40% of these genes were found to also be differentially methylated. While there was no clear pattern between direction of differential methylation and gene expression, there was a significant effect of percent methylation on gene-by-gene expression levels and the coefficient of variation in gene body methylation between treatments. These results show that in C. virginica, heavily methylated genes have high levels of gene expression with low levels of variation. Comparing our differential expression results with previously published experimental P. marinus challenges identified overlapping expression patterns for genes associated with C1q-domain-containing and V-type proton ATPase proteins. Through our comparative transcriptomic approach using field reared individuals and co-expression network analysis we have also been able to identify a network of genes that change in expression in response to infection. These combined analyses provide evidence for a conserved response to P. marinus infections across infection intensities and suggest that DNA methylation may not be a reliable predictor of differential gene expression in long-term infections.

Published

2020

6. Host and Symbionts in Pocillopora damicornis Larvae Display Different Transcriptomic Responses to Ocean Acidification and Warming

Author

Emily B. Rivest, Morgan W. Kelly, Melissa B. DeBiasse, and Gretchen E. Hofmann

Subjects

coral larvae, ocean acidification, ocean warming, holobiont, transcriptomics, Symbiodinium, Science, General. Including nature conservation, geographical distribution, QH1-199.5

Abstract

As global ocean change progresses, reef-building corals and their early life history stages will rely on physiological plasticity to tolerate new environmental conditions. Larvae from brooding coral species contain algal symbionts upon release, which assist with the energy requirements of dispersal and metamorphosis. Global ocean change threatens the success of larval dispersal and settlement by challenging the performance of the larvae and of the symbiosis. In this study, larvae of the reef-building coral Pocillopora damicornis were exposed to elevated pCO2 and temperature to examine the performance of the coral and its symbionts in situ and better understand the mechanisms of physiological plasticity and stress tolerance in response to multiple stressors. We generated a de novo holobiont transcriptome containing coral host and algal symbiont transcripts and bioinformatically filtered the assembly into host and symbiont components for downstream analyses. Seventeen coral genes were differentially expressed in response to the combined effects of pCO2 and temperature. In the symbiont, 89 genes were differentially expressed in response to pCO2. Our results indicate that many of the whole-organism (holobiont) responses previously observed for P. damicornis larvae in scenarios of ocean acidification and warming may reflect the physiological capacity of larvae to cope with the environmental changes without expressing additional protective mechanisms. At the holobiont level, the results suggest that the responses of symbionts to future ocean conditions could play a large role in shaping success of coral larval stages.

Published

2018

7. Greater evolutionary divergence of thermal limits within marine than terrestrial species

Author

Matthew Sasaki, Jordanna M. Barley, Sarah Gignoux-Wolfsohn, Cynthia G. Hays, Morgan W. Kelly, Alysha B. Putnam, Seema N. Sheth, Andrew R. Villeneuve, and Brian S. Cheng

Subjects

Environmental Science (miscellaneous), Social Sciences (miscellaneous)

Published

2022

8. Comparative transcriptomics reveals altered species interaction between the bioeroding sponge Cliona varians and the coral Porites furcata under ocean acidification

Author

Melissa B. DeBiasse, Amber D. Stubler, and Morgan W. Kelly

Subjects

Coral Reefs, Oceans and Seas, Genetics, Animals, Seawater, Hydrogen-Ion Concentration, Anthozoa, Transcriptome, Ecosystem, Ecology, Evolution, Behavior and Systematics, Porifera

Abstract

Bioeroding sponges interact and compete with corals on tropical reefs. Experimental studies have shown global change alters this biotic interaction, often in favour of the sponge. Ocean acidification in particular increases sponge bioerosion and reduces coral calcification, yet little is known about the molecular basis of these changes. We used RNA-Seq data to understand how acidification impacts the interaction between the bioeroding sponge, Cliona varians, and the coral, Porites furcata, at the transcriptomic level. Replicate sponge and coral genets were exposed to ambient (8.1 pH) and acidified (7.6 pH) conditions in isolation and in treatments where they were joined for 48 h. The coral had a small gene expression response (tens of transcripts) to the sponge, suggesting it does little at the transcriptomic level to deter sponge overgrowth. By contrast, the sponge differentially expressed 7320 transcripts in response to the coral under ambient conditions and 3707 transcripts in response to acidification. Overlap in the responses to acidification and the coral, 2500 transcripts expressed under both treatments, suggests a similar physiological response to both cues. The sponge expressed 50× fewer transcripts in response to the coral under acidification, suggesting energetic costs of bioerosion, and other cellular processes, are lower for sponges under acidification. Our results suggest how acidification drives ecosystem-level changes in the accretion/bioerosion balance on coral reefs. This shift is not only the result of changes to the thermodynamic balance of these chemical reactions but also the result of active physiological responses of organisms to each other and their abiotic environment.

Published

2022

9. Lack of genotype‐by‐environment interaction suggests limited potential for evolutionary changes in plasticity in the eastern oyster, Crassostrea virginica

Author

Kevin M. Johnson, Kyle A. Sirovy, Jerome F. La Peyre, Morgan W. Kelly, and Sandra M. Casas

Subjects

Salinity, Oyster, Genotype, Environmental change, biology, fungi, biology.organism_classification, Nucleotide diversity, Evolutionary biology, Perkinsus marinus, biology.animal, Genetics, Animals, Humans, Crassostrea, Gene-Environment Interaction, Gene–environment interaction, Transcriptome, Eastern oyster, Ecology, Evolution, Behavior and Systematics

Abstract

Eastern oysters in the northern Gulf of Mexico are facing rapid environmental changes and can respond to this change via plasticity or evolution. Plasticity can act as an immediate buffer against environmental change, but this buffering could impact the organism's ability to evolve in subsequent generations. While plasticity and evolution are not mutually exclusive, the relative contribution and interaction between them remains unclear. In this study, we investigate the roles of plastic and evolved responses to environmental variation and Perkinsus marinus infection in Crassostrea virginica by using a common garden experiment with 80 oysters from six families outplanted at two field sites naturally differing in salinity. We use growth data, P. marinus infection intensities, 3' RNA sequencing (TagSeq) and low-coverage whole-genome sequencing to identify the effect of genotype, environment and genotype-by-environment interaction on the oyster's response to site. As one of first studies to characterize the joint effects of genotype and environment on transcriptomic and morphological profiles in a natural setting, we demonstrate that C. virginica has a highly plastic response to environment and that this response is parallel among genotypes. We also find that genes responding to genotype have distinct and opposing profiles compared to genes responding to environment with regard to expression levels, Ka/Ks ratios and nucleotide diversity. Our findings suggest that C. virginica may be able to buffer the immediate impacts of future environmental changes by altering gene expression and physiology, but the lack of genetic variation in plasticity suggests limited capacity for evolved responses.

Published

2021

10. Evolutionary Change in the Eastern Oyster, Crassostrea Virginica, Following Low Salinity Exposure

Author

Joanna S Griffiths, Kevin M. Johnson, and Morgan W. Kelly

Subjects

Salinity, Oyster, education.field_of_study, Natural selection, Ecology, fungi, Population, Plant Science, Biology, biology.organism_classification, Biological Evolution, Genetic load, Larva, biology.animal, Genetic variation, Animals, Crassostrea, Animal Science and Zoology, education, Eastern oyster

Abstract

Synopsis The presence of standing genetic variation will play a role in determining a population's capacity to adapt to environmentally relevant stressors. In the Gulf of Mexico, extreme climatic events and anthropogenic changes to local hydrology will expose productive oyster breeding grounds to stressful low salinity conditions. We identified genetic variation for performance under low salinity (due to the combined effects of low salinity and genetic load) using a single-generation selection experiment on larvae from two populations of the eastern oyster, Crassostrea virginica. We used pool-sequencing to test for allele frequency differences at 152 salinity-associated genes for larval families pre- and post-low salinity exposure. Our results have implications for how evolutionary change occurs during early life history stages at environmentally relevant salinities. Consistent with observations of high genetic load observed in oysters, we demonstrate evidence for purging of deleterious alleles at the larval stage in C. virginica. In addition, we observe increases in allele frequencies at multiple loci, suggesting that natural selection for low salinity performance at the larval stage can act as a filter for genotypes found in adult populations.

Published

2021

11. Selection Experiments in the Sea: What Can Experimental Evolution Tell Us About How Marine Life Will Respond to Climate Change?

Author

Joanna S Griffiths and Morgan W. Kelly

Subjects

Experimental evolution, Extinction, Ecology, Climate Change, Climate change, Marine life, Biology, Adaptation, Physiological, Phenotype, Phytoplankton, Threatened species, General Agricultural and Biological Sciences, Ecosystem, Selection (genetic algorithm)

Abstract

Rapid evolution may provide a buffer against extinction risk for some species threatened by climate change; however, the capacity to evolve rapidly enough to keep pace with changing environments is unknown for most taxa. The ecosystem-level consequences of climate adaptation are likely to be the largest in marine ecosystems, where short-lived phytoplankton with large effective population sizes make up the bulk of primary production. However, there are substantial challenges to predicting climate-driven evolution in marine systems, including multiple simultaneous axes of change and considerable heterogeneity in rates of change, as well as the biphasic life cycles of many marine metazoans, which expose different life stages to disparate sources of selection. A critical tool for addressing these challenges is experimental evolution, where populations of organisms are directly exposed to controlled sources of selection to test evolutionary responses. We review the use of experimental evolution to test the capacity to adapt to climate change stressors in marine species. The application of experimental evolution in this context has grown dramatically in the past decade, shedding light on the capacity for evolution, associated trade-offs, and the genetic architecture of stress-tolerance traits. Our goal is to highlight the utility of this approach for investigating potential responses to climate change and point a way forward for future studies.

