Browsing by Subject "Biological Phenomena, Cell Phenomena, and Immunity"
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Item 17 Beta-Estradiol, Integrins, and Synaptic Proteins(2009-05-01) Chandra, Manjari; Simpkins, James W.Item Aging of the Thymic Epithelial Progenitor Pool is Determined by the p63-FoxN1 Regulatory Axis(2015-05-01) Burnley, Preston I.; Dong-Ming SuThe immune system is composed of various effector cells and molecules that must work in concert in order to protect the body against infections, auto-reaction, and tumor occurrence. These responses can be divided into two categories – innate and adaptive immunity. The innate response is the host’s first line of defense towards a pathogen by providing a physical and chemical barrier against infection. Once activated, innate cells such as macrophages and dendritic cells can engulf the bacterium, degrade it, and secrete proteins to destroy the pathogen. Although this response occurs immediately after an encounter with a pathogen, the innate immunity is neither long-lasting nor specific. In contrast, the adaptive immune response is initiated when the innate immune response is unsuccessful in eliminating the infection, allowing for recognition and response tailored for a particular pathogen. The cells that make up the adaptive response all originate from a common lymphoid progenitor found in the bone marrow. From this precursor arise natural killer (NK) cells (part of the innate response) and T and B lymphocytes. The T lymphocytes originate from the bone marrow but undergo development in the thymus, hence the name T cells. B lymphocytes, on the other hand, originate and develop in the bone marrow. With the exception of NK cells, these adaptive immune cells require antigen presentation in order to become activated. Once the T and B cells have matured and become activated they can work together to clear the infection by secreting cytokines and antibodies. The most important aspect of the adaptive immune response is its ability to produce immunological memory. Memory T and B cells are able to ensure a rapid and effective response to a second encounter, providing long-last immunity. Unfortunately, this well-ordered process, specifically the development of T cells, becomes compromised during aging. This is due to the fact that thymic involution (or shrinking of the thymus) occurs at the onset of puberty and continues throughout the lifespan, which is primarily resulted from age-related defect in thymic epithelial cells (TECs). The thymus is crucial for the generation of T cells so any compromise to the organ results in changes in the T cells, which can possibly lead to immune insufficiency and autoimmunity [1]. Additionally, these conditions are exacerbated with age [2, 3]. This research project will focus on the molecular mechanism(s) responsible for thymic involution. To do so, we focused on TECS and two genes associated with the homeostatic maintenance of the thymic microenvironment, p63 and FoxN1. These genes regulate the proliferation and differentiation, respectively, of thymic epithelial cells (TECs), thereby maintaining a properly functioning thymus. For this study we will utilize our mouse model (FoxN1 conditional knockout, FC) extensively because it mimics an aged thymus. This model allows us to study the thymic microenvironment of a mouse with a defect in the FoxN1 gene.Item Intercellular Nef transfer and HIV-1 infection of astrocytes(2015-05-01) Luo, Xiaoyu; He, Johnny J.; Ghorpade, Anuja; Wordinger, Robert J.Acquired immune deficiency syndrome (AIDS) is a pandemic caused by human immunodeficiency virus type 1 (HIV-1). It is a major health issue in many parts of the world ever since its discovery in 1981. The most devastating effect of HIV-1 infection is the graduate loss of CD4+ T cells, which eventually leads to the dysfunction of the immune system, susceptibility to opportunistic infections and cancer. HIV-1 Nef protein is long known as an essential pathogenic factor for HIV-1/AIDS pathogenesis. A few recent studies including ours have demonstrated that Nef can be transferred to neighboring cells and alters the function of these cells. However, the underlying mechanism of intercellular Nef transfer is in dispute. In the first part of our study, we characterized two potential underlying mechanisms for intercellular Nef transfer: direct cell-cell contact and exosomes using several complementary strategies and a panel of exosomal markers. First, we showed that Nef was transferred from Nef-expressing or HIV-infected CD4+ T lymphocytes to CD4+ T lymphocytes and astrocytes, and that the transfer was mainly associated with tunneling nanotube formation. Then we determined that Nef enhanced virological synapse formation and induced cytoskeleton re-arrangement and cell surface protrusions, suggesting that Nef promotes the establishment of intercellular connection and communication between infected cells and uninfected cells. Thirdly, we examined the possibility of Nef transfer through exosomes. In the exosome uptake assay, Nef transfer was undetectable while exosome marker CD81 transferred rapidly. In contrast, Nef was detected in crude exosomes collected from Nef-transfected 293T. In addition, two different populations of exosomes were successfully separated by OptiPrep gradient fractionation and determined as AChE+/CD81low/TSG101low exosomes and AChE- /CD81high/TSG101high exosomes. We determined that Nef was selectively secreted into the AChE+/CD81low/TSG101low population. Lastly, microscopic imaging showed no significant Nef detection in exosomal vesicle-like structures in and out the cell. Taken together, this study shows that Nef transfer requires direct cell-cell contact such as tunneling nanotubes, not cell-free exosomes. In addition, this study reveals existence of two types of exosomes: AChE+/CD81low/TSG101low exosomes