Theses and Dissertations from UMD

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New submissions to the thesis/dissertation collections are added automatically as they are received from the Graduate School. Currently, the Graduate School deposits all theses and dissertations from a given semester after the official graduation date. This means that there may be up to a 4 month delay in the appearance of a give thesis/dissertation in DRUM

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    Mechanisms by which the actin cytoskeleton switches B cell receptor signaling from the activation to the attenuation mode
    (2022) Bhanja, Anshuman; Song, Wenxia; Cell Biology & Molecular Genetics; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    The B cell-mediated humoral immune response is critical in fighting off invading pathogens and potentially harmful foreign substances. B cells detect antigens through the B cell receptor (BCR). The binding of cognate antigen to the BCR induces a signaling response, a critical initiation and regulatory step for B cell activation and differentiation. The actin cytoskeleton has been shown to play essential roles in BCR signaling. When encountering membrane-associated antigens, actin amplifies signaling by driving B cell spreading and BCR clustering, while promoting signal attenuation by causing B cell contraction. This signal attenuation is essential for curtailing the activation of autoreactive B cells. However, the mechanism by which the actin cytoskeleton switches BCR signaling from amplification to attenuation was unknown. My thesis research examined the mechanisms by which actin reorganization transitions B cells from spreading to contracting and B cell contraction switches BCR signaling from amplification to attenuation, using mouse splenic B cells, a functionalized planar lipid bilayer system, and total internal reflection fluorescence microscopy. Our results show that branched actin polymerized by Arp2/3 is required for B cell transition from spreading to contraction after driving B cell spreading. Ubiquitously expressed Neuronal Wiskott-Aldrich Syndrome Protein (N-WASP), but not the haematopoietically specific WASP, activates the branched actin polymerization and generates inner actin foci from lamellipodial actin networks, by sustaining their lifetime and centripetal movement. N-WASP-dependent inner actin foci are necessary for recruiting non-muscle myosin II, creating an actomyosin ring-like structure at the periphery of the membrane contact region to drive B cell contraction. B cell contraction primarily increases the BCR molecular density in individual BCR-antigen clusters, measured by the peak fluorescence intensity. Inhibition of B cell contraction by Arp2/3 inhibitor and B cell-specific N-WASP knockout (cNKO) reduced the increasing rates of BCR molecular density. Increased molecular density caused by B cell contraction leads to decreases in the levels of phosphorylated BCR, the stimulatory kinase Syk, the inhibitory phosphatase SHIP-1, and their phosphorylated forms in individual BCR clusters. However, the levels of total Syk and SHIP-1 have a different relationship with BCR density in individual clusters: Syk does not decrease until a high threshold of BCR density, which can be achieved only by contracting B cells, but SHIP-1 consistently reduces with the increase in BCR molecular density. Inhibiting B cell contraction by cNKO reduces the molecular density of BCR clusters but does not affect the relationship of the Syk and SHIP-1 levels with BCR molecular density in clusters. Taken together, our results suggest that the actin cytoskeleton reorganizes from the lamellipodial branched actin networks to centripetally moving actin foci, enabling actomyosin ring-like structure formation, through N-WASP-activated Arp2/3. Actomyosin-mediated B cell contraction attenuates BCR signaling by increasing receptor molecular density in individual BCR clusters, which causes the dissociation of both stimulatory and inhibitory signaling molecules. My thesis research results reveal a novel negative regulatory mechanism for BCR signaling, an essential checkpoint for generating pathogen-specific and suppressing self-reactive antibody responses.
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    HIGH-RESOLUTION ANALYSIS OF HIV ENVELOPE-SPECIFIC ANTIBODY RESPONSES TO ACCELERATE RATIONAL IMMUNOGEN DESIGN
    (2020) Lei, Lin; Li, Yuxing; Cell Biology & Molecular Genetics; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    The recent isolation of HIV broadly neutralizing antibodies (bNAbs) from HIV infected individuals has reinvigorated efforts to develop B cell-based vaccines. As the sole viral target for bNAbs, HIV envelope glycoprotein (Env) has been engineered as soluble trimers to recapitulate bNAbs responses via vaccination. However, Env-based immunogens thus far primarily induce vaccine-matched neutralizing antibody (nAb) responses. This thesis aims to understand the mechanisms restricting the neutralization breadth and to provide strategies for iterative improvements. First, we have established an antigen-specific single B cell sorting and monoclonal antibody (mAb) cloning platform for guinea pigs, a small animal model desirable in the field for initial immunogenicity analysis. This method allowed us to dissect the antibody responses at the clonal level with high accuracy and efficiency. Secondly, we have delineated the specificity of autologous neutralization elicited by the current generation HIV trimer mimicry, BG505 SOSIP.664. Our results reveal a prominent epitope in the C3/V4 region of the Env targeted by one nAb/B cell clonal lineage. We demonstrate that the nAb responses to this neutralization determinant are prevalent in trimer-vaccinated guinea pigs, rabbits, and non-human primates. In addition, this defined nAb response shares a high degree of similarity with the early nAb response in an HIV- infected pediatric patient, who later developed a bNAb response. This study offers insights into re-designing Env immunogens in the highly immunogenic region to broaden nAb responses. Lastly, we have engineered novel immunogens based on the Env sequence of a virus strain isolated from bNAb VRC01 donor, which can engage the VRC01 germline precursor in vitro. Sequential prime-boost immunizations in a VRC01-germline immunoglobulin (Ig) encoding genes knock-in mouse model with the designed immunogens induced focused VRC01-like serum antibody responses and clustered VRC01-class somatic mutations in the knock-in VRC01-germline Ig genes. In addition, the mAbs recovered from the immunized mice neutralize selected viruses containing the N276 glycan, a critical roadblock impeding the affinity maturation of VRC01-class bNAbs. Our findings demonstrate that, in the transgenic mouse model, our immunogens effectively activate bNAb precursor B cells and guide their affinity maturations required for bNAb function, which has important implications for HIV vaccine development.
