9 results on '"Kala M. Downey"'
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2. The dynamic response to hypo-osmotic stress reveals distinct stages of freshwater acclimation by a euryhaline diatom
- Author
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Kala M. Downey, Kathryn J. Judy, Eveline Pinseel, Andrew J. Alverson, and Jeffrey A. Lewis
- Subjects
Genetics ,Ecology, Evolution, Behavior and Systematics - Abstract
The salinity gradient separating marine and freshwater environments is a major ecological divide, and the mechanisms by which most organisms adapt to new salinity environments are poorly understood. Diatoms are a lineage of ancestrally marine microalgae that have repeatedly colonized and diversified in freshwaters. Cyclotella cryptica is a euryhaline diatom that naturally tolerates a broad range of salinities, thus providing a powerful system for understanding the genomic mechanisms for mitigating and acclimating to low salinity. To understand how diatoms mitigate acute hypoosmotic stress, we abruptly shifted C. cryptica from seawater to freshwater and performed transcriptional profiling during the first 10 hours. Freshwater shock dramatically remodeled the transcriptome, with ~50% of the genome differentially expressed in at least one time point. The peak response occurred within 1 hour, with strong repression of genes involved in cell growth and osmolyte production, and strong induction of specific stress defense genes. Transcripts largely returned to baseline levels within 4–10 hours, with growth resuming shortly thereafter, suggesting that gene expression dynamics may be useful for predicting acclimation. Moreover, comparison to a transcriptomics study of C. cryptica following months-long acclimation to freshwater revealed little overlap between the genes and processes differentially expressed in cells exposed to acute stress versus fully acclimated conditions. Altogether, this study highlights the power of time-resolved transcriptomics to reveal fundamental insights into how cells dynamically respond to an acute environmental shift and provides new insights into how diatoms mitigate natural salinity fluctuations and have successfully diversified across freshwater habitats worldwide.
- Published
- 2022
3. Resolving marine–freshwater transitions by diatoms through a fog of discordant gene trees
- Author
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Wade R. Roberts, Elizabeth C. Ruck, Kala M. Downey, Eveline Pinseel, and Andrew J. Alverson
- Abstract
Despite the obstacles facing marine colonists, most lineages of aquatic organisms have colonized and diversified in freshwaters repeatedly. These transitions can trigger rapid morphological or physiological change and, on longer timescales, lead to increased rates of speciation and extinction. Diatoms are a lineage of ancestrally marine microalgae that have diversified throughout freshwater habitats worldwide. We generated a phylogenomic dataset of genomes and transcriptomes for 59 diatom taxa to resolve freshwater transitions in one lineage, the Thalassiosirales. Although most parts of the species tree were consistently resolved with strong support, we had difficulties resolving a Paleocene radiation, which affected the placement of one freshwater lineage. This and other parts of the tree were characterized by high levels of gene tree discordance caused by incomplete lineage sorting and low phylogenetic signal. Despite differences in species trees inferred from concatenation versus summary methods and codons versus amino acids, traditional methods of ancestral state reconstruction supported six transitions into freshwaters, two of which led to subsequent species diversification. Evidence from gene trees, protein alignments, and diatom life history together suggest that habitat transitions were largely the product of homoplasy rather than hemiplasy, a condition where transitions occur on branches in gene trees not shared with the species tree. Nevertheless, we identified a small set of putatively hemiplasious genes, many of which have been associated with shifts to low salinity, indicating that hemiplasy played a small but potentially important role in freshwater adaptation. Accounting for differences in evolutionary outcomes, in which some taxa became locked into freshwaters while others were able to return to the ocean or become salinity generalists, might help further distinguish different sources of adaptive mutation in freshwater diatoms.
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- 2022
- Full Text
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4. Phylogenetic analysis places Spicaticribra within Cyclotella
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Kala M. Downey, Matthew L. Julius, Andrew J. Alverson, and Edward C. Theriot
- Subjects
Thalassiosirales ,Phylogenetic tree ,royalty.order_of_chivalry ,royalty ,Aquatic Science ,Biology ,phylogeny ,diatoms ,Monophyly ,ComputingMethodologies_PATTERNRECOGNITION ,Evolutionary biology ,Phylogenetics ,TheoryofComputation_ANALYSISOFALGORITHMSANDPROBLEMCOMPLEXITY ,ComputingMethodologies_DOCUMENTANDTEXTPROCESSING ,Data_FILES ,Taxonomy (biology) ,MathematicsofComputing_DISCRETEMATHEMATICS - Abstract
A strong consensus has emerged that taxonomic classifications should be based on an underlying phylogenetic hypothesis. According to this view, named groups should be monophyletic, ensuring that a ...