and AChE/CD81high/TSG101high exosomes. In the second part, we characterized HIV-1 infection of astrocytes. Astrocytes are the most abundant cells in the central nervous system (CNS) and play important roles in HIV-1/neuroAIDS. Detection of HIV-1 proviral DNA, RNA and early gene products but not late structural gene products in astrocytes in vivo and in vitro indicates that astrocytes are susceptible to HIV-1 infection albeit in a restricted manner. We, as well as others have shown that cell-free HIV-1 is capable of entering CD4- astrocytes through human mannose receptor-mediated endocytosis. In this study, we took advantage of several newly developed fluorescence protein-based HIV-1 reporter viruses and further characterized HIV-1 interaction with astrocytes. First, we found that HIV-1 was successfully transferred to astrocytes from HIV-infected CD4+ T cells in a cell-cell contact- and gp120-dependent manner. In addition, we demonstrated that compared to endocytosis-mediated cell-free HIV-1 entry and subsequent degradation of endocytosed virions, cell-cell contact between astrocytes and HIV-infected CD4+ T cells led to robust HIV-1 infection of astrocytes but retained the restricted nature of viral gene expression. Furthermore, we showed that HIV-1 latency was established in astrocytes. Lastly, we demonstrated that infectious progeny HIV-1 was readily recovered from latently infected astrocytes in a cell-cell contact-mediated manner. Taken together, our studies point to the importance of the cell-cell contact-mediated HIV-1 interaction with astrocytes and provide direct evidence to support the notion that astrocytes are HIV-1 latent reservoirs in the CNS.Item MIEN1 Drives Breast Cancer Invasion by Regulating Cytoskeletal-Focal Adhesions Dynamics(2015-05-01) Kpetemey, Marilyne F.; Vishwanatha, Jamboor K.; Clark, Abbot F.; Basu, AlakanandaIn the recent years, Migration and Invasion Enhancer 1(MIEN1) has emerged as a potential biomarker and a plausible target in breast cancer. Located in the 17q12-21 region of the human chromosome, next to the Her-2/neu loci, MIEN1 presents a robust expression in breast carcinomas; however is completely absent or low in the normal tissues. MIEN1 is post-translationally modified by geranyl-geranyl transferase-I (GgtaseI), which adds isoprenyl group to the carboxyl-terminal of the protein. Prenylated MIEN1 then associates with the inner leaflet of the plasma membrane and acts as an adaptor protein triggering downstream signaling through the Akt/NF-kB axis to regulate the expression of key proteases and angiogenic factors like MMP-9, uPA and VEGF. In migrating cells, MIEN1 enhances filopodium formation at the leading edge. Aside from its prenylation and redox-active motifs, MIEN1 also contains a canonical ITAM, reported to be associated with epithelial-to-mesenchymal transition. Although the role MIEN1 in cell migration and invasion is well known, the underlying molecular mechanisms remain elusive. Here, we show that MIEN1 interacts with Annexin A2, a cytoskeletal protein and a regulator of the plasminogen/plasmin system in breast cancer cells to increase migration and invasion. We confirmed that MIEN1 regulates actin dynamics by associating with cytoskeletal effectors in the lamellum. We also show that MIEN1 expression redirects breast tumor cell migration toward a collective migration. Our studies validate MIEN1-ITAM and CAAX as key motifs to MIEN1-induced functions. In conclusion, our findings confirm the role of MIEN1 in the remodeling of the actin cytoskeleton during motility. Furthermore it attests to previous findings suggesting that motility patterns depend on various environmental factors along with regulatory genes involved. Our study demonstrates an interesting example from cell biology where adaptor proteins regulate various signaling pathways and control cellular processes through protein-protein interactions.Item Synergy 2011: Annual Research Report(2011-01-01)Item The Effect of Lymphatic Pump Treatment on Anti-Tumor Immune Responses(2011-05-01) McCauley, Lyndsey R.; Hodge, Lisa M.The lymphatic system’s significance in maintaining health has been focused on by the osteopathic medical profession for years. Osteopathic manipulative treatments (OMT), specifically lymphatic pump techniques (LPT), aim at increasing lymphatic circulation and improving the clearance of interstitial fluid, inflammatory agents, and protein from the interstitial space. However, certain osteopathic manipulative techniques, such as LPT, are contraindicated in the presence of cancer with metastatic potential because it is thought that by accelerating the flow of lymph through the lymphatic vessels, tumor cells may metastasize throughout the body via the lymphatics. However, this theory lacks scientific proof. Studies previously conducted by our lab show that LPT increases thoracic duct lymph flow and leukocyte numbers in the rat and significantly decreases solid tumor formation and increases leukocyte concentrations in the lungs of rats with tumors (unpublished data). It is possible that increased lymph flow along with an increased number of circulating leukocytes can improve immune surveillance, providing recognition of and protection against pathogens and disease. Therefore, we hypothesized that administration of LPT would enhance anti-tumor immune responses in the lungs of rats with pulmonary tumors. In order to test this hypothesis, this thesis focused on one specific aim: to determine if LPT enhances leukocyte activation and/or function, thereby enhancing anti-tumor activities, such as tumor lysis and cytokine secretion.Item Turner, James, Ph.D.(1994-04-06) Turner, James; Hailey, BlakeDr. Turner, Professor and Chairman of the Anatomy & Cell Biology Department, recounts his work in eye disease research and his plans for future research. Interviewed by Blake Hailey, April 6, 1994