14 results on '"Mark A Phuong"'
Search Results
2. Population Analysis of Bali Sardinella (Sardinella lemuru, Bleeker 1853) Landed in PPI Kedonganan using Length-Weight Data and Digital Analysis (ImageJ)
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Ni Putu Dian Pertiwi, Ida Ayu Purnama Bestari, M. Danie Al Malik, and Mark Anthony Phuong
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Ecology ,Aquatic Science ,Oceanography - Abstract
Sardinella lemuru, one of the important pelagic fish in Bali Strait waters, has been reported to be in the overfishing condition. Various studies have been conducted to understand its population condition. Length-weight data has been also widely used to understand the population dynamic of S. lemuru, although data collection generally using manual direct measurement methods, which has the disadvantages if used on the enormous number of samples. Therefore, this research aims to understand the significance of S. lemuru length measurement using digital image analysis (ImageJ) compared with the manual measurement. Moreover, this research also aims to understand the population condition of S. lemuru landed in PPI Kedonganan analyzed using its length-weight data. The result indicated no significance difference between length measurement using manual methods and digital image methods, thus conclude that digital image data can be used to measure the fish length and represent the accurate measurement. Population condition analysis showed that S. lemuru population is in isometric condition (b=3); with indication of declining in the length growth pattern compared with previous research (L∞= 20.75 cm with K= 1.1); the mortality estimation showed that fishing mortality (F=1.27) was lower than natural mortality (M=2.22), with the survival rate higher on smaller size fish. This research result can be used as an addition to the S. lemuru fisheries data and can also be used as reference methods to help conduct sampling and data collection more efficiently.
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- 2023
3. Selecting Potential Neuronal Drug Leads from Conotoxins of Various Venomous Marine Cone Snails in Bali, Indonesia
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Made Pharmawati, Bayu K. Mahardika, Mark A Phuong, Anak Agung Raka Sudewi, I Gusti Ngurah Kade Mahardika, Ni Made Susilawathi, and Agung Nova Mahendra
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genetic structures ,General Chemical Engineering ,General Chemistry ,Biology ,complex mixtures ,Cone (formal languages) ,Article ,Chemistry ,nervous system ,Evolutionary biology ,parasitic diseases ,sense organs ,Conotoxin ,QD1-999 - Abstract
Many conotoxins, natural peptides of marine cone snails, have been identified to target neurons. Here, we provide data on pharmacological families of the conotoxins of 11 species of cone snails collected in Bali. The identified definitive pharmacological families possibly targeting neuronal tissues were α (alpha), ι (iota), κ (kappa), and ρ (rho). These classes shall target nicotinic acetylcholine receptors, voltage-gated Na channels, voltage-gated K channels, and α1-adrenoceptors, respectively. The VI/VII-O3 conotoxins might be prospected as an inhibitor of N-methyl-d-aspartate. Con-ikot-ikot could be applied as an α-amino-3-hydroxy-5-methyl-4-isoxazole propionic acid receptor blocker medicine. The definitive pharmacology classes of conotoxins as well as those yet to be elucidated need to be further established and verified.
