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Kubanek,
Julia
Kubanek,
Julia
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ItemMetabolomics and Proteomics Reveal Impacts of Chemically Mediated Competition on Marine Plankton Dataset(Georgia Institute of Technology, 2017-12-22) Poulson-Ellestad, Kelsey L. ; Jones, Christina ; Roy, Jessie ; Viant, Mark ; Fernández, Facundo M. ; Kubanek, Julia ; Nunn, BrookCompetition is a major force structuring marine planktonic communities. The release of compounds that inhibit competitors, a process known as allelopathy, may play a role in the maintenance of large blooms of the red-tide dinoflagellate Karenia brevis, which produces potent neurotoxins that negatively impact coastal marine ecosystems. K. brevis is variably allelopathic to multiple competitors, typically causing sublethal suppression of growth. We used metabolomic and proteomic analyses to investigate the role of chemically mediated ecological interactions between K. brevis and two diatom competitors, Asterionellopsis glacialis and Thalassiosira pseudonana. The impact of K. brevis allelopathy on competitor physiology was reflected in the metabolomes and expressed proteomes of both diatoms, although the diatom that co-occurs with K. brevis blooms (A. glacialis) exhibited more robust metabolism in response to K. brevis. The observed partial resistance of A. glacialis to allelopathy may be a result of its frequent exposure to K. brevis blooms in the Gulf of Mexico. For the more sensitive diatom, T. pseudonana, which may not have had opportunity to evolve resistance to K. brevis, allelopathy disrupted energy metabolism and impeded cellular protection mechanisms including altered cell membrane components, inhibited osmoregulation, and increased oxidative stress. Allelopathic compounds appear to target multiple physiological pathways in sensitive competitors, demonstrating that chemical cues in the plankton have the potential to alter large-scale ecosystem processes including primary production and nutrient cycling.
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ItemChemical Encoding of Risk Perception and Predator Detection Among Estuarine Invertebrates Dataset(Georgia Institute of Technology, 2017-12-07) Poulin, Remington X. ; Lavoie, Serge ; Siegel, Katherine ; Gaul, David A. ; Weissburg, Marc J. ; Kubanek, JuliaThe data files in "Archived PCA Spectra" and “Archived PLS-R Spectra” contain the unprocessed 1H NMR spectral data files underlying the publication " Chemical encoding of risk perception and predator detection among estuarine invertebrates."
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ItemVariable Allelopathy Among Phytoplankton Reflected in Red Tide Metabolome Dataset(Georgia Institute of Technology, 2017-12-06) Poulin, Remington X. ; Poulson-Ellestad, Kelsey L. ; Roy, Jessie S. ; Kubanek, JuliaDataset for Harmful Algae Manuscript titled: "Variable allelopathy among phytoplankton reflected in red tide metabolome"
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ItemKarenia brevis allelopathy compromises the lipidome, membrane integrity, and photosynthesis of competitors (dataset)(Georgia Institute of Technology, 2015-12-17) Poulin, R. X. ; Kubanek, JuliaThe attached data files underlie the forthcoming publication, "Karenia brevis allelopathy compromises the lipidome, membrane integrity, and photosynthesis of competitors".