Published

2021

12. Transcriptomic signatures of temperature adaptation in the eastern oyster Crassostrea virginica

Author

Kevin M. Johnson, Morgan W. Kelly, Hollis R. Jones, Sandra M. Casas, and Jerome F. La Peyre

Subjects

education.field_of_study, Natural selection, Range (biology), Acclimatization, Population, Temperature, Zoology, Marine invertebrates, Biology, biology.organism_classification, Adaptation, Physiological, Animals, Humans, Crassostrea, Adaptation, Transcriptome, Eastern oyster, education, Ecology, Evolution, Behavior and Systematics

Abstract

The large geographic distribution of the eastern oyster, Crassostrea virginica, makes it an ideal species to test how populations have adapted to latitudinal gradients in temperature. Despite inhabiting distinct thermal regimes, populations of C. virginica near the species' southern and northern geographic range show no population differences in their physiological response to temperature. In this study, we used comparative transcriptomics to understand how oysters from either end of the species' range maintain enantiostasis across three acclimation temperatures (10, 20, and 30°C). With this approach, we identified genes that were differentially expressed in response to temperature between individuals of C. virginica collected from New Brunswick, Canada and Louisiana, USA. We observed a core set of genes whose expression responded to temperature in both populations, but also an even larger set of genes with expression patterns that were unique to each population. Intriguingly, the genes with population-specific responses to temperature had elevated FST and Ka/Ks ratios compared to the genome-wide average. In contrast, genes showing only a response to temperature were found to only have elevated FST values suggesting that divergent FST may be due to selection on linked regulatory regions rather than positive selection on protein coding regions. Taken together, our results suggest that, despite coarse-scale physiological similarities, natural selection has shaped divergent gene expression responses to temperature in geographically separated populations of this broadly eurythermal marine invertebrate.

Published

2021

13. Differential hypoxia tolerance of eastern oysters from the northern Gulf of Mexico at elevated temperature

Author

Nicholas Coxe, Sandra M. Casas, Danielle A. Marshall, Megan K. La Peyre, Morgan W. Kelly, and Jerome F. La Peyre

Subjects

Aquatic Science, Ecology, Evolution, Behavior and Systematics

Published

2023

14. Greater local adaptation to temperature in the ocean than on land

Author

Jordanna Barley, Matthew C. Sasaki, Morgan W. Kelly, Sarah A. Gignoux-Wolfsohn, Brian S. Cheng, Cynthia G. Hays, Seema N. Sheth, Andrew R. Villeneuve, and Alysha B. Putnam

Subjects

Climatology, Environmental science, Local adaptation

Abstract

Warming threatens biodiversity but there is considerable uncertainty in which species and ecosystems are most vulnerable. Moreover, our understanding of organismal sensitivity is largely centered on species level assessments, which do not consider variation across populations. Here, we used meta-analysis to quantify differentiation in thermal tolerance across 413 populations from 105 species living in terrestrial, marine, and freshwater realms. Strikingly, we found strong differentiation in heat tolerance across populations in marine and intertidal taxa but not terrestrial or freshwater taxa. This is counter to the expectation that increased dispersal potential in the ocean should reduce intraspecific variation. Our findings are consistent with the “Bogert effect” operating in terrestrial but not marine ecosystems, which predicts that behavioral thermoregulation constrains evolution. Such adaptive differentiation in the ocean suggests that there may be standing genetic variation at the species level to buffer climate impacts. Assessments of organismal vulnerability to warming, especially in marine species, should account for variation in thermal tolerance among populations or risk under- or overestimating climate vulnerability.

Published

2021

15. Limited plasticity in thermally tolerant ectotherm populations: evidence for a trade-off

Author

Brian S. Cheng, Andrew R. Villeneuve, Morgan W. Kelly, Seema N. Sheth, Alysha B. Putnam, Jordanna Barley, Cynthia G. Hays, Matthew C. Sasaki, and Sarah A. Gignoux-Wolfsohn

Subjects

Thermotolerance, Phenotypic plasticity, Extinction, General Immunology and Microbiology, Ecology, Acclimatization, Climate Change, Temperature, Climate change, General Medicine, Plasticity, Biology, Trade-off, Adaptation, Physiological, General Biochemistry, Genetics and Molecular Biology, Heat tolerance, Ectotherm, General Agricultural and Biological Sciences, Ecosystem, General Environmental Science, Local adaptation

Abstract

Many species face extinction risks owing to climate change, and there is an urgent need to identify which species' populations will be most vulnerable. Plasticity in heat tolerance, which includes acclimation or hardening, occurs when prior exposure to a warmer temperature changes an organism's upper thermal limit. The capacity for thermal acclimation could provide protection against warming, but prior work has found few generalizable patterns to explain variation in this trait. Here, we report the results of, to our knowledge, the first meta-analysis to examine within-species variation in thermal plasticity, using results from 20 studies (19 species) that quantified thermal acclimation capacities across 78 populations. We used meta-regression to evaluate two leading hypotheses. The climate variability hypothesis predicts that populations from more thermally variable habitats will have greater plasticity, while the trade-off hypothesis predicts that populations with the lowest heat tolerance will have the greatest plasticity. Our analysis indicates strong support for the trade-off hypothesis because populations with greater thermal tolerance had reduced plasticity. These results advance our understanding of variation in populations' susceptibility to climate change and imply that populations with the highest thermal tolerance may have limited phenotypic plasticity to adjust to ongoing climate warming.

Published

2021

16. Synergistic Effects of Temperature and Salinity on the Gene Expression and Physiology of Crassostrea virginica

Author

Morgan W. Kelly, Kevin M. Johnson, and Hollis R. Jones

Subjects

0106 biological sciences, 0301 basic medicine, Salinity, Oyster, Hot Temperature, Temperature salinity diagrams, Gene Expression, Physiology, Plant Science, 010603 evolutionary biology, 01 natural sciences, 03 medical and health sciences, biology.animal, Respiration, Animals, Ecosystem, 14. Life underwater, Crassostrea, biology, Louisiana, biology.organism_classification, 030104 developmental biology, Osmolyte, Animal Science and Zoology, Eastern oyster

Abstract

The eastern oyster, Crassostrea virginica, forms reefs that provide critical services to the surrounding ecosystem. These reefs are at risk from climate change, in part because altered rainfall patterns may amplify local fluctuations in salinity, impacting oyster recruitment, survival, and growth. As in other marine organisms, warming water temperatures might interact with these changes in salinity to synergistically influence oyster physiology. In this study, we used comparative transcriptomics, measurements of physiology, and a field assessment to investigate what phenotypic changes C. virginica uses to cope with combined temperature and salinity stress in the Gulf of Mexico. Oysters from a historically low salinity site (Sister Lake, LA) were exposed to fully crossed temperature (20°C and 30°C) and salinity (25, 15, and 7 PSU) treatments. Using comparative transcriptomics on oyster gill tissue, we identified a greater number of genes that were differentially expressed (DE) in response to low salinity at warmer temperatures. Functional enrichment analysis showed low overlap between genes DE in response to thermal stress compared with hypoosmotic stress and identified enrichment for gene ontologies associated with cell adhesion, transmembrane transport, and microtubule-based process. Experiments also showed that oysters changed their physiology at elevated temperatures and lowered salinity, with significantly increased respiration rates between 20°C and 30°C. However, despite the higher energetic demands, oysters did not increase their feeding rate. To investigate transcriptional differences between populations in situ, we collected gill tissue from three locations and two time points across the Louisiana Gulf coast and used quantitative PCR to measure the expression levels of seven target genes. We found an upregulation of genes that function in osmolyte transport, oxidative stress mediation, apoptosis, and protein synthesis at our low salinity site and sampling time point. In summary, oysters altered their phenotype more in response to low salinity at higher temperatures as evidenced by a higher number of DE genes during laboratory exposure, increased respiration (higher energetic demands), and in situ differential expression by season and location. These synergistic effects of hypoosmotic stress and increased temperature suggest that climate change will exacerbate the negative effects of low salinity exposure on eastern oysters.

