Hydrilla verticillata is an invasive aquatic plant found in freshwater systems throughout the United States. Invasions pose a threat to plants and animals that come into contact with the rapidly expanding hydrilla, and recreational activities such as fishing and boating are disrupted when densely packed mats of vegetative material form near the surface of the water. These invasions have historically been controlled using the herbicide fluridone, but resistant hydrilla populations have emerged with mutations in the pds gene associated with the production of phytoene desaturase. These resistant mutant plants are outwardly indistinguishable from the susceptible wildtype, and as such it can be challenging for aquatic systems managers to identify whether or not fluridone can be considered as an effective treatment option without some form of genetic testing. The existing standard process for identifying resistant mutants is a lengthy process that relies on amplifying and sequencing the pds gene. Our work has sought to utilize the process of double-mismatch allele-specific qPCR (DMAS-qPCR) to create a quicker and more cost-effective tool to aid in understanding the extent of fluridone resistant hydrilla. Having designed sets of primers specific to the mutations found within the pds gene, the next step is to apply this method to screening hydrilla samples from a variety of geographies in order to outline the spread of the resistant mutant populations.

The prevalence of antimicrobial-resistant bacteria is a rapidly growing public health crisis. This, combined with a decline in the development of novel antimicrobial therapies, makes the search for unique drug targets essential. Previous work from our lab has identified a promising antimicrobial drug target within Bacillus anthracis, the regulatory ATPase, ClpX. ClpX is essential for virulence in B. anthracis and critical for resistance to a host of cell envelope-targeting antimicrobials. ClpX works with ClpP to form a global protease that regulates a wide range of proteins, including transcriptional regulators. Previously, we conducted a microarray of a ΔclpX mutant and found 119 genes with altered expression. One such gene, msrB, has been studied for reactive oxygen species tolerance in other pathogens. This gene encodes for methionine sulfoxide reductase, an antioxidant enzyme that restores functionality to oxidized methionine residues. Increased msrB expression was seen with oxacillin exposure in S. aureus, indicating a potential connection between MsrB and cell wall-targeting antimicrobials. In B. anthracis Sterne, loss of msrB induces sensitivity to penicillin, but unlike ΔclpX, this phenotype is not seen with daptomycin or LL-37. This suggests that the role of msrB in antimicrobial tolerance may be limited to cell wall active antibiotics. Further experiments will include testing the ΔmsrB mutant with additional cell wall-specific antimicrobials (e.g., bacitracin and vancomycin). Our research provides additional information regarding the role of MsrB in the bacterial cell and its potential suitability as a pharmacological target to increase susceptibility to antibiotics.

Understanding the diversity and distribution of species on Earth is crucial in the face of contemporary threats to biodiversity, such as climate change and unsustainable economic practices. Unfortunately, the process of documenting and describing biodiversity often cannot keep pace with habitat loss and species extinction, especially in tropical regions where the number of undescribed and poorly known species is highest, and where biodiversity is most severely threatened. If this diversity is not documented, it will mean a loss of valuable understanding of the natural world and a failure to recognize species whose societal values remain undiscovered or underappreciated. This research will assess the extinction risk of selected fern species to understand their conservation status. The focus lies on understanding the classification, distribution, and conservation status of a group of species within the fern genus Elaphoglossum, the Elaphoglossum dendricola Clade, consisting of around 12 species distributed in the Tropical Andes, mostly at high altitudes (over 2400 m). This assessment aims to serve as a baseline for future conservation studies of this neotropical group of ferns.

Due to widespread anthropogenic emissions and a global atmospheric cycle, mercury contaminates all aquatic ecosystems, including in the Arctic, at concentrations above pre-industrial baselines. Many seabirds nest in large colonies in the Arctic and are at elevated risk of mercury contamination due to their planktivorous and piscivorous diets and long lifespan. We investigated temporal trends of mercury contamination in five species of seabirds from northwest Greenland. Blood samples were collected regularly since 2010 from adult Atlantic puffins (Fracterula arctica), black guillemots (Cepphus grylle), black-legged kittiwakes (Rissa tridactyla), dovekies (Alle alle) and thick-billed murres (Uria lomvia). Samples were analyzed for total mercury using direct mercury analysis. All species had average blood mercury concentrations between 212 and 769 ng/g-wet weight, concentrations associated with a low risk for mercury toxicity. Individual black guillemots and thick-billed murres had blood mercury concentrations >1,000 ng/g wet weight, concentrations associated with moderate risk for mercury toxicity. Preliminary analyses suggest an overall increase in mercury concentrations in black-legged kittiwakes, dovekies and thick-billed murres over the study period. Comparable temporal studies in the Arctic have shown wide variation in mercury contamination trends. The results of the present study contribute to the understanding of regional mercury trends in the Arctic and efforts to assess the impact of the Minamata Convention.

Silicon-Perovskite tandem solar cells are some of the leading emerging technology solar cells due to their high photoconversion efficiency or the ability to turn light into electricity. These solar cells rely on the ability to harvest a higher percentage of the solar spectrum due to the differences in the two materials. MHPs are an ionic crystal that have the chemical formula ABX3 where A is a monovalent cation (+1) such as cesium, methylammonium or formamidinium; B is a divalent cation (+2) such as lead or tin, and X is a halide such as chloride, bromide, or iodide. Porous silicon is crystalline silicon that has been etched to form pores with properties dependent upon the etching conditions. Porous silicon that has been etched such that the silicon area between the pores is between 1-4nm becomes photoluminescent (PL). It has been shown that the optoelectronic properties of metal halide perovskite (MHPs) grown within porous silicon (pSi) are highly dependent upon the surface area, pore size, and surface chemistry of the pSi. This interaction has led us to investigate the fundamental interactions that occur when nanoscale porous silicon encounters nanoscale MHP, namely the possibility of energy/charge transfer.
We have evaluated two different experimental designs. The first entails adsorbing ligand passivated MHP quantum dots onto a solid piece of luminescent mesoporous Si membrane and allow the solvent to evaporate. The change in luminescence from the pSi can be used to monitor the impact the perovskite has upon the pSi by monitoring the change in intensity and wavelength. The second approach as previously described utilizes MHP quantum dots (QDs) dispersed in toluene which is then titrated with non-luminescent pSi and the PL monitored. The primary impact of the pSi upon the light emission of the perovskite QDs is a significant reduction in the intensity of the emission. Comparisons of different pSi with hydride terminated versus oxide terminated surfaces show a dependence upon the surface chemistry to the change in PL. The PL lifetimes will be measured, and comparisons made to determine the mechanism of energy transfer.