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ItemYou are what you eat: A combined metabolomics – bioassay approach to understanding prey responses to chemical cues produced by predators fed different diets dataset(Georgia Institute of Technology, 2015-09-09) Weissburg, Marc J. ; Poulin, R.X. ; Kubanek, Julia
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ItemWarding Off Disease on Coral Reefs: Antimicrobial Chemical Cues and their Future in Drug Discovery(Georgia Institute of Technology, 2012-05-08) Kubanek, JuliaUnlike many animals, seaweeds do not possess adaptive immune systems to ward off disease. In many cases, they produce small molecules – natural antibiotics – that prevent colonization or infection by pathogens. We have found that seaweeds produce unusual secondary metabolites against pathogen attack, including complex isoprenoid-and shikimate-derived macrolides not seen in any other organisms. Surprisingly, these natural antifungals are not distributed evenly across algal surfaces; instead they are concentrated at discrete surface patches where they provide bursts of protection at sites that may be especially vulnerable to infection due to prior wounding. Working with the Fernandez lab at Georgia Tech, we applied surface imaging mass spectrometry to intact algal surfaces to show that antifungal defenses are heterogeneously distributed, with compound concentrations high enough at localized patches to block infection. This patchy distribution may represent an optimal defense strategy, in which the most vulnerable parts of the alga are best defended. Chemical defenses of seaweeds also serve as valuable leads for pharmaceutical development. Members of one group of algal antifungal agents, the bromophycolides, exhibit potent in vitro and in vivo antimalarial activity with an unexpected mechanism of action, inhibiting growth of the malarial parasite Plasmodium falciparum at sub-micromolar concentrations. Using a molecular probe designed from the seaweed’s antifungal agent, we identified a major molecular target and drug binding mechanism within the malaria parasite that is helping guide our synthesis of novel analogs for future development.
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ItemA biochemical, genetic, and genomic investigation of the evolution and ecology of sexual reproduction(Georgia Institute of Technology, 2010-11-17) Snell, Terry W. ; Kubanek, Julia
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ItemBiochemical Warfare on the Reef: The Role of Glutathione Transferases in Consumer Tolerance of Dietary Prostaglandins(Georgia Institute of Technology, 2010-01-06) Whalen, Kristen E. ; Lane, Amy L. ; Kubanek, Julia ; Hahn, Mark E.Background: Despite the profound variation among marine consumers in tolerance for allelochemically-rich foods, few studies have examined the biochemical adaptations underlying diet choice. Here we examine the role of glutathione Stransferases (GSTs) in the detoxification of dietary allelochemicals in the digestive gland of the predatory gastropod Cyphoma gibbosum, a generalist consumer of gorgonian corals. Controlled laboratory feeding experiments were used to investigate the influence of gorgonian diet on Cyphoma GST activity and isoform expression. Gorgonian extracts and semipurified fractions were also screened to identify inhibitors and possible substrates of Cyphoma GSTs. In addition, we investigated the inhibitory properties of prostaglandins (PGs) structurally similar to antipredatory PGs found in high concentrations in the Caribbean gorgonian Plexaura homomalla. Principal Findings: Cyphoma GST subunit composition was invariant and activity was constitutively high regardless of gorgonian diet. Bioassay-guided fractionation of gorgonian extracts revealed that moderately hydrophobic fractions from all eight gorgonian species examined contained putative GST substrates/inhibitors. LC-MS and NMR spectral analysis of the most inhibitory fraction from P. homomalla subsequently identified prostaglandin A2 (PGA2) as the dominant component. A similar screening of commercially available prostaglandins in series A, E, and F revealed that those prostaglandins most abundant in gorgonian tissues (e.g., PGA2) were also the most potent inhibitors. In vivo estimates of PGA2 concentration in digestive gland tissues calculated from snail grazing rates revealed that Cyphoma GSTs would be saturated with respect to PGA2 and operating at or near physiological capacity. Significance: The high, constitutive activity of Cyphoma GSTs is likely necessitated by the ubiquitous presence of GST substrates and/or inhibitors in this consumer’s gorgonian diet. This generalist’s GSTsmay operate as ‘all-purpose’ detoxification enzymes, capable of conjugating or sequestering a broad range of lipophilic gorgonian compounds, thereby allowing this predator to exploit a range of chemically-defended prey, resulting in a competitive dietary advantage for this species.