Published

2019

17. An Experimental Test of Adaptive Introgression in Locally Adapted Populations of Splash Pool Copepods

Author

Yasmeen Kawji, Joanna S Griffiths, Morgan W. Kelly, and Melissa, Wilson

Subjects

0106 biological sciences, Male, Thermotolerance, copepods, Population, Adaptation, Biological, Introgression, selection, AcademicSubjects/SCI01180, Genetic Introgression, 010603 evolutionary biology, 01 natural sciences, Copepoda, 03 medical and health sciences, Gene Frequency, Genetic, Genetics, Tigriopus californicus, Animals, 2.1 Biological and endogenous factors, Selection, Genetic, Allele, Adaptation, adaptive introgression, Aetiology, education, Molecular Biology, Allele frequency, Discoveries, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Hybrid, 0303 health sciences, education.field_of_study, Evolutionary Biology, biology, Whole Genome Sequencing, Human Genome, AcademicSubjects/SCI01130, heat tolerance, biology.organism_classification, Biological, Polygene, Evolutionary biology, Female, Biochemistry and Cell Biology

Abstract

As species struggle to keep pace with the rapidly warming climate, adaptive introgression of beneficial alleles from closely related species or populations provides a possible avenue for rapid adaptation. We investigate the potential for adaptive introgression in the copepod, Tigriopus californicus, by hybridizing two populations with divergent heat tolerance limits. We subjected hybrids to strong heat selection for 15 generations followed by whole-genome resequencing. Utilizing a hybridize evolve and resequence (HER) technique, we can identify loci responding to heat selection via a change in allele frequency. We successfully increased the heat tolerance (measured as LT50) in selected lines, which was coupled with higher frequencies of alleles from the southern (heat tolerant) population. These repeatable changes in allele frequencies occurred on all 12 chromosomes across all independent selected lines, providing evidence that heat tolerance is polygenic. These loci contained genes with lower protein-coding sequence divergence than the genome-wide average, indicating that these loci are highly conserved between the two populations. In addition, these loci were enriched in genes that changed expression patterns between selected and control lines in response to a nonlethal heat shock. Therefore, we hypothesize that the mechanism of heat tolerance divergence is explained by differential gene expression of highly conserved genes. The HER approach offers a unique solution to identifying genetic variants contributing to polygenic traits, especially variants that might be missed through other population genomic approaches.

Published

2021

18. Author response for 'Transcriptomic signatures of temperature adaptation in the eastern oyster Crassostrea virginica'

Author

Hollis R. Jones, Kevin M. Johnson, Morgan W. Kelly, Jerome F. La Peyre, and Sandra M. Casas

Subjects

Transcriptome, biology, Ecology, Crassostrea, Adaptation, Eastern oyster, biology.organism_classification

Published

2021

19. OUP accepted manuscript

Author

Terence A. Palmer, F. Scott Rikard, Natasha Breaux, William C. Walton, Danielle A. Marshall, Morgan W. Kelly, Sandra M. Casas, Megan K. La Peyre, Jerome F. La Peyre, and Jennifer Beseres Pollack

Subjects

Oyster, education.field_of_study, geography, geography.geographical_feature_category, biology, Physiology, Ecological Modeling, Population, Estuary, Management, Monitoring, Policy and Law, biology.organism_classification, Salinity, Fishery, Perkinsus marinus, biology.animal, Crassostrea, Eastern oyster, education, Bay, Nature and Landscape Conservation

Abstract

The eastern oyster, Crassostrea virginica, is a foundation species within US Gulf of Mexico (GoM) estuaries that has experienced substantial population declines. As changes from management and climate are expected to continue to impact estuarine salinity, understanding how local oyster populations might respond and identifying populations with adaptations to more extreme changes in salinity could inform resource management, including restoration and aquaculture programs. Wild oysters were collected from four estuarine sites from Texas [Packery Channel (PC): 35.5, annual mean salinity, Aransas Bay (AB): 23.0] and Louisiana [Calcasieu Lake (CL): 16.2, Vermilion Bay (VB): 7.4] and spawned. The progeny were compared in field and laboratory studies under different salinity regimes. For the field study, F1 oysters were deployed at low (6.4) and intermediate (16.5) salinity sites in Alabama. Growth and mortality were measured monthly. Condition index and Perkinsus marinus infection intensity were measured quarterly. For the laboratory studies, mortality was recorded in F1 oysters that were exposed to salinities of 2.0, 4.0, 20.0/22.0, 38.0 and 44.0 with and without acclimation. The results of the field study and laboratory study with acclimation indicated that PC oysters are adapted to high-salinity conditions and do not tolerate very low salinities. The AB stock had the highest plasticity as it performed as well as the PC stock at high salinities and as well as Louisiana stocks at the lowest salinity. Louisiana stocks did not perform as well as the Texas stocks at high salinities. Results from the laboratory studies without salinity acclimation showed that all F1 stocks experiencing rapid mortality at low salinities when 3-month oysters collected at a salinity of 24 were used and at both low and high salinities when 7-month oysters collected at a salinity of 14.5 were used.

Published

2021

20. Constitutive gene expression differs in three brain regions important for cognition in neophobic and non-neophobic house sparrows (Passer domesticus)

Author

Tosha R. Kelly, Morgan W. Kelly, Christine R. Lattin, and Kevin M. Johnson

Subjects

Genetics, Arcopallium, Sparrow, Multidisciplinary, biology, Neophobia, Brain, Gene Expression, Hippocampus, Animals, Wild, medicine.disease, Phenotype, Transcriptome, Cognition, biology.animal, medicine, Animals, Nidopallium, Female, Gene, Sparrows

Abstract

Neophobia (aversion to new objects, food, and environments) is a personality trait that affects the ability of wildlife to adapt to new challenges and opportunities. Despite the ubiquity and importance of this trait, the molecular mechanisms underlying repeatable individual differences in neophobia in wild animals are poorly understood. We evaluated wild-caught house sparrows (Passer domesticus) for neophobia in the lab using novel object tests. We then selected the most and least neophobic individuals (n=3 of each) and extracted RNA from four brain regions involved in learning, memory, threat perception, and executive function: striatum, dorsomedial hippocampus, medial ventral arcopallium, and caudolateral nidopallium (NCL). Our analysis of differentially expressed genes (DEGs) used 11,889 gene regions annotated in the house sparrow reference genome for which we had an average of 25.7 million mapped reads/sample. PERMANOVA identified significant effects of brain region, phenotype (neophobic vs. non-neophobic), and a brain region by phenotype interaction. Comparing neophobic and non-neophobic birds revealed constitutive differences in DEGs in three of the four brain regions examined: hippocampus (12% of the transcriptome significantly differentially expressed), striatum (4%) and NCL (3%). DEGs included important known neuroendocrine mediators of learning, memory, executive function, and anxiety behavior, including serotonin receptor 5A, dopamine receptors 1, 2 and 5 (downregulated in neophobic birds), and estrogen receptor beta (upregulated in neophobic birds). These results suggest that some of the behavioral differences between phenotypes may be due to underlying gene expression differences in the brain. The large number of DEGs in neophobic and non-neophobic birds also implies that there are major differences in neural function between the two phenotypes that could affect a wide variety of behavioral traits beyond neophobia.

Published

2022

21. Characterizing the Epigenetic and Transcriptomic Responses to Perkinsus marinus Infection in the Eastern Oyster Crassostrea virginica

Author

Kyle A. Sirovy, Morgan W. Kelly, Jerome F. La Peyre, Kevin M. Johnson, and Sandra M. Casas

Subjects

weighted gene co-expression network analyses, lcsh:QH1-199.5, Ocean Engineering, lcsh:General. Including nature conservation, geographical distribution, Aquatic Science, Perkinsus marinus disease, Oceanography, Transcriptome, transcriptomics, Perkinsus marinus, Gene expression, Epigenetics, lcsh:Science, Gene, Water Science and Technology, Genetics, Global and Planetary Change, DNA methylation, biology, eastern oyster Crassostrea virginica, Methylation, biology.organism_classification, Reduced representation bisulfite sequencing, lcsh:Q, TagSeq

Abstract

Eastern oysters in the northern Gulf of Mexico are routinely infected with the protistan parasite Perkinsus marinus, the cause of the disease commonly known as dermo. Recent experimental challenges among Atlantic coast populations have identified both resistant and susceptible genotypes using comparative transcriptomics. While controlled experimental challenges are essential first assessments, expanding this analysis to field reared individuals provides an opportunity to identify key genomic signatures of infection that appear both in the laboratory and in the field. In this study we combined reduced representation bisulfite sequencing with 3′ RNA sequencing (Tag-seq) to describe two molecular phenotypes associated with infection in oysters outplanted at a common garden field site. These combined approaches allowed us to examine changes in DNA methylation and gene expression for a large number of individuals (n = 40) that developed infections during the course of a common garden outplant experiment. Our epigenetic analysis of DNA methylation identified significant changes in gene body methylation associated with increasing infection intensity, across genes associated with immune responses. There was a smaller transcriptomic response to increasing infection intensities with 32 genes showing differential expression; however, only 40% of these genes were found to also be differentially methylated. While there was no clear pattern between direction of differential methylation and gene expression, there was a significant effect of percent methylation on gene-by-gene expression levels and the coefficient of variation in gene body methylation between treatments. These results show that in C. virginica, heavily methylated genes have high levels of gene expression with low levels of variation. Comparing our differential expression results with previously published experimental P. marinus challenges identified overlapping expression patterns for genes associated with C1q-domain-containing and V-type proton ATPase proteins. Through our comparative transcriptomic approach using field reared individuals and co-expression network analysis we have also been able to identify a network of genes that change in expression in response to infection. These combined analyses provide evidence for a conserved response to P. marinus infections across infection intensities and suggest that DNA methylation may not be a reliable predictor of differential gene expression in long-term infections.