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- 2019
4. Exon-Capture-Based Phylogeny and Diversification of the Venomous Gastropods (Neogastropoda, Conoidea)
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Jawad Abdelkrim, Nicolas Puillandre, Paul Zaharias, Yuri I. Kantor, Alexander E. Fedosov, Pierre Lozouet, Mark A Phuong, Laetitia Aznar-Cormano, Puillandre, Nicolas, Institut de Systématique, Evolution, Biodiversité (ISYEB ), Muséum national d'Histoire naturelle (MNHN)-École pratique des hautes études (EPHE), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Centre National de la Recherche Scientifique (CNRS), A.N. Severtsov Institute of Ecology and Evolution, Russian Academy of Sciences [Moscow] (RAS), Direction générale déléguée aux collections (DGD.C), and Muséum national d'Histoire naturelle (MNHN)
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0106 biological sciences ,0301 basic medicine ,Sequence analysis ,Gastropoda ,Biology ,Neogastropoda ,[SDV.BID.SPT]Life Sciences [q-bio]/Biodiversity/Systematics, Phylogenetics and taxonomy ,phylogeny ,010603 evolutionary biology ,01 natural sciences ,Evolution, Molecular ,03 medical and health sciences ,Phylogenetics ,[SDV.BID.SPT] Life Sciences [q-bio]/Biodiversity/Systematics, Phylogenetics and taxonomy ,Genetics ,Animals ,Supermatrix ,Conoidea ,14. Life underwater ,supertree ,Molecular Biology ,Phylogeny ,ComputingMilieux_MISCELLANEOUS ,Ecology, Evolution, Behavior and Systematics ,Phylogenetic tree ,Conus Snail ,Genetic Variation ,Exons ,Sequence Analysis, DNA ,biology.organism_classification ,Biological Evolution ,Supertree ,genomic DNA ,030104 developmental biology ,exon-capture ,Evolutionary biology ,Transcriptome - Abstract
Transcriptome-based exon capture methods provide an approach to recover several hundred markers from genomic DNA, allowing for robust phylogenetic estimation at deep timescales. We applied this method to a highly diverse group of venomous marine snails, Conoidea, for which published phylogenetic trees remain mostly unresolved for the deeper nodes. We targeted 850 protein coding genes (678,322 bp) in ca. 120 samples, spanning all (except one) known families of Conoidea and a broad selection of non-Conoidea neogastropods. The capture was successful for most samples, although capture efficiency decreased when DNA libraries were of insufficient quality and/or quantity (dried samples or low starting DNA concentration) and when targeting the most divergent lineages. An average of 75.4% of proteins was recovered, and the resulting tree, reconstructed using both supermatrix (IQ-tree) and supertree (Astral-II, combined with the Weighted Statistical Binning method) approaches, are almost fully supported. A reconstructed fossil-calibrated tree dates the origin of Conoidea to the Lower Cretaceous. We provide descriptions for two new families. The phylogeny revealed in this study provides a robust framework to reinterpret changes in Conoidea anatomy through time. Finally, we used the phylogeny to test the impact of the venom gland and radular type on diversification rates. Our analyses revealed that repeated losses of the venom gland had no effect on diversification rates, while families with a breadth of radula types showed increases in diversification rates, thus suggesting that trophic ecology may have an impact on the evolution of Conoidea.
- Published
- 2018
5. Targeted Sequencing of Venom Genes from Cone Snail Genomes Improves Understanding of Conotoxin Molecular Evolution
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Mark A Phuong and I Gusti Ngurah Kade Mahardika
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0301 basic medicine ,Gene Expression ,Venom ,Computational biology ,complex mixtures ,Genome ,Cone snail ,Evolution, Molecular ,03 medical and health sciences ,Exon ,Molecular evolution ,Genetics ,Animals ,Conotoxin ,Conidae ,Molecular Biology ,Gene ,Discoveries ,Ecology, Evolution, Behavior and Systematics ,biology ,Conus Snail ,Exons ,biology.organism_classification ,030104 developmental biology ,Multigene Family ,Conotoxins - Abstract
To expand our capacity to discover venom sequences from the genomes of venomous organisms, we applied targeted sequencing techniques to selectively recover venom gene superfamilies and nontoxin loci from the genomes of 32 cone snail species (family, Conidae), a diverse group of marine gastropods that capture their prey using a cocktail of neurotoxic peptides (conotoxins). We were able to successfully recover conotoxin gene superfamilies across all species with high confidence (> 100× coverage) and used these data to provide new insights into conotoxin evolution. First, we found that conotoxin gene superfamilies are composed of one to six exons and are typically short in length (mean = ∼85 bp). Second, we expanded our understanding of the following genetic features of conotoxin evolution: 1) positive selection, where exons coding the mature toxin region were often three times more divergent than their adjacent noncoding regions, 2) expression regulation, with comparisons to transcriptome data showing that cone snails only express a fraction of the genes available in their genome (24–63%), and 3) extensive gene turnover, where Conidae species varied from 120 to 859 conotoxin gene copies. Finally, using comparative phylogenetic methods, we found that while diet specificity did not predict patterns of conotoxin evolution, dietary breadth was positively correlated with total conotoxin gene diversity. Overall, the targeted sequencing technique demonstrated here has the potential to radically increase the pace at which venom gene families are sequenced and studied, reshaping our ability to understand the impact of genetic changes on ecologically relevant phenotypes and subsequent diversification.
