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Description
White-nose syndrome (WNS) is a fungal infection devastating bat populations throughout eastern North America. WNS is caused by a fungus, Pseudogymnoascus destructans (Pd), that invades the skin of hibernating bats. While there are a number of treatments being researched, there is currently no effective treatment for WNS that is deployed in the field, except a few being tested on a limited scale. Bats have lowered immune function and response during hibernation, which may increase susceptibility to infection during the winter months. Antimicrobial peptides (AMPs) are a crucial component of the innate immune system and serve as barriers against infection. AMPs are constitutively expressed on skin and facilitate wound healing, stimulate other immune responses, and may also stay active on bat skin during hibernation. AMPs are expressed by all tissues, have direct killing abilities against microbes, and are a potential treatment for bats infected with Pd. In this investigation, the fungicidal activity of several readily available commercial AMPs were compared, and killing assay protocols previously investigated by Frasier and Lake were replicated to establish a control trial for use in future killing assays. Another aim of this investigation was to synthesize a bat-derived AMP for use in the killing assay. Sequences of bat-derived AMPs have been identified in bat skin samples obtained from a large geographic sampling of susceptible and resistant species. Contact was made with GenScript Inc., the company from which commercially available AMPs were purchased, to determine the characteristics of peptide sequences needed to synthesize an AMP for lab use. Based on recommendations from GenScript Inc., peptide sequences need to have a hydrophobicity of less than 50% and a sequence length of less than 50 amino acids. These criteria serve as a potential barrier because none of the known bat-derived sequences analyzed satisfy both of these requirements. The final aim of this study was to generate a conceptual model of the immune response molecules activated when bats are exposed to a fungal pathogen such as Pd. Overall, this work investigated sources of variability between trials of the killing assay, analyzed known bat-derived peptide sequences, and generated a conceptual model that will serve as a guideline for identification of immune response molecules on the skin of bats in future proteomics work.
ContributorsBarton, Madisen L (Author) / Moore, Marianne (Thesis director) / Penton, Christopher (Committee member) / College of Integrative Sciences and Arts (Contributor) / Barrett, The Honors College (Contributor)
Created2019-05
Description
White-nose syndrome (WNS) is a fungal disease that infects hibernating bats of multiple species across large portions of eastern North America. To date, WNS has been responsible for the deaths of over seven million bats. It is not yet known why certain species are able to resist infection. Since the fungus invades the skin and some resistant species show no signs of the characteristic cutaneous lesions, it seems likely that resistant species contain specific defense mechanisms within their skin, such as antimicrobial peptides (AMPs) and other immunologically relevant proteins expressed by specific cell types or as secreted soluble components. Proteomics could be a useful tool for understanding differences in susceptibility, and could help identify AMPs that could be synthesized and used as control agents against the spread of the causative fungus. This study is the first to optimize proteomics methods for bat wing tissues in order to compare the skin proteomes of species variably impacted by WNS, including those of two endangered species. Further tests are planned to investigate methods of increasing protein yield without altering the size of the tissue sample collected, as well as the analysis of mass spectrometry data from processed skin tissues of five bat species differentially affected by WNS.
ContributorsPatrose, Reena Paulene (Author) / Moore, Marianne (Thesis director) / Steele, Kelly (Committee member) / College of Integrative Sciences and Arts (Contributor) / Barrett, The Honors College (Contributor)
Created2018-05
Description
Phytohemagglutinin (PHA) is a plant lectin commonly used to stimulate and test responses of the immune system and is known to induce T cell proliferation, agglutinate human leukocytes, and yield adjustments in lymphocyte populations. What is not well know is how responses to PHA correlate with a host's ability to resist or recover from pathogen invasion. This study uses information from previously published studies to determine whether or not PHA can be a good indicator of disease severity or disease resistance in a host. With PHA having the abilities that it does, immune responses to PHA may correlate with responses important for pathogen resistance and clearance. Such a relationship could only be uncovered if in vivo or in vitro responses to PHA are measured and, independent from the PHA challenge, symptoms and/or mortality rates of hosts are documented after pathogen exposure. An in vitro response can be detected by measuring cellular proliferation in response to PHA followed by separate cell cultures exposed to a pathogen. While an in vivo response can be detected by measuring variation in swelling in response to an injection of PHA. In reviewing a broad range of articles that meet my criteria, the majority of articles failed to show a strong relationship between PHA and disease severity or disease resistance. Therefore, immunologists must consider the usefulness of the PHA tests as a measure of immunocompetence, which is a host's ability to predict response to a pathogen. According to the literature, using PHA does not predict responses to pathogen invasion. However, it is possible that with carefully designed experiments, it could be determined that PHA does provide an indication of pathogen resistance in certain host species exposed to specific pathogen.