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    The regulation of B cell activation by membrane damage and antigen density
    (2015) Miller, Heather; Song, Wenxia; Cell Biology & Molecular Genetics; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    Antibodies generated by B cells neutralize pathogens and pathogen-secreted toxins and flag them for immune clearance. Antibody responses are initiated via binding of cognate antigen to B-cell receptors (BCR). This induces BCR aggregation in lipid rafts, promoting BCR signaling and internalization of antigen for processing and presentation to T helper cells, which is essential for generating high affinity and long-lasting antibody responses. The ability of an immunogen to activate BCR signaling and internalization is necessary for efficient vaccines. To capture these immunogens, B cells circulate and migrate through blood and lymphoid tissues. During circulation, the plasma membrane of B cells may be damaged by mechanical forces and membrane-perforating toxins. The impact of plasma membrane damage on B-cell activation is unknown. The first part of this thesis investigated the mechanism of plasma membrane repair in B cells and the effects of repair on BCR activation. My research reveals that B cells rapidly repair membrane wounds provoked by streptolysin O, a pore forming bacterial toxin. Similar to the mechanism reported for fibroblasts and muscle cells, B cells repair by Ca2+ triggered lysosome exocytosis, which releases acid sphingomyelinase (ASM) to the plasma membrane to induce endocytosis of damaged membrane. Different from previous reports, ASM induces direct endocytosis of lipid rafts in the absence of the membrane invaginating lipid raft protein, caveolin. Importantly, it was discovered that BCR activation interferes with plasma membrane repair, while wounding inhibits BCR signaling and internalization by segregating BCRs from lipid rafts. These data suggest that plasma membrane repair and B cell activation interfere with one another due to competition for lipid rafts. The second part of my thesis established and characterized a membrane-bound antigen system where all antigenic molecules are optimally oriented for BCR binding. Using the new system, we investigated the role of the density and valency of membrane-bound antigen on BCR activation. The results show that increases in the density but not valency of antigen on membranes significantly enhance the magnitudes of the early events of BCR activation, including BCR self-clustering, cell spreading on antigen-presenting surface, and protein tyrosine phosphorylation. The enhanced signaling is correlated with greater actin dynamics required for BCR aggregation, B-cell spreading and signaling. These results indicate that this model antigen will benefit quantitative studies of the molecular mechanisms underlying BCR activation, and also suggest that manipulations of molecular configuration and density can be applied to enhance the immunogenicity of vaccines.
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    REGULATORY FUNCTIONS OF THE ACTIN CYTOSKELETON IN B CELL RECEPTOR SIGNALING
    (2013) Liu, Chaohong; Song, Wenxia; Cell Biology & Molecular Genetics; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    The binding of antigen (Ag) to the B cell receptor (BCR) induces the activation of intracellular signaling and the reorganization of the actin cytoskeleton. However, the function of actin reorganization and the mechanisms by which BCR signaling and actin reorganization is coupled have not been well studied. This thesis has investigated how BCR signaling regulates actin reorganization and how actin remodeling in turn influences BCR signalig. My studies show that the key stimulatory signaling molecule of the BCR, Bruton's tyrosine kinase (Btk), is critical for actin polymerization at the activation surface and BCR clustering and B cell spreading, events that are essential for signaling initiation and amplification. The key inhibitory signaling molecule, SH2-containing phosphatidylinositol-5 phasphatase (SHIP-1), is important for removal of F-actin from the activation surface, and actin-mediated B cell contraction and the formation of BCR central clusters. SHIP-1 suppresses actin polymerization by inhibiting Btk-dependent activation of Wiskott-Aldrich syndrome protein (WASP). These results suggest that BCR signaling can regulate B cell morphology and surface BCR clustering via modulationg actin dynamics. To understand the roles of actin reorganization in BCR signaling, I investigated the effects of gene knockout of the two actin regulators, WASP and its homolog, neuronal (N)-WASP. My results show that both WASP and N-WASP are required for optimal BCR clustering, B cell spreading, and BCR signaling, but they play distinct roles. WASP promotes actin polymerization, B cell spreading, BCR clustering, and signaling amplification, and N-WASP inhibits actin polymerization at the activation surface and promotes B cell contraction, BCR central cluster formation, and signaling attenuation. Importantly, B cell-specific N-WASP knockout causes increases in the levels of autoantibody. In addition, WASP and N-WASP negatively regulate each other, compete for Arp2/3, and are inversely regulated by Btk and SHIP-1. Taken together, these results demonstrate that the balance of stimulatory and inhibitory BCR signaling controls actin dynamics and organization through regulating the activities of WASP and N-WASP. Actin remodeling in turn amplifies BCR signaling activation or down regulation by modulating B cell morphlogy and the organization of surface BCRs.This research reveals a bidrectional feedback loop between BCR signaling and the actin cytoskeleton.