- Published
- 2018
6. Lack of Signal for the Impact of Conotoxin Gene Diversity on Speciation Rates in Cone Snails
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Jonathan R. Hendricks, Thomas von Rintelen, Philipp W H Vogt, Michael E. Alfaro, Ristiyanti M. Marwoto, Romanus Edy Prabowo, Mark A Phuong, I Gusti Ngurah Kade Mahardika, Nicolas Puillandre, and Serb, Joanne
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0106 biological sciences ,0301 basic medicine ,Genetic Speciation ,Gastropoda ,Macroevolution ,010603 evolutionary biology ,01 natural sciences ,complex mixtures ,03 medical and health sciences ,Phylogenetics ,Genetic algorithm ,Genetics ,Animals ,Conotoxin ,Conidae ,Ecology, Evolution, Behavior and Systematics ,Evolutionary Biology ,Phylogenetic tree ,biology ,Genetic Variation ,venom evolution ,biology.organism_classification ,Biological Evolution ,Evolvability ,phylogenetics ,030104 developmental biology ,Evolutionary biology ,Adaptation ,Conotoxins ,Regular Articles ,Biotechnology - Abstract
Understanding why some groups of organisms are more diverse than others is a central goal in macroevolution. Evolvability, or the intrinsic capacity of lineages for evolutionary change, is thought to influence disparities in species diversity across taxa. Over macroevolutionary time scales, clades that exhibit high evolvability are expected to have higher speciation rates. Cone snails (family: Conidae, $>$900 spp.) provide a unique opportunity to test this prediction because their toxin genes can be used to characterize differences in evolvability between clades. Cone snails are carnivorous, use prey-specific venom (conotoxins) to capture prey, and the genes that encode venom are known and diversify through gene duplication. Theory predicts that higher gene diversity confers a greater potential to generate novel phenotypes for specialization and adaptation. Therefore, if conotoxin gene diversity gives rise to varying levels of evolvability, conotoxin gene diversity should be coupled with macroevolutionary speciation rates. We applied exon capture techniques to recover phylogenetic markers and conotoxin loci across 314 species, the largest venom discovery effort in a single study. We paired a reconstructed timetree using 12 fossil calibrations with species-specific estimates of conotoxin gene diversity and used trait-dependent diversification methods to test the impact of evolvability on diversification patterns. Surprisingly, we did not detect any signal for the relationship between conotoxin gene diversity and speciation rates, suggesting that venom evolution may not be the rate-limiting factor controlling diversification dynamics in Conidae. Comparative analyses showed some signal for the impact of diet and larval dispersal strategy on diversification patterns, though detection of a signal depended on the dataset and the method. If our results remain true with increased taxonomic sampling in future studies, they suggest that the rapid evolution of conid venom may cause other factors to become more critical to diversification, such as ecological opportunity or traits that promote isolation among lineages.
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- 2019
7. Following the rivers: historical reconstruction of California volesMicrotus californicus(Rodentia: Cricetidae) in the deserts of eastern California
- Author
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Marisa C. W. Lim, Sebastian Höhna, Mark A Phuong, James L. Patton, Chris J. Conroy, and Brett E. Parmenter
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0106 biological sciences ,0301 basic medicine ,education.field_of_study ,biology ,Pleistocene ,Ecology ,Population ,Endangered species ,biology.organism_classification ,010603 evolutionary biology ,01 natural sciences ,03 medical and health sciences ,Phylogeography ,030104 developmental biology ,California vole ,Vole ,Microtus ,education ,Ecology, Evolution, Behavior and Systematics ,Cricetidae - Abstract
The California vole, Microtus californicus, restricted to habitat patches where water is available nearly year-round, is a remnant of the mesic history of the southern Great Basin and Mojave deserts of eastern California. The history of voles in this region is a model for species-edge population dynamics through periods of climatic change. We sampled voles from the eastern deserts of California and examined variation in the mitochondrial cytb gene, three nuclear intron regions, and across 12 nuclear microsatellite markers. Samples are allocated to two mitochondrial clades: one associated with southern California and the other with central and northern California. The limited mtDNA structure largely recovers the geographical distribution, replicated by both nuclear introns and microsatellites. The most remote population, Microtus californicus scirpensis at Tecopa near Death Valley, was the most distinct. This population shares microsatellite alleles with both mtDNA clades, and both its northern clade nuclear introns and southern clade mtDNA sequences support a hybrid origin for this endangered population. The overall patterns support two major invasions into the desert through an ancient system of riparian corridors along streams and lake margins during the latter part of the Pleistocene followed by local in situ divergence subsequent to late Pleistocene and Holocene drying events. Changes in current water resource use could easily remove California voles from parts of the desert landscape.