ContributorsMackey, Tracy Michelle (Author) / Moore, Marianne (Thesis director) / Penton, Ryan (Committee member) / College of Integrative Sciences and Arts (Contributor) / Barrett, The Honors College (Contributor)
Created2017-05
Description
Sexually transmitted diseases like gonorrhea and chlamydia, standardly treated with antibiotics, produce over 1.2 million cases annually in the emergency department (Jenkins et al., 2013). To determine a need for antibiotics, hospital labs utilize bacterial cultures to isolate and identify possible pathogens. Unfortunately, this technique can take up to 72 hours, leading to several physicians presumptively treating patients based solely on history and physical presentation. With vague standards for diagnosis and a high percentage of asymptomatic carriers, several patients undergo two scenarios; over- or under-treatment. These two scenarios can lead to consequences like unnecessary exposure to antibiotics and development of secondary conditions (for example: pelvic inflammatory disease, infertility, etc.). This presents a need for a laboratory technique that can provide reliable results in an efficient matter. The viability of DNA-based chip targeted for C. trachomatis, N. gonorrhoeae, and other pathogens of interest were evaluated. The DNA-based chip presented several advantages as it can be easily integrated as a routine test given the process is already well-known, is customizable and able to target multiple pathogens within a single test and has the potential to return results within a few hours as opposed to days. As such, implementation of a DNA-based chip as a diagnostic tool is a timely and potentially impactful investigation.
ContributorsCharoenmins, Patherica (Author) / Penton, Christopher (Thesis director) / Moore, Marianne (Committee member) / College of Integrative Sciences and Arts (Contributor) / Barrett, The Honors College (Contributor)
Created2016-12
Description
Vitamin supplements have beneficial and adverse effects depending on the dosage given and the age and sex of the recipient. Vitamin supplements have been extremely profitable in the health industry, but there is limited scientific data supporting vitamin supplement benefits. Many studies over the last decade have shown that vitamin supplements provide few health benefits and can lead to adverse effects, such as abnormal bone growth, birth defects, or an increased risk of cancer. Some researchers state that people with a specific vitamin deficiency should take vitamin supplements because the supplement can alleviate this deficiency. Many healthy people take vitamin supplements to prevent disease or have better health, but some researchers argue this is a misconception. Most health organizations indicate that consuming vitamins should be through diet, not supplements. The value of dietary supplements, most of which are consumed in developed countries, has been a controversial topic, because the beneficial effects of taking vitamin supplements is hotly contested. Many experts in the field of nutritional physiology suggest that Americans adequately receive enough vitamins in their diet and do not need to take vitamin supplements. Researchers at John Hopkins announced that the United States should stop spending money on vitamin supplements. Their research has found no benefits to taking vitamin supplements, because most people in industrialized areas are well-nourished. In this study, I have gathered that vitamin supplements are not beneficial when one has a sufficiently nutrient-rich diet; whereas, one who has a vitamin deficient diet can benefit from taking vitamin supplements. Furthermore, I have gathered that people older than 65-years-old should take vitamin B12 because vitamin B12 levels decrease with age. There is not enough evidence to prove or disprove that vitamin supplements are generally beneficial. In fact, I gathered that vitamin supplements may even be harmful. I propose that further studies should be conducted to discover the truth about the possible benefits of vitamin supplementation for healthy individuals and among people with different health conditions, activity levels, and nutrient requirements.