Published

2020

22. Transcriptomics reveal transgenerational effects in purple sea urchin embryos: Adult acclimation to upwelling conditions alters the response of their progeny to differential p CO 2 levels

Author

Kevin M. Johnson, Morgan W. Kelly, Juliet M. Wong, and Gretchen E. Hofmann

Subjects

0106 biological sciences, 0301 basic medicine, Environmental change, biology, Mechanism (biology), Offspring, Maternal effect, Zoology, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Acclimatization, Strongylocentrotus purpuratus, Transcriptome, 03 medical and health sciences, 030104 developmental biology, Genetics, Upwelling, Ecology, Evolution, Behavior and Systematics

Abstract

Understanding the mechanisms with which organisms can respond to a rapidly changing ocean is an important research priority in marine sciences, especially in the light of recent predictions regarding the pace of ocean change in the coming decades. Transgenerational effects, in which the experience of the parental generation can shape the phenotype of their offspring, may serve as such a mechanism. In this study, adult purple sea urchins, Strongylocentrotus purpuratus, were conditioned to regionally and ecologically relevant pCO2 levels and temperatures representative of upwelling (colder temperature and high pCO2 ) and nonupwelling (average temperature and low pCO2 ) conditions typical of coastal upwelling regions in the California Current System. Following 4.5 months of conditioning, adults were spawned and offspring were raised under either high or low pCO2 levels, to examine the role of maternal effects. Using RNA-seq and comparative transcriptomics, our results indicate that differential conditioning of the adults had an effect on the gene expression patterns of the progeny during the gastrula stage of early development. For example, maternal conditioning under upwelling conditions intensified the transcriptomic response of the progeny when they were raised under high versus low pCO2 conditions. Additionally, mothers that experienced upwelling conditions produced larger progeny. The overall findings of this study are complex, but do suggest that transgenerational plasticity in situ could act as an important mechanism by which populations might keep pace with rapid environmental change.

Published

2018

23. Tolerance of northern Gulf of Mexico eastern oysters to chronic warming at extreme salinities

Author

Morgan W. Kelly, F. Scott Rikard, Megan K. La Peyre, Jennifer Beseres Pollack, Jerome F. La Peyre, Nicholas C. Coxe, William C. Walton, and Danielle A. Marshall

Subjects

Thermotolerance, Low salinity, Physiology, Subtropics, Global Warming, Biochemistry, Aquaculture, Animals, Biomass, Crassostrea, Gulf of Mexico, geography, geography.geographical_feature_category, biology, business.industry, Estuary, Salt Tolerance, biology.organism_classification, Salinity, Fishery, Environmental science, Thermal limit, General Agricultural and Biological Sciences, Eastern oyster, business, Developmental Biology

Abstract

The eastern oyster, Crassostrea virginica, provides critical ecosystem services and supports valuable fishery and aquaculture industries in northern Gulf of Mexico (nGoM) subtropical estuaries where it is grown subtidally. Its upper critical thermal limit is not well defined, especially when combined with extreme salinities. The cumulative mortalities of the progenies of wild C. virginica from four nGoM estuaries differing in mean annual salinity, acclimated to low (4.0), moderate (20.0), and high (36.0) salinities at 28.9 °C (84 °F) and exposed to increasing target temperatures of 33.3 °C (92 °F), 35.6 °C (96 °F) or 37.8 °C (100 °F), were measured over a three-week period. Oysters of all stocks were the most sensitive to increasing temperatures at low salinity, dying quicker (i.e., lower median lethal time, LT50) than at the moderate and high salinities and resulting in high cumulative mortalities at all target temperatures. Oysters of all stocks at moderate salinity died the slowest with high cumulative mortalities only at the two highest temperatures. The F1 oysters from the more southern and hypersaline Upper Laguna Madre estuary were generally more tolerant to prolonged higher temperatures (higher LT50) than stocks originating from lower salinity estuaries, most notably at the highest salinity. Using the measured temperatures oysters were exposed to, 3-day median lethal Celsius degrees (LD50) were estimated for each stock at each salinity. The lowest 3-day LD50 (35.1–36.0 °C) for all stocks was calculated at a salinity of 4.0, while the highest 3-day LD50 (40.1–44.0 °C) was calculated at a salinity of 20.0.

Published

2021

24. Trait Correlations in the Genomics Era

Author

Frances C. Hessel, Julia B. Saltz, and Morgan W. Kelly

Subjects

0106 biological sciences, 0301 basic medicine, Linkage (software), Genetics, Linkage disequilibrium, Models, Genetic, Quantitative Trait Loci, Genetic Variation, Genomics, Quantitative genetics, Biology, Biological Evolution, 010603 evolutionary biology, 01 natural sciences, Genetic architecture, 03 medical and health sciences, Phenotype, 030104 developmental biology, Pleiotropy, Evolutionary biology, Trait, Humans, Identification (biology), Ecology, Evolution, Behavior and Systematics

Abstract

Thinking about the evolutionary causes and consequences of trait correlations has been dominated by quantitative genetics theory that is focused on hypothetical loci. Since this theory was initially developed, technology has enabled the identification of specific genetic variants that contribute to trait correlations. Here, we review studies of the genetic basis of trait correlations to ask: What has this new information taught us? We find that causal variants can be pleiotropic and/or linked in different ways, indicating that pleiotropy and linkage are not alternative genetic mechanisms. Further, many trait correlations have a polygenic basis, suggesting that both pleiotropy and linkage likely contribute. We discuss implications of these findings for the evolutionary causes and consequences of trait correlations.

Published

2017

25. Differential responses to ocean acidification between populations of Balanophyllia elegans corals from high and low upwelling environments

Author

Joanna S Griffiths, Tien Chien Francis Pan, and Morgan W. Kelly

Subjects

0106 biological sciences, 0301 basic medicine, Oceans and Seas, Coral, Population, Environment, Biology, 010603 evolutionary biology, 01 natural sciences, 03 medical and health sciences, Respiration, Genetics, Animals, Gene Regulatory Networks, Calcium ion binding, education, Ecology, Evolution, Behavior and Systematics, Principal Component Analysis, education.field_of_study, Ecology, Discriminant Analysis, Proteins, Ocean acidification, Hydrogen-Ion Concentration, Anthozoa, Lipids, Aerobiosis, Gene Ontology, 030104 developmental biology, Gene Expression Regulation, Upwelling, Seawater, Respiration rate, Acids

Abstract

Ocean acidification (OA), the global decrease in surface water pH from absorption of anthropogenic CO2 , may put many marine taxa at risk. However, populations that experience extreme localized conditions, and are adapted to these conditions predicted in the global ocean in 2,100, may be more tolerant to future OA. By identifying locally adapted populations, researchers can examine the mechanisms used to cope with decreasing pH. One oceanographic process that influences pH is wind-driven upwelling. Here we compare two Californian populations of the coral Balanophyllia elegans from distinct upwelling regimes, and test their physiological and transcriptomic responses to experimental seawater acidification. We measured respiration rates, protein and lipid content, and gene expression in corals from both populations exposed to pH levels of 7.8 and 7.4 for 29 days. Corals from the population that experiences lower pH due to high upwelling maintained the same respiration rate throughout the exposure. In contrast, corals from the low upwelling site had reduced respiration rates, protein content and lipid-class content at low pH exposure, suggesting they have depleted their energy reserves. Using RNA-Seq, we found that corals from the high upwelling site upregulated genes involved in calcium ion binding and ion transport, most likely related to pH homeostasis and calcification. In contrast, corals from the low upwelling site downregulated stress response genes at low pH exposure. Divergent population responses to low pH observed in B. elegans highlight the importance of multi-population studies for predicting a species' response to future OA.

Published

2019

26. Transgenerational plasticity and the capacity to adapt to low salinity in the eastern oyster, Crassostrea virginica

Author

Mark S Yeats, Kevin M. Johnson, Jerome F. La Peyre, Kyle A. Sirovy, Francis T. C. Pan, Morgan W. Kelly, and Joanna S Griffiths

Subjects

Salinity, Oyster, quantitative genetics, animal structures, Crassostrea virginica, Climate change, heritability, Medical and Health Sciences, General Biochemistry, Genetics and Molecular Biology, biology.animal, North Carolina, Animals, Precipitation, Crassostrea, rapid evolution, Research Articles, General Environmental Science, transgenerational plasticity, Gulf of Mexico, Agricultural and Veterinary Sciences, General Immunology and Microbiology, biology, Ecology, Special Feature, General Medicine, Quantitative genetics, Biological Sciences, Heritability, Louisiana, biology.organism_classification, Climate Action, General Agricultural and Biological Sciences, Eastern oyster

Abstract

Salinity conditions in oyster breeding grounds in the Gulf of Mexico are expected to drastically change due to increased precipitation from climate change and anthropogenic changes to local hydrology. We determined the capacity of the eastern oyster, Crassostrea virginica , to adapt via standing genetic variation or acclimate through transgenerational plasticity (TGP). We outplanted oysters to either a low- or medium-salinity site in Louisiana for 2 years. We then crossed adult parents using a North Carolina II breeding design, and measured body size and survival of larvae 5 dpf raised under low or ambient salinity. We found that TGP is unlikely to significantly contribute to low-salinity tolerance since we did not observe increased growth or survival in offspring reared in low salinity when their parents were also acclimated at a low-salinity site. However, we detected genetic variation for body size, with an estimated heritability of 0.68 ± 0.25 (95% CI). This suggests there is ample genetic variation for this trait to evolve, and that evolutionary adaptation is a possible mechanism through which oysters will persist with future declines in salinity. The results of this experiment provide valuable insights into successfully breeding low-salinity tolerance in this commercially important species.