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- 2016
8. Lack of signal for the impact of venom gene diversity on speciation rates in cone snails
- Author
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Michael E. Alfaro, Ristiyanti M. Marwoto, Thomas von Rintelen, Jonathan R. Hendricks, I Gusti Ngurah Kade Mahardika, Mark A Phuong, Philipp W H Vogt, Nicolas Puillandre, and Romanus Edy Prabowo
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0106 biological sciences ,0303 health sciences ,biology ,Phylogenetic tree ,Macroevolution ,biology.organism_classification ,010603 evolutionary biology ,01 natural sciences ,complex mixtures ,Evolvability ,03 medical and health sciences ,Evolutionary biology ,Genetic algorithm ,Biological dispersal ,Conotoxin ,Conidae ,Adaptation ,030304 developmental biology - Abstract
Understanding why some groups of organisms are more diverse than others is a central goal in macroevolution. Evolvability, or lineages’ intrinsic capacity for evolutionary change, is thought to influence disparities in species diversity across taxa. Over macroevolutionary time scales, clades that exhibit high evolvability are expected to have higher speciation rates. Cone snails (family: Conidae, >900 spp.) provide a unique opportunity to test this prediction because their venom genes can be used to characterize differences in evolvability between clades. Cone snails are carnivorous, use prey-specific venom (conotoxins) to capture prey, and the genes that encode venom are known and diversify through gene duplication. Theory predicts that higher gene diversity confers a greater potential to generate novel phenotypes for specialization and adaptation. Therefore, if conotoxin gene diversity gives rise to varying levels of evolvability, conotoxin gene diversity should be coupled with macroevolutionary speciation rates. We applied exon capture techniques to recover phylogenetic markers and conotoxin loci across 314 species, the largest venom discovery effort in a single study. We paired a reconstructed timetree using 12 fossil calibrations with species-specific estimates of conotoxin gene diversity and used trait-dependent diversification methods to test the impact of evolvability on diversification patterns. Surprisingly, did not detect any signal for the relationship between conotoxin gene diversity and speciation rates, suggesting that venom evolution may not be the rate-limiting factor controlling diversification dynamics in Conidae. Comparative analyses showed some signal for the impact of diet and larval dispersal strategy on diversification patterns, though whether or not we detected a signal depended on the dataset and the method. If our results remain true with increased sampling in future studies, they suggest that the rapid evolution of Conidae venom may cause other factors to become more critical to diversification, such as ecological opportunity or traits that promote isolation among lineages.
- Published
- 2018
- Full Text
- View/download PDF
9. Delimiting species in the genusOtospermophilus(Rodentia: Sciuridae), using genetics, ecology, and morphology
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Marisa C. W. Lim, Daniel R. Wait, Kevin C. Rowe, Craig Moritz, and Mark A Phuong
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Evolutionary biology ,Ecology ,Genus ,Ecology (disciplines) ,Molecular phylogenetics ,Zoology ,Morphology (biology) ,Biology ,Otospermophilus ,biology.organism_classification ,Vertebrate zoology ,Ecology, Evolution, Behavior and Systematics - Abstract
This workwas supported by UC Berkeley Summer Undergradu-ate Research Fellowships to MAP and ML, UC Berke-ley Biology Fellows Program Awards to DRW and MAP,the Museum of Vertebrate Zoology UndergraduateBiodiversity Award, and the NSF DEB 0640859 to CM.