- Published
- 2021
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5. Improved Reference Genome for Cyclotella cryptica CCMP332, a Model for Cell Wall Morphogenesis, Salinity Adaptation, and Lipid Production in Diatoms (Bacillariophyta)
- Author
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Kala M. Downey, Wade R. Roberts, Jesse C. Traller, Andrew J. Alverson, and Elizabeth C. Ruck
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Transposable element ,Salinity ,QH426-470 ,Biology ,Genome ,lipids ,Cell wall ,03 medical and health sciences ,0302 clinical medicine ,Cell Wall ,Morphogenesis ,Genetics ,algal biofuels ,nanopore ,Repeated sequence ,Molecular Biology ,Gene ,Genetics (clinical) ,030304 developmental biology ,Diatoms ,0303 health sciences ,biology.organism_classification ,Genome Report ,Diatom ,Evolutionary biology ,Horizontal gene transfer ,horizontal gene transfer ,transposable elements ,030217 neurology & neurosurgery ,Reference genome - Abstract
The diatom, Cyclotella cryptica, is a well-established model species for physiological studies and biotechnology applications of diatoms. To further facilitate its use as a model diatom, we report an improved reference genome assembly and annotation for C. cryptica strain CCMP332. We used a combination of long- and short-read sequencing to assemble a high-quality and contaminant-free genome. The genome is 171 Mb in size and consists of 662 scaffolds with a scaffold N50 of 494 kb. This represents a 176-fold decrease in scaffold number and 41-fold increase in scaffold N50 compared to the previous assembly. The genome contains 21,250 predicted genes, 75% of which were assigned putative functions. Repetitive DNA comprises 59% of the genome, and an improved classification of repetitive elements indicated that a historically steady accumulation of transposable elements has contributed to the relatively large size of the C. cryptica genome. The high-quality C. cryptica genome will serve as a valuable reference for ecological, genetic, and biotechnology studies of diatoms.
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- 2020
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6. Population genetics of a rare wetland species, the Tennessee yellow-eyed grass (Xyris tennesseensis, Xyridaceae)
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Carol J. Baskauf and Kala M. Downey
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0106 biological sciences ,0301 basic medicine ,Genetic diversity ,biology ,Endangered species ,Disjunct distribution ,Population genetics ,Zoology ,biology.organism_classification ,010603 evolutionary biology ,01 natural sciences ,Gene flow ,03 medical and health sciences ,030104 developmental biology ,Genetic variation ,Genetics ,Xyris tennesseensis ,Genetic variability ,Ecology, Evolution, Behavior and Systematics - Abstract
Federally endangered Xyris tennesseensis is a perennial monocot found in imperiled wetlands such as calcareous seeps and riparian habitats within its disjunct distribution (one county in Tennessee, three in Alabama and four in Georgia). This species belongs to a genus of wetland plants for which very little genetic work has been carried out. Because of the rarity of this species, we hypothesized that it would have low genetic variability overall and that populations were likely to be genetically differentiated due to the species’ disjunct distribution. Fourteen microsatellite loci polymorphic at the species level showed limited variability at the population level, averaging 16.3% polymorphic loci, 1.17 alleles per locus, an observed heterozygosity of 0.017, and an expected heterozygosity of 0.054. The discrepancy between observed and expected heterozygosity resulted in a relatively high FIS of 0.71, suggesting that X. tennesseensis experiences high levels of inbreeding. We also found evidence of varying levels of vegetative reproduction in this species. Analysis of molecular variance estimated that differentiation among the regions (states) accounted for the majority (60%) of the genetic variation in this species, with an additional 31% due to genetic differences among the populations of each state and only 9% due to variability within populations. These data indicate X. tennesseensis possesses low levels of genetic diversity and experiences virtually no gene flow among populations. To preserve the genetic diversity of this species, multiple populations must be protected, with priority given to the largest and most variable populations in each region.
