Life Sciences

Colton Smith, Dixie State University

Kayleigh Ingersoll, Brigham Young University

Weston Elison, Brigham Young University

Tason Turek, Dixie State University

Somer Doody, Utah Valley University

Kaden Jordan, Dixie State University

Trevor Lloyd; Mason Poffenbarger; Austin Ricks; Andrew Barlow; Zoey Fishburn, Brigham Young University

Lydia Morley, University of Utah

Joshua Wilkerson; Seung-Ook Yang; Parker J. Funk; Steven K. Stanley, Brigham Young University

Tegan Parks, Utah Valley University

Alyson DeNittis, Utah Valley University

Diabetes affects over 30 million Americans and 185,000 Utahn’s. Type 1 and Type 2 diabetes are characterized by decreased functional β-cell mass and insulin production. Diabetes also results in increased circulating glucose and fatty acid levels, which damage and destroy β-cells over time. Our study will shed further light on the effects of palmitate, the most commonly made fatty acid in the liver, on hyperlipidemia. In this study we test the specific effects of chronic palmitate exposure on various cell lines acclimated to 0.15 mM, 0.3 mM, and 0.5 mM concentrations of palmitate. We demonstrate the effects of progressive long-term exposure to palmitate on β-cell proliferation and resistance to apoptosis. We demonstrate mechanistic changes that result in the observed phenotypes. Our goal in this study is to explore how β-cells adapt to exposure to hyperlipidemia, and to define interventions to protect β-cells from the harmful effects of hyperlipidemia.

Parker Booren, Nathanael Jensen, Talon Aitken, Samuel Grover, Jackie Crabree, Brigham Young University Diabetes continues to grow at a rapid rate, affecting the lives of both young and old. Both Type 1 and Type 2 diabetes lead to eventual ë_ cell depletion (and subsequent decrease in insulin secretion). This can be treated through ë_ cell transplantation from the pancreata of cadavers. Currently, collecting sufficient ë_ cells for one diabetic patient requires pancreata from multiple cadavers. If proliferation can be induced in a donor’s aged ë_ cells, transplantation would become more effective as one donor now becomes sufficient to serve one or two patients. Nkx6.1 is a transcription factor that increases insulin secretion and induces proliferation of young rat ë_ cells (5 weeks) through the upregulation of its target genes: VGF, Nr4a1 and Nr4a3. Aged rat ë_ cells (5+ months) fail to proliferate after overexpression of Nkx6.1. We have also shown that upregulation of Nkx6.1’s target genes is disrupted in these aged ë_ cells. This may be due to changes in expression of a binding partner necessary for Nkx6.1’s upregulation of these target genes or to changes in Nkx6.1 posttranslational modifications that impede binding partner interactions in aged ë_ cells. We present data from co-immunoprecipitation and mass spectrometry experiments that reveal the presence or absence of Nkx6.1’s binding partner in young and aged ë_ cells. Furthermore, we present mass spectrometry results of Nkx6.1 posttranslational modification from young and old ë_ cells. This data will increase understanding on the ability of Nkx6.1 to upregulate its target genes in an aged ë_ cell.

Nayla Rhein, Southern Utah University

Stephen Smith, Southern Utah University

Gemma Clark, University of Utah

Dominique Pablito, University of Utah

Bess Bauer, Weber State University

Jacob Delano, Utah Valley University

Jess Breda; William Kristan; Kathleen French, Westminster College

Maile Marriott; Laura Lupi, University of Utah

Sophie Overbeck, Weber State University

David Coffman; Carson Cole, Weber State University

Charlotte Brickwood-Figgins, University of Utah

Mariah Richins; Jefferson Last, Dixie State University

Ireland Green, Weber State University

Michael Lange; Don Rodriguez; Elijah Bingham, Brigham Young University

Paola Garrison-Tovar; Jazmine James; Denton Shepherd, Southern Utah University

Karaleen Anderson; Mariel Hatch; Caeleb Harris; Karina Bravo; Rawly Lyle; Tyson Hill, Utah Valley University

Nadja Redd; Gloria Slattum; Jody Rosenblatt; Franco Jin, University of Utah

Mark Albrecht; Brock Orme; Mary Jo Tufte, Southern Utah University

Grace Hoffmann; Monika Lakk, University of Utah

Tyler Johnson, Utah Valley University

Karaleen Anderson; Li Szhen Teh; Mariel Hatch; Caeleb Harris; Hannah; Stephanie Pare, Utah Valley University

Jordan Parker, Southern Utah University

Matt Austin, Brooke Smyth, Lauren Manwaring, Moroni Lopez, Brigham Young University Type 2 diabetes is characterized by the inability of pancreatic ë_-cells, which secrete insulin, to regulate blood glucose levels. The glucose-regulating mechanisms of these dysfunctional ë_-cells exhibit a gradual insensitivity to insulin, caused by prolonged hyperglycemia. Treatment for individuals suffering from Type 2 diabetes is limited to supplementary insulin injections. However, recent studies have revealed that powerful anti-oxidants called flavanols, which are found in cocoa, affect insulin secretion and glucose tolerance of ë_-cells. We isolated three fractions from the whole cocoa extract: monomeric catechin-rich, oligomeric procyandin-rich and polymeric procyandin-rich flavanols. Because cellular respiration is closely related to insulin secretion, we hypothesize that these fractions may exert their anti-diabetic effects by enhancing cellular respiration. To determine the effects of cocoa flavanols on ë_-cell respiration, we performed respiration assays on INS-1 ë_-cell lines incubated with increasing concentrations of whole cocoa extract, monomeric, polymeric and oligomeric catechin fractions or a control. We present data demonstrating the effect of these compounds on ë_-cell respiration. Advancements based on our research could provide an innovative therapeutic alternative to current diabetes treatment and new insight into the respiratory pathways of ë_-cells, affording new targets for a multitude of potential gene therapies.