Published

2021

27. Adaptation to heat stress reduces phenotypic and transcriptional plasticity in a marine copepod

Author

M. Sabrina Pankey, Melissa B. DeBiasse, David C. Plachetzki, and Morgan W. Kelly

Subjects

0106 biological sciences, 0301 basic medicine, Phenotypic plasticity, Ecology, Marine invertebrates, Plasticity, Biology, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Phenotype, Transcriptome, 03 medical and health sciences, 030104 developmental biology, Reaction norm, Evolutionary biology, Tigriopus californicus, Adaptation, Ecology, Evolution, Behavior and Systematics

Abstract

Summary 1.Organisms may respond to changing environments through phenotypic plasticity or adaptive evolution. These two processes are not mutually exclusive, and may either dampen or strengthen each other's effects, depending on the genetic correlation between trait values and the slopes of their norms of reaction. 2.To examine the effect of adaptation to heat stress on the plasticity of heat tolerance we hybridized populations of the crustacean Tigriopus californicus that show divergent phenotypes for heat tolerance. We then selected for increased heat tolerance in hybrids and measured heat tolerance and the phenotypic plasticity of heat tolerance in both selected lines and unselected controls. 3.To test whether changes in phenotypic plasticity were associated with changes in the plasticity of gene expression, we also sequenced transcriptomes of selected and unselected lines, both under heat shock and at ambient temperatures. 4.We observed increased heat tolerance in selected lines, but also lower phenotypic and transcriptional plasticity in response to heat stress. The plastic response to heat stress was highly enriched for hydrolytic and catalytic activities, suggesting a prominent role for degradation of mis-folded proteins. 5.Our findings have important implications for biological responses to climate change: if adaptation to environmental stress reduces plasticity, then plasticity and adaptive evolution will make overlapping, rather than additive contributions to buffering populations from environmental change. This article is protected by copyright. All rights reserved.

Published

2016

28. Adaptation to climate change: trade‐offs among responses to multiple stressors in an intertidal crustacean

Author

Vidal A. Villela, Colleen F. Cecola, Hope L. Roberts, Melissa B. DeBiasse, and Morgan W. Kelly

Subjects

0106 biological sciences, 0301 basic medicine, ecological genetics, Intertidal zone, adaptation, Biology, comparative physiology, 010603 evolutionary biology, 01 natural sciences, transcriptomics, 03 medical and health sciences, Genetics, Tigriopus californicus, experimental evolution, Ecology, Evolution, Behavior and Systematics, Experimental evolution, Ecology, Comparative physiology, Original Articles, Replicate, biology.organism_classification, Salinity, climate change, 030104 developmental biology, Original Article, Adaptation, contemporary evolution, General Agricultural and Biological Sciences, Copepod

Abstract

Trade‐offs may influence both physiological and evolutionary responses to co‐occurring stressors, but their effects on both plastic and adaptive responses to climate change are poorly understood. To test for genetic and physiological trade‐offs incurred in tolerating multiple stressors, we hybridized two populations of the intertidal copepod Tigriopus californicus that were divergent for both heat and salinity tolerance. Starting in the F2 generation, we selected for increased tolerance of heat, low salinity, and high salinity in replicate lines. After five generations of selection, heat‐selected lines had greater heat tolerance but lower fecundity, indicating an energetic cost to tolerance. Lines selected for increased salinity tolerance did not show evidence of adaptation to their respective environments; however, hypo‐osmotic selection lines showed substantial loss of tolerance to hyperosmotic stress. Neither of the salinity selection regimes resulted in diminished heat tolerance at ambient salinity; however, simultaneous exposure to heat and hypo‐osmotic stress led to decreased heat tolerance, implying a physiological trade‐off in tolerance to the two stressors. When we quantified the transcriptomic response to heat and salinity stress via RNA sequencing, we observed little overlap in the stress responses, suggesting the observed synergistic effects of heat and salinity stress were driven by competing energetic demands, rather than shared stress response pathways.

Published

2016

29. Evolutionary Responses to Climate Change

Author

Joanna S Griffiths and Morgan W. Kelly

Subjects

0106 biological sciences, Phenotypic plasticity, Extinction, Ecology, 010604 marine biology & hydrobiology, Climate change, 15. Life on land, 010603 evolutionary biology, 01 natural sciences, Geography, 13. Climate action, Geologic history, sense organs, Adaptation, skin and connective tissue diseases, Evolutionary rescue, Pace

Abstract

The current rate of climate change is faster than all of geologic history, and one-sixth of all species are at risk of extinction. Changes in species’ distributions through migration and persistence through phenotypic plasticity will not be enough to match unprecedented rates of change. However, recent evidence suggests that some species are capable of adapting through evolution at a sufficient pace to evade extinction. This article explores some of the discoveries of recent adaptations to current climate change and outlines the methods used to demonstrate that evolution has occurred. Additionally, many studies have documented the potential for adaptation to predicted changes in climate. We describe the methods used to demonstrate evolutionary potential and how these methods can inform conservation thinking and management.

Published

2018

30. Plastic and Evolved Responses to Global Change: What Can We Learn from Comparative Transcriptomics?: Table 1

Author

Melissa B. DeBiasse and Morgan W. Kelly

Subjects

0301 basic medicine, Ecology, Stressor, Gene regulatory network, RNA-Seq, Genomics, Biology, Transcriptome Sequencing, Gene expression profiling, Transcriptome, 03 medical and health sciences, 030104 developmental biology, Evolutionary biology, Genetics, Molecular Biology, Genetics (clinical), Biotechnology, Local adaptation

Abstract

Physiological plasticity and adaptive evolution may facilitate persistence in a changing environment. As a result, there is an interest in understanding species' capacities for plastic and evolved responses, and the mechanisms by which these responses occur. Transcriptome sequencing has become a powerful tool for addressing these questions, providing insight into otherwise unobserved effects of changing conditions on organismal physiology and variation in these effects among individuals and populations. Here, we review recent studies using comparative transcriptomics to understand plastic and evolutionary responses to changing environments. We focus on 2 areas where transcriptomics has played an important role: first, in understanding the genetic basis for local adaptation to current gradients as a proxy for future adaptation, and second, in understanding organismal responses to multiple stressors. We find most studies examining multiple stressors have tested the effects of each stressor individually; the few studies testing multiple stressors simultaneously have found synergistic effects on gene expression that would not have been predicted from single stressor studies. We discuss the importance of robust experimental design to allow for a more sophisticated characterization of transcriptomic responses and conclude by offering recommendations for future research, including integrating genomics with transcriptomics, testing gene regulatory networks, and comparing the equivalence of transcription to translation and the effects of environmental stress on the proteome.

Published

2015

31. High pCO2 affects body size, but not gene expression in larvae of the California mussel (Mytilus californianus)

Author

Morgan W. Kelly, Gretchen E. Hofmann, and Jacqueline L. Padilla-Gamiño

Subjects

0301 basic medicine, Larva, Ecology, biology, fungi, Aquatic Science, Body size, Oceanography, biology.organism_classification, Mytilus, Fishery, 03 medical and health sciences, 030104 developmental biology, Gene expression, California mussel, Ecology, Evolution, Behavior and Systematics

Abstract

Many studies have reported reductions in body size and calcification rates for marine larvae exposed to ocean acidification conditions. However, the physiological mechanisms driving these effects, and mechanisms underlying body size variation in general, are poorly understood. Here, we combine transcriptome sequencing with bulked segregant analysis to assess the physiological response to acidification in larvae of the California mussel, Mytilus californianus, and to explore physiological basis of variation in larval size. We reared three families of M. californianus larvae under ambient (∼350 µatm, pHtotal 8.1) and high (∼1300 µatm, pHtotal 7.6) pCO2 conditions, then passed larvae through a mesh filter, separating each family × pCO2 treatment into fractions of larvae with large vs. small body sizes. We sequenced larval mRNA for each family × treatment × body size combination, and assembled a de novo transcriptome. We then mapped reads from each library to this assembly to identify effects of high pCO2 on gene expression, and to identify transcriptomic differences between small vs. large larvae of the same age class. Although larvae reared under elevated pCO2 were smaller, we observed no consistent effect of elevated pCO2 on gene expression. Nevertheless, 1225 transcripts, primarily related to metabolism, were differentially expressed between large vs. small larvae, regardless of CO2 treatment. We conclude that the observed reduction in larval body size under high CO2 may be driven by a direct effect of the environment on phenotype, unmediated by changes in gene expression. Because M. calfornianus has evolved in the context of seasonal upwelling, exposure to 1300 µatm, pCO2 may not produce the large stress-mediated effects on gene expression that might be expected for an organism exposed to conditions far outside those of its typical environment.