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- 2014
10. RANGE INSTABILITY LEADS TO CYTONUCLEAR DISCORDANCE IN A MORPHOLOGICALLY CRYPTIC GROUND SQUIRREL SPECIES COMPLEX
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Ke Bi, Craig Moritz, and Mark A Phuong
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0106 biological sciences ,0301 basic medicine ,Gene Flow ,Male ,Species complex ,X Chromosome ,Library science ,Biology ,010603 evolutionary biology ,01 natural sciences ,DNA, Mitochondrial ,Article ,03 medical and health sciences ,Genetics ,Animals ,Mexico ,Ecology, Evolution, Behavior and Systematics ,Ecosystem ,Phylogeny ,Ecology ,Sciuridae ,Exons ,Biological Evolution ,Phylogeography ,030104 developmental biology ,Undergraduate research ,Female ,Animal Distribution - Abstract
The processes responsible for cytonuclear discordance frequently remain unclear. Here, we employed an exon capture data set and demographic methods to test hypotheses generated by species distribution models to examine how contrasting histories of range stability vs. fluctuation have caused cytonuclear concordance and discordance in ground squirrel lineages from the Otospermophilus beecheyi species complex. Previous studies in O. beecheyi revealed three morphologically cryptic and highly divergent mitochondrial DNA lineages (named the Northern, Central and Southern lineages based on geography) with only the Northern lineage exhibiting concordant divergence for nuclear genes. Here, we showed that these mtDNA lineages likely formed in allopatry during the Pleistocene, but responded differentially to climatic changes that occurred since the last interglacial (~120,000 years ago). We find that the Northern lineage maintained a stable range throughout this period, correlating with genetic distinctiveness among all genetic markers and low migration rates with the other lineages. In contrast, our results suggested that the Southern lineage expanded from Baja California Sur during the Late Pleistocene to overlap and potentially swamp a contracting Central lineage. High rates of intraspecific gene flow between Southern lineage individuals among expansion origin and expansion edge populations largely eroded Central ancestry from autosomal markers. However, male-biased dispersal in this system preserved signals of this past hybridization and introgression event in matrilineal-biased X-chromosome and mtDNA markers. Our results highlight the importance of range stability in maintaining the persistence of phylogeographic lineages, whereas unstable range dynamics can increase the tendency for lineages to merge upon secondary contact.
- Published
- 2017
11. Targeted sequencing of venom genes from cone snail genomes reveals coupling between dietary breadth and conotoxin diversity
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I Gusti Ngurah Kade Mahardika and Mark A Phuong
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0106 biological sciences ,0303 health sciences ,biology ,Phylogenetic tree ,Ecology ,Venom ,biology.organism_classification ,010603 evolutionary biology ,01 natural sciences ,Genome ,complex mixtures ,Cone snail ,03 medical and health sciences ,Evolutionary biology ,Gene family ,Conotoxin ,Conidae ,Gene ,030304 developmental biology - Abstract
Although venomous taxa provide an attractive system to study the genetic basis of adaptation and speciation, the slow pace of toxin gene discovery through traditional laboratory techniques (e.g., cDNA cloning) have limited their utility in the study of ecology and evolution. Here, we applied targeted sequencing techniques to selectively recover venom gene superfamilies and non-toxin loci from the genomes of 32 species of cone snails (family, Conidae), a hyper diverse group of carnivorous marine gastropods that capture their prey using a cocktail of neurotoxic proteins (conotoxins). We were able to successfully recover conotoxin gene superfamilies across all species sequenced in this study with high confidence (> 100X coverage). We found that conotoxin gene superfamilies are composed of 1-6 exons and adjacent noncoding regions are not enriched for simple repetitive elements. Additionally, we provided further evidence for several genetic factors shaping venom composition in cone snails, including positive selection, extensive gene turnover, expression regulation, and potentially, presence-absence variation. Using comparative phylogenetic methods, we found that while diet specificity did not predict patterns of conotoxin gene superfamily size evolution, dietary breadth was positively correlated with total conotoxin gene diversity. These results continue to emphasize the importance of dietary breadth in shaping venom evolution, an underappreciated ecological correlate in venom biology. Finally, the targeted sequencing technique demonstrated here has the potential to radically increase the pace at which venom gene families are sequenced and studied, reshaping our ability to understand the impact of genetic changes on ecologically relevant phenotypes and subsequent diversification.