ContributorsMcDowell, Alexandra Catherine Jo (Author) / Moore, Marianne (Thesis director) / Huffman, Holly (Committee member) / College of Integrative Sciences and Arts (Contributor) / Department of Management and Entrepreneurship (Contributor) / Barrett, The Honors College (Contributor)
Created2018-05
Description
Across large areas of eastern and midwestern North America, a severe reduction in multiple populations of bat species has been observed as the result of the emerging fungal disease, white-nose syndrome (WNS). WNS is caused by a psychrophilic (i.e. cold loving) fungus, Pseudogymnoascus destructans (Pd), that invades the skin of bats during hibernation. Recent studies have shown that during hibernation, bats have decreased immune system activity which would suggest increased susceptibility to infection. Antimicrobial peptides (AMPs) are an important component of the innate immune system and are expressed constitutively within all tissues that serve as barriers against infection. Killing pathogens at the level of the skin could prevent the need for more complex immune responses likely inhibited during hibernation, and therefore AMPs could be critical in combating infection by Pd and reducing population loss of susceptible bat species. In this investigation, the fungicidal activity of commercially available AMPs derived from the skin of multiple taxa, including amphibians, catfish, and humans were compared in order to study immunity at the level of the skin. Additionally, our aim was to create optimal methods for a low-cost antimicrobial-assay protocol that would provide quantitative results. We found that killing abilities at various concentrations of dermaseptin S-1 against Ca ATCC 10231 were consistent with literature values, while our values for magainin 2 and parasin 1 were far from the values previously recorded by other studies. It is possible that some differences can be accounted for by the difference in antimicrobial assay procedures, but our findings suggest potential differences to the well-known killing abilities of certain peptides nonetheless. Overall, the protocol established for the antimicrobial assays using serial dilutions and Sabouraud Dextrose plates was successful.
ContributorsFrazier, Eric (Co-author) / Lake, Alexis M. (Co-author) / Moore, Marianne (Thesis director) / Penton, Christopher (Committee member) / College of Integrative Sciences and Arts (Contributor) / Barrett, The Honors College (Contributor)
Created2018-05
Description
Across large areas of eastern and midwestern North America, a severe reduction in multiple populations of bat species has been observed as the result of the emerging fungal disease, white-nose syndrome (WNS). WNS is caused by a psychrophilic (i.e. cold loving) fungus, Pseudogymnoascus destructans (Pd), that invades the skin of bats during hibernation. Recent studies have shown that during hibernation, bats have decreased immune system activity which would suggest increased susceptibility to infection. Antimicrobial peptides (AMPs) are an important component of the innate immune system and are expressed constitutively within all tissues that serve as barriers against infection. Killing pathogens at the level of the skin could prevent the need for more complex immune responses likely inhibited during hibernation, and therefore AMPs could be critical in combating infection by Pd and reducing population loss of susceptible bat species. In this investigation, the fungicidal activity of commercially available AMPs derived from the skin of multiple taxa, including amphibians, catfish, and humans were compared in order to study immunity at the level of the skin. Additionally, our aim was to create optimal methods for a low-cost antimicrobial-assay protocol that would provide quantitative results. We found that killing abilities at various concentrations of dermaseptin S-1 against Ca ATCC 10231 were consistent with literature values, while our values for magainin 2 and parasin 1 were far from the values previously recorded by other studies. It is possible that some differences can be accounted for by the difference in antimicrobial assay procedures, but our findings suggest potential differences to the well-known killing abilities of certain peptides nonetheless. Overall, the protocol established for the antimicrobial assays using serial dilutions and Sabouraud Dextrose plates was successful.