Published

2015

32. Ocean acidification research in the ‘post-genomic’ era: Roadmaps from the purple sea urchin Strongylocentrotus purpuratus

Author

Francis Chan, Jacqueline L. Padilla-Gamiño, Eric Sanford, Gretchen E. Hofmann, Morgan W. Kelly, Bruce A. Menge, Tessa M. Hill, Brian Gaylord, Tyler G. Evans, Melissa H. Pespeni, Stephen R. Palumbi, and Ann D. Russell

Subjects

Physiology, Climate Change, Population, Genomics, Biochemistry, biology.animal, Adaptation, Psychological, Animals, Humans, Seawater, education, Strongylocentrotus purpuratus, Molecular Biology, Sea urchin, Organism, education.field_of_study, biology, Ecology, Ocean acidification, Carbon Dioxide, Hydrogen-Ion Concentration, biology.organism_classification, embryonic structures, Adaptation

Abstract

Advances in nucleic acid sequencing technology are removing obstacles that historically prevented use of genomics within ocean change biology. As one of the first marine calcifiers to have its genome sequenced, purple sea urchins (Strongylocentrotus purpuratus) have been the subject of early research exploring genomic responses to ocean acidification, work that points to future experiments and illustrates the value of expanding genomic resources to other marine organisms in this new 'post-genomic' era. This review presents case studies of S. purpuratus demonstrating the ability of genomic experiments to address major knowledge gaps within ocean acidification. Ocean acidification research has focused largely on species vulnerability, and studies exploring mechanistic bases of tolerance toward low pH seawater are comparatively few. Transcriptomic responses to high pCO₂ seawater in a population of urchins already encountering low pH conditions have cast light on traits required for success in future oceans. Secondly, there is relatively little information on whether marine organisms possess the capacity to adapt to oceans progressively decreasing in pH. Genomics offers powerful methods to investigate evolutionary responses to ocean acidification and recent work in S. purpuratus has identified genes under selection in acidified seawater. Finally, relatively few ocean acidification experiments investigate how shifts in seawater pH combine with other environmental factors to influence organism performance. In S. purpuratus, transcriptomics has provided insight into physiological responses of urchins exposed simultaneously to warmer and more acidic seawater. Collectively, these data support that similar breakthroughs will occur as genomic resources are developed for other marine species.

Published

2015

33. Phenotypic and transcriptomic responses to salinity stress across genetically and geographically divergent Tigriopus californicus populations

Author

Melissa B. DeBiasse, Morgan W. Kelly, and Yasmeen Kawji

Subjects

0301 basic medicine, Male, Salinity, Population, Temperature salinity diagrams, Intertidal zone, Zoology, Salt Stress, Copepoda, 03 medical and health sciences, Genetics, Tigriopus californicus, Animals, RNA, Messenger, education, Ecology, Evolution, Behavior and Systematics, education.field_of_study, Principal Component Analysis, biology, Geography, Gene Expression Profiling, Phenotypic trait, biology.organism_classification, Aerobiosis, 030104 developmental biology, Logistic Models, Phenotype, Gene Expression Regulation, Genetic Loci, Female, Respiration rate, Transcriptome, Copepod

Abstract

Species inhabiting the North American west coast intertidal must tolerate an extremely variable environment, with large fluctuations in both temperature and salinity. Uncovering the mechanisms for this tolerance is key to understanding species' persistence. We tested for differences in salinity tolerance between populations of Tigriopus californicus copepods from locations in northern (Bodega Reserve) and southern (San Diego) California known to differ in temperature, precipitation and humidity. We also tested for differences between populations in their transcriptomic responses to salinity. Although these two populations have ~20% mtDNA sequence divergence and differ strongly in other phenotypic traits, we observed similarities in their phenotypic and transcriptomic responses to low and high salinity stress. Salinity significantly affected respiration rate (increased under low salinity and reduced under high salinity), but we found no significant effect of population on respiration or a population by salinity interaction. Under high salinity, there was no population difference in knock-down response, but northern copepods had a smaller knock-down under low salinity stress, corroborating previous results for T. californicus. Northern and southern populations had a similar transcriptomic response to salinity based on a principle components analysis, although differential gene expression under high salinity stress was three times lower in the northern population compared to the southern population. Transcripts differentially regulated under salinity stress were enriched for "amino acid transport" and "ion transport" annotation categories, supporting previous work demonstrating that the accumulation of free amino acids is important for osmotic regulation in T. californicus.

Published

2017

34. Transcriptomics reveal transgenerational effects in purple sea urchin embryos: Adult acclimation to upwelling conditions alters the response of their progeny to differential pCO

Author

Juliet M, Wong, Kevin M, Johnson, Morgan W, Kelly, and Gretchen E, Hofmann

Subjects

Cold Temperature, Maternal Exposure, Acclimatization, Climate Change, Gene Expression Profiling, Animals, Gene Expression Regulation, Developmental, Female, Carbon Dioxide, Strongylocentrotus purpuratus

Abstract

Understanding the mechanisms with which organisms can respond to a rapidly changing ocean is an important research priority in marine sciences, especially in the light of recent predictions regarding the pace of ocean change in the coming decades. Transgenerational effects, in which the experience of the parental generation can shape the phenotype of their offspring, may serve as such a mechanism. In this study, adult purple sea urchins, Strongylocentrotus purpuratus, were conditioned to regionally and ecologically relevant pCO

Published

2017

35. Identifying the gene(s) that allow tigriopus californicus to survive under thermal stress

Author

Morgan W. Kelly, Sabrina Pankey, and Christabel Chan

Subjects

Ecology, fungi, Hsp70 gene, Tigriopus californicus, Biology, biology.organism_classification, Gene

Abstract

The copepod species, Tigriopus californicus, is one of the most thermally adaptable species in the biosphere. They have been found in tide pools from the coast of Alaska down to the coast of Southern California. However, as all other organisms have limits, the T. californicus are only able to tolerate temperatures up to 34oC. By comparing gene expression between specimens exposed to high temperatures and those expressed to optimal temperatures, we identified the genes responsible for conferring tolerance to increasing temperatures. After testing gene expression between copepods at 20oC and at 34oC, we have determined that both the hsp70 gene and the toll-like receptors of the T. californicus play a role in tolerance to temperature variance. L’espece copepode, Tigriopus californicus, est une des especes les plus thermiquement adaptables de la biosphere. On les trouve dans les bâches depuis la cote de l’Alaska jusqu’a la cote sud de la Californie. Toutefois, comme tous les autres organ¬ismes, les Tigriopus californicus ont des limites et ne peuvent pas tolerer des temperatures superieures a 34oC. En comparant l’expression genetique entre les specimens exposes a des temperatures elevees et ceux exposes a des temperatures optimales, nous avons identifie les genes responsables de la tolerance a des temperatures en hausse. Apres avoir teste l’expression genetique entre les copepodes a 20oC et a 34oC, nous avons determine que le gene hsp70 et les recepteurs de type Toll du T. californicus jouent tous deux un role dans la tolerance aux variations de temperature.

Published

2014

36. Adaptation to climate change through genetic accommodation and assimilation of plastic phenotypes

Author

Morgan W. Kelly

Subjects

0106 biological sciences, 0301 basic medicine, Climate Change, Climate change, Plasticity, Biology, 010603 evolutionary biology, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, skin and connective tissue diseases, Local adaptation, Phenotypic plasticity, business.industry, Assimilation (biology), Articles, Adaptation, Physiological, Biological Evolution, Phenotype, 030104 developmental biology, Evolutionary biology, sense organs, General Agricultural and Biological Sciences, business, Accommodation, Evolutionary rescue

Abstract

Theory suggests that evolutionary changes in phenotypic plasticity could either hinder or facilitate evolutionary rescue in a changing climate. Nevertheless, the actual role of evolving plasticity in the responses of natural populations to climate change remains unresolved. Direct observations of evolutionary change in nature are rare, making it difficult to assess the relative contributions of changes in trait means versus changes in plasticity to climate change responses. To address this gap, this review explores several proxies that can be used to understand evolving plasticity in the context of climate change, including space for time substitutions, experimental evolution and tests for genomic divergence at environmentally responsive loci. Comparisons among populations indicate a prominent role for divergence in environmentally responsive traits in local adaptation to climatic gradients. Moreover, genomic comparisons among such populations have identified pervasive divergence in the regulatory regions of environmentally responsive loci. Taken together, these lines of evidence suggest that divergence in plasticity plays a prominent role in adaptation to climatic gradients over space, indicating that evolving plasticity is also likely to play a key role in adaptive responses to climate change through time. This suggests that genetic variation in plastic responses to the environment (G × E) might be an important predictor of species' vulnerabilities to climate-driven decline or extinction.This article is part of the theme issue ‘The role of plasticity in phenotypic adaptation to rapid environmental change’.

Published

2019

37. Trade-Offs, Geography, and Limits to Thermal Adaptation in a Tide Pool Copepod

Author

Morgan W. Kelly, Richard K. Grosberg, and Eric Sanford

Subjects

Male, Hot Temperature, Climate Change, Population, Adaptation, Biological, Genetic correlation, California, Copepoda, Oregon, Animals, Tigriopus californicus, Selection, Genetic, education, Ecology, Evolution, Behavior and Systematics, Selection (genetic algorithm), Analysis of Variance, geography, education.field_of_study, geography.geographical_feature_category, Geography, biology, Ecology, Genetic Variation, biology.organism_classification, Fecundity, Biological Evolution, Female, Genetic Fitness, Adaptation, Tide pool, Copepod

Abstract

Antagonistic correlations among traits may slow the rate of adaptation to a changing environment. The tide pool copepod Tigriopus californicus is locally adapted to temperature, but within populations, the response to selection for increased heat tolerance plateaus rapidly, suggesting either limited variation within populations or costs of increased tolerance. To measure possible costs of thermal tolerance, we selected for increased upper lethal limits for 10 generations in 22 lines of T. californicus from six populations. Then, for each line, we measured six fitness-related traits. Selected lines showed an overall increase in male and female body sizes, fecundity, and starvation resistance, suggesting a small benefit from (rather than costs of) increased tolerance. The effect of selection on correlated traits also varied significantly by population for five traits, indicating that the genetic basis for the selection response differed among populations. Our results suggest that adaptation was limited by the presence of variation within isolated populations rather than by costs of increased tolerance.