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- 2017
- Full Text
- View/download PDF
12. Range Stability Predicts Lineage Persistence in a Morphologically Cryptic Ground Squirrel Species Complex
- Author
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Mark A Phuong, Craig Moritz, and Ke Bi
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0106 biological sciences ,0303 health sciences ,Mitochondrial DNA ,Species complex ,Ecology ,Range (biology) ,Lineage (evolution) ,Allopatric speciation ,Biology ,010603 evolutionary biology ,01 natural sciences ,Gene flow ,03 medical and health sciences ,Phylogeography ,Evolutionary biology ,Biological dispersal ,10. No inequality ,030304 developmental biology - Abstract
The processes responsible for patterns of cytonuclear discordance remain unclear. Here, we employ an exon capture dataset, demographic methods, and species distribution modeling to elucidate the impact of historical demography on patterns of genealogical concordance and discordance in ground squirrel lineages from theOtospermophilus beecheyispecies complex. Previous studies inO. beecheyirevealed three morphologically cryptic and highly divergent mitochondrial DNA (mtDNA) lineages (named the Northern, Central, and Southern lineages based on geography) with only the Northern lineage exhibiting concordant divergence in nuclear markers. We show that these mtDNA lineages likely formed in allopatry during the Pleistocene, but responded differentially to climatic changes that occurred since the last interglacial (∼120,000 years ago). We find that the Northern lineage maintained a stable range throughout this period, correlating with genetic distinctiveness among all genetic markers and low migration rates between the other lineages. In contrast, our results support a scenario where the Southern lineage expanded from Baja California Sur during the Late Pleistocene and hybridized with the Central lineage, eventually driving the Central lineage to extinction. While high intraspecific gene flow among newly colonized populations eroded significant signals of Central ancestry from autosomal markers, male sex-biased dispersal in this system preserved signals of this past hybridization and introgression event in matrilineal-biased X-chromosome and mtDNA markers. Our results highlight the importance of range stability in maintaining the persistence of phylogeographic lineages, whereas unstable range dynamics can increase the tendency for lineages to interact and collapse upon secondary contact.
- Published
- 2016
13. Dietary Breadth is Positively Correlated with Venom Complexity in Cone Snails
- Author
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Michael E. Alfaro, Mark A Phuong, and I Gusti Ngurah Kade Mahardika
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0106 biological sciences ,0301 basic medicine ,Venom duct transcriptome ,Bioinformatics ,Gene Expression ,Poison control ,Zoology ,Venom ,Comparative biology ,Generalist and specialist species ,010603 evolutionary biology ,01 natural sciences ,Medical and Health Sciences ,complex mixtures ,Predation ,Cone snail ,03 medical and health sciences ,Phylogenetics ,Information and Computing Sciences ,Genetics ,Animals ,Cluster Analysis ,Conotoxin ,Conidae ,Phylogeny ,Nutrition ,030304 developmental biology ,0303 health sciences ,Phylogenetic tree ,biology ,Venoms ,Ecology ,Gene Expression Profiling ,Conus Snail ,Computational Biology ,High-Throughput Nucleotide Sequencing ,Biological Sciences ,biology.organism_classification ,Animal Feed ,030104 developmental biology ,Molluscivore ,Peptides ,Transcriptome ,Research Article ,Biotechnology - Abstract
Background Although diet is believed to be a major factor underlying the evolution of venom, few comparative studies examine both venom composition and diet across a radiation of venomous species. Cone snails within the family, Conidae, comprise more than 700 species of carnivorous marine snails that capture their prey by using a cocktail of venomous neurotoxins (conotoxins or conopeptides). Venom composition across species has been previously hypothesized to be shaped by (a) prey taxonomic class (i.e., worms, molluscs, or fish) and (b) dietary breadth. We tested these hypotheses under a comparative phylogenetic framework using ecological data from past studies in conjunction with venom duct transcriptomes sequenced from 12 phylogenetically disparate cone snail species, including 10 vermivores (worm-eating), one molluscivore, and one generalist. Results We discovered 2223 unique conotoxin precursor peptides that encoded 1864 unique mature toxins across all species, >90 % of which are new to this study. In addition, we identified two novel gene superfamilies and 16 novel cysteine frameworks. Each species exhibited unique venom profiles, with venom composition and expression patterns among species dominated by a restricted set of gene superfamilies and mature toxins. In contrast with the dominant paradigm for interpreting Conidae venom evolution, prey taxonomic class did not predict venom composition patterns among species. We also found a significant positive relationship between dietary breadth and measures of conotoxin complexity. Conclusions The poor performance of prey taxonomic class in predicting venom components suggests that cone snails have either evolved species-specific expression patterns likely as a consequence of the rapid evolution of conotoxin genes, or that traditional means of categorizing prey type (i.e., worms, mollusc, or fish) and conotoxins (i.e., by gene superfamily) do not accurately encapsulate evolutionary dynamics between diet and venom composition. We also show that species with more generalized diets tend to have more complex venoms and utilize a greater number of venom genes for prey capture. Whether this increased gene diversity confers an increased capacity for evolutionary change remains to be tested. Overall, our results corroborate the key role of diet in influencing patterns of venom evolution in cone snails and other venomous radiations. Electronic supplementary material The online version of this article (doi:10.1186/s12864-016-2755-6) contains supplementary material, which is available to authorized users.