ContributorsLake, Alexis (Co-author) / Frazier, Eric (Co-author) / Moore, Marianne (Thesis director) / Penton, Christopher (Committee member) / W.P. Carey School of Business (Contributor) / College of Integrative Sciences and Arts (Contributor) / Barrett, The Honors College (Contributor)
Created2018-05
Description
Nutrition has been around for as long as human beings have resided on the planet, giving it one of the most impactful roles in history, particularly in medicine. Certain herbs or dietary restrictions could help individuals recover from illnesses—this form of healing has been passed down generations, which medical providers from all over the world take advantage of. Before the era of antibiotics and pharmaceutical companies, food was the medicine used to treat. As civilization has flourished and become progressive, it seems that certain qualities of the past have been forgotten, such as the power of diet. Medical providers like to push patients towards pharmaceutical intervention because of the financial profit that this method entails, which has been shown to backfire. These interventions are not solving the true problem, but only applying a short-term solution. Dietary restrictions as well as the increase in heart-healthy foods can entirely reverse these conditions in order to avoid the fatal effects they may have. With the increase in nutritional education amongst the population via medical providers, specifically primary care providers, patients are able to reverse the symptoms of effects of chronic cardiovascular disease amongst others.
ContributorsTarin, Marjan (Author) / Huffman, Holly (Thesis director) / Moore, Marianne (Committee member) / College of Integrative Sciences and Arts (Contributor) / Barrett, The Honors College (Contributor)
Created2018-12
A Review of the Current Understanding on Immune Cell Sensitivity to Variation in Energy Availability
Description
This study takes a broad look into the existing research on the relationship between two physiological topics, nutrition and immunity in vertebrates, specifically the mammalian and avian branches. This was achieved by critiquing available studies on different types of immune cells, and how variable energy availability, as well as specific pathogens, impact cell function. Notably, most studies examined individuals with compromised immune systems, which reveals an existing knowledge gap in the linkages between nutrition and immunity in healthy organisms. Links between immunity and nutrition were identified across the studies, with the three main energy molecules, carbohydrates, lipids, and proteins, implicated in functional roles as immune modulators. Stimulatory and inhibitory effects occur dependent on elevated and depleted nutrient levels, and multiple cell types are sensitive to changes in nutrient availability. Further studies should be conducted on healthy individuals of model species, as well as wildlife and other non-model species to identify and describe the effects of host nutritional status on the spread of pathogens and the implications at the population level for humans, domestic animals, and wildlife.
ContributorsViteri, Xela Amariana (Author) / Moore, Marianne (Thesis director) / Penton, Christopher (Committee member) / College of Integrative Sciences and Arts (Contributor) / Barrett, The Honors College (Contributor)
Created2017-12
Description
White-nose syndrome (WNS) is a cutaneous fungal infection caused by Pseudogymnoascus destructans (Pd) which was first observed in the United States in 2006. Pd infects bats during hibernation and leads to the development of cutaneous lesions and behavioral changes that can result in the animal's death. This study generated the first complete bat skin proteome for the WNS resistant gray bat (Myotis grisescens) to optimize sample preparation methods and identify immune proteins that may signal resistance. Wing tissue was collected from a female gray bat and processed in a Barocycler using 4M or 8M urea followed by an in-gel trypsin digestion of pooled samples and processing of separate samples without digestion specifically to capture and identify small antimicrobial peptides. Both undigested and digested samples were analyzed using a Thermo Fisher LTQ Orbitrap Velos mass spectrometer and interpreted using PEAKS software. A total of 29 immune proteins were identified including the antimicrobial peptide dermcidin. This method will be applied to a larger range of samples from five species variably impacted by WNS to compare skin proteomes with the aim of identifying immune proteins that are responsible for resistance at the barrier where Pd invades.
ContributorsBoone, Brianna Marie (Author) / Moore, Marianne (Thesis director) / Steele, Kelly (Committee member) / College of Integrative Sciences and Arts (Contributor) / Department of Psychology (Contributor) / Barrett, The Honors College (Contributor)
Created2017-05