Published

2013

38. Responses to Climate Change, Evolution and

Author

Morgan W. Kelly and B. Thapa

Subjects

Resurrection ecology, Experimental evolution, Phenotypic plasticity, business.industry, Ecology, media_common.quotation_subject, Environmental resource management, Biodiversity, Climate change, Biology, Evolutionary ecology, Psychological resilience, Adaptation, business, media_common

Abstract

Climate change may put as much as 35% of the earth’s biota at risk of extinction. Studies of evolutionary responses to climate change seek to understand both past responses to climate and the role that evolutionary adaptation might play in increasing species’ resilience to the effects of future change. We discuss several methods for documenting evolutionary responses to recent climate change, including resurrection ecology, common-garden experiments, quantitative genetic analyses, and molecular genetics. We conclude with a discussion of the ways that evolutionary thinking can be incorporated into management efforts, in an attempt to minimize biodiversity losses from climate change.

Published

2016

39. Adaptation and the physiology of ocean acidification

Author

Gretchen E. Hofmann and Morgan W. Kelly

Subjects

Habitat, Ecology, Climate change, Marine ecosystem, Ocean acidification, Adaptation, Biology, Ph monitoring, Acclimatization, Ecology, Evolution, Behavior and Systematics, Local adaptation

Abstract

Summary Ocean acidification, caused by the uptake of atmospheric CO2, is a threat to marine biodiversity, potentially rivalling the threat imposed by rising temperatures in some marine ecosystems. Although a growing body of literature documents negative effects of acidification on marine organisms, the majority of this work has focused on the effects of future conditions on modern populations, ignoring the potential effects of adaptation and physiological acclimatization. We review current literature on the potential for adaptation to elevated pCO2 in marine organisms. Although this body of work is currently quite small, we argue that data on the physiological effects of acidification, natural variation in pH and lessons learned from previous work on thermal adaptation can all inform predictions and priorities for future research. Spatially varying selection is one of the most important forces maintaining intraspecific genetic variation. Unlike temperature, pH lacks a strong and persistent global gradient, and so selection may maintain less adaptive variation for pH than for temperature. On the other hand, we are only beginning to amass long-term data sets for pH variation in natural habitats, and thus, pH gradients may be more common than previously observed. Two of the most important effects of elevated pCO2 are reduced calcification and changes in metabolism. We discuss the ways that a detailed understanding of the physiological mechanisms underlying these effects is key to predicting the capacity for acclimatization and adaptation. Important priorities for future research will be to assess local adaptation to pH conditions and to measure the capacity for adaptation to future acidified conditions in natural populations. Tools for this work include traditional quantitative genetics, transcriptomics and the adaptation of ion-sensitive field-effect transistor (ISFET) technology for use in continuous seawater pH monitoring in the field.

Published

2012

40. Local Adaptation in Marine Invertebrates

Author

Eric Sanford and Morgan W. Kelly

Subjects

Abiotic component, Community, Ecology, Range (biology), Oceans and Seas, Marine invertebrates, Biology, Oceanography, Adaptation, Physiological, Invertebrates, Animals, Biological dispersal, Marine ecosystem, Ecosystem, Local adaptation, Invertebrate

Abstract

Local adaptation in the sea was regarded historically as a rare phenomenon that was limited to a handful of species with exceptionally low dispersal potential. However, a growing body of experimental studies indicates that adaptive differentiation occurs in numerous marine invertebrates in response to selection imposed by strong gradients (and more complex mosaics) of abiotic and biotic conditions. Moreover, a surprisingly high proportion of the marine invertebrates known or suspected of exhibiting local adaptation are species with planktonic dispersal. Adaptive divergence among populations can occur over a range of spatial scales, including those that are fine-grained (i.e., meters to kilometers), reflecting a balance between scales of gene flow and selection. Addressing the causes and consequences of adaptive genetic differentiation among invertebrate populations promises to advance community ecology, climate change research, and the effective management of marine ecosystems.

Published

2011

41. The evolution of mating systems in barnacles

Author

Morgan W. Kelly and Eric Sanford

Subjects

Barnacle, biology, Dioecy, Androdioecy, Zoology, Interspecific competition, Aquatic Science, Mating, Mating system, biology.organism_classification, Sperm competition, Ecology, Evolution, Behavior and Systematics, Sex allocation

Abstract

Thoracican barnacles exhibit tremendous diversity among species in reproductive life histories, including hermaphroditism, dioecy and androdioecy. Androdioecy (where populations contain a mix of males and hermaphrodites) is rare among animals, but has been described in more than 30 species of barnacles and appears to have evolved independently at least four times in this clade. Several models have been suggested to explain the evolution and stability of different mating systems in barnacles, including the relatively high frequency of androdioecy. We review this body of theory and compare predictions to existing empirical data on interspecific patterns of sex allocation. Allocation to male and female reproduction may also vary within barnacle species, and these patterns may provide additional insight into the evolutionary forces that select for different mating systems. Theory predicts that for simultaneous hermaphrodites, the optimal allocation to male function should increase with the size of mating groups, due to sperm competition. This prediction is supported by the only previously published study to address this issue. We present new data from another intertidal barnacle (Tetraclita rubescens) that do not support the predicted association between investment in male reproduction and local density of conspecifics. We suggest that this departure from the expected relationship may arise from a reduced importance of sperm competition in this species. Despite over 150 years of interest in barnacle mating systems, many questions remain unanswered. We argue that barnacles provide a superb opportunity to test predictions of sex allocation theory and we offer suggestions for promising areas of future research.

Published

2010

42. Population genetic structure of a rare unionid (Lampsilis cariosa) in a recently glaciated landscape

Author

J. M. Rhymer and Morgan W. Kelly

Subjects

education.field_of_study, Habitat fragmentation, Range (biology), Ecology, Population, Biology, biology.organism_classification, Effective population size, Lampsilis cariosa, Genetic structure, Genetics, Biological dispersal, education, Ecology, Evolution, Behavior and Systematics, Isolation by distance

Abstract

The yellow lampmussel (Lampsilis cariosa) is a rare unionid species in need of conservation, as it is declining throughout most of its Atlantic slope range in North America. Because freshwater mussels rely on a fish host for dispersal of their larvae, barriers to the movement of hosts, such as habitat fragmentation by dams, may indirectly affect population genetic structure. We used microsatellite loci to assess genetic variation for L. cariosa within and among three river drainages in the northern part of its range, which emerged from glaciation only ∼ ∼8–10 kya. Despite this relatively recent emergence, significant differences were observed among populations both within and among drainages, possibly because low effective population sizes meant that populations of these mussels achieved drift-migration equilibrium rapidly following glaciation. L. cariosa individuals could be assigned to their own drainages with 89.3% accuracy. Among-population differences were modest, however, in comparison to differences observed in another study of rare mussels south of the recently glaciated region. L. cariosa populations exhibited significant isolation by distance, but there was no additional variation explained by the number, size, or age of intervening dams. An understanding of mussel population genetic structure provides information, useful for conservation planning, on patterns of isolation and connectivity among populations.

Published

2005

43. Temperature and CO2 additively regulate physiology, morphology and genomic responses of larval sea urchins, Strongylocentrotus purpuratus

Author

Tyler G. Evans, Jacqueline L. Padilla-Gamiño, Gretchen E. Hofmann, and Morgan W. Kelly

Subjects

Hot Temperature, Effects of global warming on oceans, Molecular Sequence Data, Global Warming, General Biochemistry, Genetics and Molecular Biology, California, chemistry.chemical_compound, Two temperature, Animals, Seawater, Strongylocentrotus purpuratus, Research Articles, Phylogeny, General Environmental Science, Oligonucleotide Array Sequence Analysis, Larva, General Immunology and Microbiology, biology, Ecology, Gene Expression Profiling, Global warming, fungi, Global change, Ocean acidification, General Medicine, Sequence Analysis, DNA, Carbon Dioxide, biology.organism_classification, Logistic Models, chemistry, Carbon dioxide, General Agricultural and Biological Sciences

Abstract

Ocean warming and ocean acidification, both consequences of anthropogenic production of CO 2 , will combine to influence the physiological performance of many species in the marine environment. In this study, we used an integrative approach to forecast the impact of future ocean conditions on larval purple sea urchins ( Strongylocentrotus purpuratus ) from the northeast Pacific Ocean. In laboratory experiments that simulated ocean warming and ocean acidification, we examined larval development, skeletal growth, metabolism and patterns of gene expression using an orthogonal comparison of two temperature (13°C and 18°C) and pCO 2 (400 and 1100 μatm) conditions. Simultaneous exposure to increased temperature and pCO 2 significantly reduced larval metabolism and triggered a widespread downregulation of histone encoding genes. pCO 2 but not temperature impaired skeletal growth and reduced the expression of a major spicule matrix protein, suggesting that skeletal growth will not be further inhibited by ocean warming. Importantly, shifts in skeletal growth were not associated with developmental delay. Collectively, our results indicate that global change variables will have additive effects that exceed thresholds for optimized physiological performance in this keystone marine species.