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ItemGenetic determinants of mate recognition in Brachionus manjavacas (Rotifera)(Georgia Institute of Technology, 2009-09-09) Snell, Terry W. ; Shearer, Tonya L ; Smith, Hilary A. ; Kubanek, Julia ; Gribble, Kristin E. ; Welch , David B. MarkBackground: Mate choice is of central importance to most animals, influencing population structure, speciation, and ultimately the survival of a species. Mating behavior of male brachionid rotifers is triggered by the product of a chemosensory gene, a glycoprotein on the body surface of females called the mate recognition pheromone. The mate recognition pheromone has been biochemically characterized, but little was known about the gene(s). We describe the isolation and characterization of the mate recognition pheromone gene through protein purification, N-terminal amino acid sequence determination, identification of the mate recognition pheromone gene from a cDNA library, sequencing, and RNAi knockdown to confirm the functional role of the mate recognition pheromone gene in rotifer mating. Results: A 29 kD protein capable of eliciting rotifer male circling was isolated by high-performance liquid chromatography. Two transcript types containing the N-terminal sequence were identified in a cDNA library; further characterization by screening a genomic library and by polymerase chain reaction revealed two genes belonging to each type. Each gene begins with a signal peptide region followed by nearly perfect repeats of an 87 to 92 codon motif with no codons between repeats and the final motif prematurely terminated by the stop codon. The two Type A genes contain four and seven repeats and the two Type B genes contain three and five repeats, respectively. Only the Type B gene with three repeats encodes a peptide with a molecular weight of 29 kD. Each repeat of the Type B gene products contains three asparagines as potential sites for N-glycosylation; there are no asparagines in the Type A genes. RNAi with Type A double-stranded RNA did not result in less circling than in the phosphate-buffered saline control, but transfection with Type B double-stranded RNA significantly reduced male circling by 17%. The very low divergence between repeat units, even at synonymous positions, suggests that the repeats are kept nearly identical through a process of concerted evolution. Information-rich molecules like surface glycoproteins are well adapted for chemical communication and aquatic animals may have evolved signaling systems based on these compounds, whereas insects use cuticular hydrocarbons. Conclusion: Owing to its critical role in mating, the mate recognition pheromone gene will be a useful molecular marker for exploring the mechanisms and rates of selection and the evolution of reproductive isolation and speciation using rotifers as a model system. The phylogenetic variation in the mate recognition pheromone gene can now be studied in conjunction with the large amount of ecological and population genetic data being gathered for the Brachionus plicatilis species complex to understand better the evolutionary drivers of cryptic speciation.
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ItemChemically mediated competition between microbes and animals: microbes as consumers in food webs(Georgia Institute of Technology, 2006-11) Burkepile, Deron E. ; Parker, John D. ; Woodson, Clifton Brock ; Mills, Heath Jordan ; Kubanek, Julia ; Sobecky, Patricia A. ; Hay, Mark E.Microbes are known to affect ecosystems and communities as decomposers, pathogens, and mutualists. However, they also may function as classic consumers and competitors with animals if they chemically deter larger consumers from using rich food-falls such as carrion, fruits, and seeds that can represent critical windfalls to both microbes and animals. Microbes often use chemicals (i.e., antibiotics) to compete against other microbes. Thus using chemicals against larger competitors might be expected and could redirect significant energy subsidies from upper trophic levels to the detrital pathway. When we baited traps in a coastal marine ecosystem with fresh vs. microbe-laden fish carrion, fresh carrion attracted 2.6 times as many animals per trap as microbe-laden carrion. This resulted from fresh carrion being found more frequently and from attracting more animals when found. Microbe-laden carrion was four times more likely to be uncolonized by large consumers than was fresh carrion. In the lab, the most common animal found in our traps (the stone crab Menippe mercenaria) ate fresh carrion 2.4 times more frequently than microbe-laden carrion. Bacteria-removal experiments and feeding bioassays using organic extracts of microbe-laden carrion showed that bacteria produced noxious chemicals that deterred animal consumers. Thus bacteria compete with large animal scavengers by rendering carcasses chemically repugnant. Because food-fall resources such as carrion are major food subsidies in many ecosystems, chemically mediated competition between microbes and animals could be an important, common, but underappreciated interaction within many communities.