Sydney Cahoon, University of Utah

Kirk Harter; Spencer Drennan; Liza Jarman; Weon Kim; Gregory Boatwright, Brigham Young University

Diana Villicana; Kaitlin Veylupek, Southern Utah University

Christian Kodele, Lian Li, Jane Yang, University of Utah Non-Hodgkin lymphoma (NHL) is an immune disease mostly of B-cell origin (eighty-five percent of the time) as well as the ninth leading cause of cancer death in the United States. Although treatments for NHLs greatly improved following the FDA approval of Rituximab (RTX), refractive malignancies still occur that are nonresponsive and/or resistance to current therapies in at least a third of all patients. This has been attributed both to the inability of immune effector cells (eg., macrophages, natural killer cells) to hypercrosslink ligated monoclonal antibodies (mAbs), and to Fc receptor (FcR)-mediated endocytosis or ‰ÛÏtrogocytosis‰Û of CD20 antigens. In order to address these clinical obstacles, we designed a novel paradigm in macromolecular therapeutics that can specifically kill cancer cells without a drug. This paradigm is based on the use of anti-CD20 Fab’ fragments in a multivalent system. Crosslinking of CD20 receptors leads to receptor clustering, transfer to lipid rafts, opening of a calcium channel, and ultimately apoptosis. Additionally, the removal of the Fc fragment resulted enticingly in both the rendering of the system to be immune dependent and in decreasing the numerous adverse effects. In this study, we have used human serum albumin (HSA) as the multivalent carrier of RTX based Fab’ fragments. We have covalently attached multiple Fab’ fragments to HSA, characterized the nanoconjugate’s physiochemical properties, and evaluated its efficacy to induce apoptosis of Raji B cells in vitro. The efficacy of the nanoconjugate to induce apoptosis was determined with Annexin V assay and flow cytometry. The interaction of the nanoconstruct with Raji cells was characterized using confocal microscopy of Cy5 labeled conjugates. As predicted, the HSA-(Fab’)x conjugate was able to induce cell death in vitro. The results of the Annexin V apoptosis assay showed that 38.9 percent of the cell population treated with the conjugate became apoptotic, while 13.6 and 15.7 percent of the cell populations untreated and treated with whole RTX mAb became apoptotic respectively. Furthermore, images recorded by use of confocal microscopy suggest that the attachment of HSA-(Fab’)x conjugate to the cell membrane is CD20 specific. While not conclusive, the combination of these results suggest that the mechanism of action involves cross-linking of the CD20 receptor, which subsequently induces apoptosis. We believe these results warrant further investigation of the mechanism of action of HSA-(Fab’)x, as well as the treatment potential of this nanoconjugate.

Chloe Jensen; Thomas Jarman, Brigham Young University

John Hancock; Benjamin Bickman; Kyle Kener; Kevin Garland; Claudia M Tellez Freitas; Scott Weber; Chad Hancock, Brigham Young University

Karaleen Anderson, Mariel Hatch, Caeleb Harris, Anastasiia Matkovska, Kendrick Kiggins, Levi Neely, Utah Valley University Mucormycosis is a life-threatening disease that occurs in immunocompromised individuals, such as burn, cancer and diabetic patients. Amphotericin B is the current line of treatment for the disease, however it is known to have many adverse side effects including cell toxicity. Due to the high mortality and morbidity associated with the disease even when treated with Amphotericin B, it is vital that new combination therapeutic techniques be investigated in order to more effectively treat the disease. Mucromycosis is most often caused by a filamentous, opportunistic fungi called Rhizopus oryzae. This species causes up to 80% of infections and is the most common species isolated from confirmed Mucormycosis sites. Origanum vulgare (oregano) oil has been shown to have broad anti-microbial properties in various studies. This study investigates the ability of oregano oil to lower the concentration of Amphotericin B needed to successfully inhibit R. oryzae biofilms. Various concentrations of oregano oil and Amphotericin B are tested to determine the optimal concentration ratio that maximizes biofilm inhibition. Synergistic activity of oregano oil and Amp B could be used to decrease the amount of Amphotericin B needed to treat Mucormycosis infections while still utilizing the antifungal properties of Oregano oil.

Erin Kinnally; Jefferson Hunter; John Capitanio; Erika Jones; Elizabeth Wood, Brigham Young University

Mason Smith, Southern Utah University

Li Szhen Teh; Preston Larsen; Ian Sudbury; McKay Christensen; Ranae Zauner, Utah Valley University

Angel Guerra; Curtis Hoffmann, Utah Valley University

Agueda Rodriguez; Michael Hope, Southern Utah University

Kyson McBride, Southern Utah University

Hal Jones, Brigham Young University