Published

2013

44. Natural variation and the capacity to adapt to ocean acidification in the keystone sea urchin Strongylocentrotus purpuratus

Author

Gretchen E. Hofmann, Jacqueline L. Padilla-Gamiño, and Morgan W. Kelly

Subjects

Environmental change, Population, Carbonates, Biology, California, Genetic variation, Environmental Chemistry, Animals, Body Size, Seawater, education, Strongylocentrotus purpuratus, General Environmental Science, Local adaptation, Global and Planetary Change, education.field_of_study, Polymorphism, Genetic, Ecology, Ocean acidification, Heritability, Carbon Dioxide, Hydrogen-Ion Concentration, biology.organism_classification, Adaptation, Physiological, Phenotype, Larva, Adaptation

Abstract

A rapidly growing body of literature documents the potential negative effects of CO2 -driven ocean acidification (OA) on marine organisms. However, nearly all this work has focused on the effects of future conditions on modern populations, neglecting the role of adaptation. Rapid evolution can alter demographic responses to environmental change, ultimately affecting the likelihood of population persistence, but the capacity for adaptation will differ among populations and species. Here, we measure the capacity of the ecologically important purple sea urchin Strongylocentrotus purpuratus to adapt to OA, using a breeding experiment to estimate additive genetic variance for larval size (an important component of fitness) under future high-pCO2 /low-pH conditions. Although larvae reared under future conditions were smaller than those reared under present-day conditions, we show that there is also abundant genetic variation for body size under elevated pCO2 , indicating that this trait can evolve. The observed heritability of size was 0.40 ± 0.32 (95% CI) under low pCO2 , and 0.50 ± 0.30 under high-pCO2 conditions. Accounting for the observed genetic variation in models of future larval size and demographic rates substantially alters projections of performance for this species in the future ocean. Importantly, our model shows that after incorporating the effects of adaptation, the OA-driven decrease in population growth rate is up to 50% smaller, than that predicted by the 'no-adaptation' scenario. Adults used in the experiment were collected from two sites on the coast of the Northeast Pacific that are characterized by different pH regimes, as measured by autonomous sensors. Comparing results between sites, we also found subtle differences in larval size under high-pCO2 rearing conditions, consistent with local adaptation to carbonate chemistry in the field. These results suggest that spatially varying selection may help to maintain genetic variation necessary for adaptation to future OA.

Published

2013

45. Limited potential for adaptation to climate change in a broadly distributed marine crustacean

Author

Eric Sanford, Richard K. Grosberg, and Morgan W. Kelly

Subjects

Experimental evolution, Extinction, General Immunology and Microbiology, Environmental change, Geography, Ecology, Climate Change, Temperature, General Medicine, Biology, biology.organism_classification, Adaptation, Physiological, General Biochemistry, Genetics and Molecular Biology, Intraspecific competition, Copepoda, Genetic variation, Tigriopus californicus, Animals, Adaptation, General Agricultural and Biological Sciences, Heat-Shock Response, Research Articles, General Environmental Science, Local adaptation

Abstract

The extent to which acclimation and genetic adaptation might buffer natural populations against climate change is largely unknown. Most models predicting biological responses to environmental change assume that species' climatic envelopes are homogeneous both in space and time. Although recent discussions have questioned this assumption, few empirical studies have characterized intraspecific patterns of genetic variation in traits directly related to environmental tolerance limits. We test the extent of such variation in the broadly distributed tidepool copepod Tigriopus californicus using laboratory rearing and selection experiments to quantify thermal tolerance and scope for adaptation in eight populations spanning more than 17° of latitude. Tigriopus californicus exhibit striking local adaptation to temperature, with less than 1 per cent of the total quantitative variance for thermal tolerance partitioned within populations. Moreover, heat-tolerant phenotypes observed in low-latitude populations cannot be achieved in high-latitude populations, either through acclimation or 10 generations of strong selection. Finally, in four populations there was no increase in thermal tolerance between generations 5 and 10 of selection, suggesting that standing variation had already been depleted. Thus, plasticity and adaptation appear to have limited capacity to buffer these isolated populations against further increases in temperature. Our results suggest that models assuming a uniform climatic envelope may greatly underestimate extinction risk in species with strong local adaptation.

Published

2011

46. Love the one you're with: proximity determines paternity success in the barnacle Tetraclita rubescens

Author

Eric Sanford, Richard K. Grosberg, and Morgan W. Kelly

Subjects

Genotype, Zoology, California, Sperm displacement, Barnacle, Genetics, Animals, Body Size, Hermaphroditic Organisms, reproductive and urinary physiology, Ecology, Evolution, Behavior and Systematics, Invertebrate, Reproductive success, biology, Ecology, Reproduction, Sire, Thoracica, Sequence Analysis, DNA, biology.organism_classification, Mating system, Sperm, Logistic Models, Sexual selection, behavior and behavior mechanisms, Microsatellite Repeats

Abstract

A species' mating system sets limits on the strength of sexual selection. Sexual selection is widespread in dioecious species, but is less well documented in hermaphrodites, and may be less important. We used four highly polymorphic microsatellite markers to assign paternity to broods of the hermaphroditic eastern Pacific volcano barnacle Tetraclita rubescens. These data were used to describe the species' mating system and to examine factors affecting male reproductive success. Tetraclita can sire broods over distances of 11.2 cm, but proximity to the sperm recipient had a highly significant effect on the probability of siring success. There was no effect of body size or the mass of male reproductive tissues on siring success. Broods showed relatively low frequencies of multiple paternity; even at high densities, 75% of broods had only one father. High frequencies of single-paternity broods imply either that this species does not compete via sperm displacement, or that sperm displacement is extremely effective, potentially explaining the lack of a positive relationship between male investment and paternity. In addition, there was low variance in siring success among individuals, suggesting a lack of strong sexual selection on male traits. Low variance among sires and the strong effect of proximity are probably driven by the unusual biology of a sessile copulating species.

Published

2011

47. Mechanistic species distribution modelling as a link between physiology and conservation

Author

Sarah E. Diamond, Tyler G. Evans, and Morgan W. Kelly

Subjects

Correlative, demography, model, Occupancy, Environmental change, Physiology, business.industry, Ecological Modeling, Environmental resource management, Vulnerability, Reviews, temperature, Climate change, Context (language use), Management, Monitoring, Policy and Law, Biology, Environmental niche modelling, Predictive power, species distribution, business, Nature and Landscape Conservation

Abstract

Species distribution modeling is the most common method of estimating climate change impacts on biodiversity. In this review, we argue a need for collaboration among physiologists, modelers and conservationists to parameterize models with physiological information in order to increase their accuracy and advance the field of conservation physiology., Climate change conservation planning relies heavily on correlative species distribution models that estimate future areas of occupancy based on environmental conditions encountered in present-day ranges. The approach benefits from rapid assessment of vulnerability over a large number of organisms, but can have poor predictive power when transposed to novel environments and reveals little in the way of causal mechanisms that define changes in species distribution or abundance. Having conservation planning rely largely on this single approach also increases the risk of policy failure. Mechanistic models that are parameterized with physiological information are expected to be more robust when extrapolating distributions to future environmental conditions and can identify physiological processes that set range boundaries. Implementation of mechanistic species distribution models requires knowledge of how environmental change influences physiological performance, and because this information is currently restricted to a comparatively small number of well-studied organisms, use of mechanistic modelling in the context of climate change conservation is limited. In this review, we propose that the need to develop mechanistic models that incorporate physiological data presents an opportunity for physiologists to contribute more directly to climate change conservation and advance the field of conservation physiology. We begin by describing the prevalence of species distribution modelling in climate change conservation, highlighting the benefits and drawbacks of both mechanistic and correlative approaches. Next, we emphasize the need to expand mechanistic models and discuss potential metrics of physiological performance suitable for integration into mechanistic models. We conclude by summarizing other factors, such as the need to consider demography, limiting broader application of mechanistic models in climate change conservation. Ideally, modellers, physiologists and conservation practitioners would work collaboratively to build models, interpret results and consider conservation management options, and articulating this need here may help to stimulate collaboration.

Published

2015

48. Limited potential for adaptation to climate change in a broadly distributed marine crustacean.

Author

Morgan W., Kelly, Eric, Sanford, and Richard K., Grosberg

Subjects

*CLIMATE change, *CRUSTACEA, *MARINE animals, *MARINE invertebrates, *THERMAL tolerance (Physiology), *PHENOTYPES

Abstract

The extent to which acclimation and genetic adaptation might buffer natural populations against climate change is largely unknown. Most models predicting biological responses to environmental change assume that species' climatic envelopes are homogeneous both in space and time. Although recent discussions have questioned this assumption, few empirical studies have characterized intraspecific patterns of genetic variation in traits directly related to environmental tolerance limits. We test the extent of such variation in the broadly distributed tidepool copepod Tigriopus californicus using laboratory rearing and selection experiments to quantify thermal tolerance and scope for adaptation in eight populations spanning more than 17° of latitude. Tigriopus californicus exhibit striking local adaptation to temperature, with less than 1 per cent of the total quantitative variance for thermal tolerance partitioned within populations. Moreover, heat-tolerant phenotypes observed in low-latitude populations cannot be achieved in high-latitude populations, either through acclimation or 10 generations of strong selection. Finally, in four populations there was no increase in thermal tolerance between generations 5 and 10 of selection, suggesting that standing variation had already been depleted. Thus, plasticity and adaptation appear to have limited capacity to buffer these isolated populations against further increases in temperature. Our results suggest that models assuming a uniform climatic envelope may greatly underestimate extinction risk in species with strong local adaptation. [ABSTRACT FROM AUTHOR]

Published

2012