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- 2020
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7. Genotype-specific transcriptional responses overshadow salinity effects in a marine diatom sampled along the Baltic Sea salinity cline
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Elizabeth C. Ruck, Kala M. Downey, Anke Kremp, Anna Godhe, Kathryn J. Judy, Andrew J. Alverson, Olga Kourtchenko, Koen Van den Berge, Conny Sjöqvist, Mats Töpel, Eveline Pinseel, and Teofil Nakov
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Salinity ,Nutrient ,Brackish water ,Environmental change ,Skeletonema marinoi ,Ecology ,fungi ,Cline (biology) ,Biology ,Nitrogen cycle ,Intraspecific competition - Abstract
The salinity gradient separating marine and freshwater environments represents a major ecological divide for microbiota, yet the mechanisms by which marine microbes have adapted to and ultimately diversified in freshwater environments are poorly understood. Here, we take advantage of a natural evolutionary experiment: the colonization of the brackish Baltic Sea by the ancestrally marine diatom Skeletonema marinoi. To understand how diatoms respond to low salinity, we characterized transcriptomic responses of S. marinoi grown in a common garden. Our experiment included eight genotypes from source populations spanning the Baltic Sea salinity cline. Changes in gene expression revealed a shared response to salinity across genotypes, where low salinities induced profound changes in cellular metabolism, including upregulation of carbon fixation and storage compound biosynthesis, and increased nutrient demand and oxidative stress. Nevertheless, the genotype effect overshadowed the salinity effect, as genotypes differed significantly in their response, both in the magnitude and direction of gene expression. Intraspecific differences included regulation of transcription and translation, nitrogen metabolism, cell signaling, and aerobic respiration. The high degree of intraspecific variation in gene expression observed here highlights an important but often overlooked source of biological variation associated with how diatoms respond and adapt to environmental change.
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- 2021
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8. Improved Reference Genome forCyclotella CrypticaCCMP332, a Model for Cell Wall Morphogenesis, Salinity Adaptation, and Lipid Production in Diatoms (Bacillariophyta)
- Author
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Andrew J. Alverson, Kala M. Downey, Elizabeth C. Ruck, Wade R. Roberts, and Jesse C. Traller
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Transposable element ,Cell wall ,Diatom ,biology ,Evolutionary biology ,Strain (biology) ,Repeated sequence ,biology.organism_classification ,Genome ,Gene ,Reference genome - Abstract
The diatom,Cyclotella cryptica, is a well-established experimental model for physiological studies and, more recently, biotechnology applications of diatoms. To further facilitate its use as a model diatom species, we report an improved reference genome assembly and annotation forC. crypticastrain CCMP332. We used a combination of long- and short-read sequencing to assemble a high-quality and contaminant-free genome. The genome is 171 Mb in size and consists of 662 scaffolds with a scaffold N50 of 494 kb. This represents a 176-fold decrease in scaffold number and 41-fold increase in scaffold N50 compared to the previous assembly. The genome contains 21,250 predicted genes, 75% of which were assigned putative functions. Repetitive DNA comprises 59% of the genome, and an improved classification of repetitive elements indicated that a historically steady accumulation of transposable elements has contributed to the relatively large size of theC. crypticagenome. The high-qualityC. crypticagenome will serve as a valuable reference for ecological, genetic, and biotechnology studies of diatoms.Data available fromNCBI BioProjects PRJNA628076 and PRJNA589195
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- 2020
- Full Text
- View/download PDF
9. Transcriptional Response of Osmolyte Synthetic Pathways and Membrane Transporters in a Euryhaline Diatom During Long-term Acclimation to a Salinity Gradient
- Author
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Kala M. Downey, Kathryn J. Judy, Teofil Nakov, Andrew J. Alverson, and Elizabeth C. Ruck
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0106 biological sciences ,Diatoms ,Salinity ,Osmotic shock ,010604 marine biology & hydrobiology ,Acclimatization ,Membrane Transport Proteins ,Plant Science ,Euryhaline ,Aquatic Science ,Biology ,010603 evolutionary biology ,01 natural sciences ,chemistry.chemical_compound ,Betaine ,Biochemistry ,chemistry ,Osmolyte ,Osmotic Pressure ,Gene expression ,Osmotic pressure - Abstract
How diatoms respond to fluctuations in osmotic pressure is important from both ecological and applied perspectives. It is well known that osmotic stress affects photosynthesis and can result in the accumulation of compounds desirable in pharmaceutical and alternative fuel industries. Gene expression responses to osmotic stress have been studied in short-term trials, but it is unclear whether the same mechanisms are recruited during long-term acclimation. We used RNA-seq to study the genome-wide transcription patterns in the euryhaline diatom, Cyclotella cryptica, following long-term acclimation to salinity that spanned the natural range of fresh to oceanic water. Long-term acclimated C. cryptica exhibited induced synthesis or repressed degradation of the osmolytes glycine betaine, taurine and dimethylsulfoniopropionate (DMSP). Although changes in proline concentration is one of the main responses in short-term osmotic stress, we did not detect a transcriptional change in proline biosynthetic pathways in our long-term experiment. Expression of membrane transporters showed a general tendency for increased import of potassium and export of sodium, consistent with the electrochemical gradients and dependence on co-transported molecules. Our results show substantial between-genotype differences in growth and gene expression reaction norms and suggest that the regulation of proline synthesis important in short-term osmotic stress might not be maintained in long-term acclimation. Further examination using time-course gene expression experiments, metabolomics and genetic validation of gene functions would reinforce patterns inferred from RNA-seq data.
- Published
- 2019
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