- Published
- 2015
- Full Text
- View/download PDF
14. Nitric oxide signaling differentially affects habitat choice by two larval morphs of the sea slugAlderia willowi: mechanistic insight into evolutionary transitions in dispersal strategies
- Author
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Mark A. Phuong, Melissa R. Romero, Patrick J. Krug, and Cory D. Bishop
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Serotonin ,animal structures ,Physiology ,Dopamine ,media_common.quotation_subject ,Gastropoda ,Adaptation, Biological ,Aquatic Science ,Biology ,Arginine ,Nitric Oxide ,Generalist and specialist species ,Models, Biological ,California ,Cyclic N-Oxides ,Levodopa ,Animals ,Metamorphosis ,Cyclic GMP ,Molecular Biology ,Ecosystem ,Ecology, Evolution, Behavior and Systematics ,media_common ,Analysis of Variance ,Appetitive Behavior ,Larva ,Ecology ,Marine larval ecology ,fungi ,Imidazoles ,Metamorphosis, Biological ,biology.organism_classification ,Biological Evolution ,Sea slug ,Sexual dimorphism ,NG-Nitroarginine Methyl Ester ,Insect Science ,Linear Models ,Biological dispersal ,Animal Science and Zoology ,Animal Distribution ,Stramenopiles ,Signal Transduction - Abstract
SummaryIn many marine animals, adult habitat is selected by lecithotrophic (non-feeding) larvae with a limited lifespan. In generalist species, larvae may increasingly accept sub-optimal habitat over time as energy stores are depleted (‘desperate larva’ hypothesis). If the fitness cost of suboptimal habitat is too high, larvae of specialists may prolong the searching phase until encountering a high-quality patch or dying (‘death before dishonor’ hypothesis). In generalists, starvation is hypothesized to lead to a decline in inhibitory nitric oxide (NO) signaling, thereby triggering metamorphosis. Here, we document alternative functions for identified signaling pathways in larvae having ‘desperate’ versus ‘death before dishonor’ strategies in lecithotrophic clutches of a habitat specialist, the sea slug Alderia willowi. In an unusual dimorphism, each clutch of A. willowi hatches both non-selective larvae that settle soon after hatching, and siblings that delay settlement in the absence of cues from the alga Vaucheria, the sole adult food. Phamacological manipulation of NO signaling induced metamorphosis in non-selective but not selective stages. However, decreased NO signaling in selective larvae lowered the threshold for response to habitat cues, mimicking the effect of declining energy levels. Manipulation of cGMP or dopamine production induced metamorphosis in selective and non-selective larvae alike, highlighting a distinct role for the NO pathway in the two larval morphs. We propose a model in which NO production (i) links nitrogen metabolism with sensory receptor signaling, and (ii) shifts from a regulatory role in ‘desperate larva’ strategies to a modulatory role in ‘death-before-dishonor’ strategies. This study provides new mechanistic insight into how the function of conserved signaling pathways may change in response to selection on larval habitat choice behaviors.
- Published
- 2012
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