School of Medicine: Recent submissions
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Response Gene to Complement-32 Expression is Upregulated in Lupus T cells and Promotes IL-17A ExpressionBackground/Purpose: RGC (Response Gene to Complement)-32 is a cell cycle regulator expressed in normal tissues, tumors and a variety of cell lines. RGC-32 plays a role in a variety of pathological processes such as carcinogenesis, metabolic disorders, angiogenesis, atherosclerosis, and autoimmunity. We have shown that RGC-32 exerts a proinflammatory role by promoting Th17 responses in vitro and enhances Th-17 mediated autoimmune diseases in vivo. Th17 pathway has been linked to human lupus including lupus glomerulonephritis (GN). We have shown that in an immune complex mediated model of glomerulonephritis, RGC-32 promoted the Th17 and Th1 dependent proinflammatory responses and the organ specific pathways of renal fibrosis. The expression of RGC-32 in human PBMC and whether RGC-32 plays a role in the Th17 differentiation pathway and in Th17 abnormalities in lupus patients has not yet been investigated. Methods: RGC-32 mRNA expression was first assessed with the BD Biosciences Clontech Autoimmune Disease Profiling Array spotted with cDNA from CD3+, CD19+ and CD14+ cells from 11 lupus patients and 12 controls. PBMC were obtained from 20 patients with lupus and 18 controls. RGC-32 mRNA expression was determined by RT-PCR in purified CD4+ T cells from healthy controls, stimulated under Th0, Th1, Th2, Th17 and Treg conditions. The effect of RGC-32 overexpression and silencing under Th17 conditions was determined by nucleofection. RGC-32 expression in T cells from patients and controls was evaluated by RTPCR, western blot and flow cytometry. Results: Using the Autoimmune Disease Profiling Array, mRNA expression of RGC-32 in healthy controls was highest in CD3+, followed by CD14+ and CD19+ cells. By western blot, RGC-32 protein was constitutively expressed in T cell lysates from normal controls at baseline and upregulated upon TCR stimulation. By intracellular staining RGC-32 was detected in both CD4+ and CD8+ T cells. RGC-32 mRNA expression in T cells from healthy controls was upregulated by TCR stimulation, TGFβ, a known inducer and activator of RGC-32 and by incubation with serum from lupus patients with high anti ds-DNA levels. RGC-32 translocated into nucleus upon TCR stimulation in the presence of TGFβ. In in vitro T cell differentiation assays, RGC-32 upregulation was more robust under Th17 (3.2 ± fold) and Treg (2.6 ± 0.8 fold) vs. Th1 (1.3 ± 0.4 fold) and Th2 (1.8 ± 0.1 fold) conditions. Overexpression or silencing of RGC-32 in CD4+ T cells upregulated, respectively downregulated IL-17A transcript levels and protein secretion. RGC-32 mRNA expression was increased in T cells from lupus patients (1.5 ± 0.38) compared to controls (0.5± 0.2). By flow cytometry, both the proportion (30%± 8 vs 16%± 5) and MFI (200± 65 vs 120±35) of RGC-32+ T cells was significantly higher in lupus T cells vs controls. Conclusion: These results suggest that RGC-32 promotes the differentiation of human Th17 cells. Furthermore, T cells from patients with lupus exhibit increased expression of RGC-32 compared to controls. These data support the idea that RGC-32 signaling may enhance disease expression in SLE by promoting abnormalities in the Th17 pathway and provide a compelling rationale for further investigating the therapeutic potential of blocking RGC-32 in lupus.
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Impact of protein corona on the molecular specificity and cellular uptake of decreased nonspecific adhesivity, receptor-targeted (DART) nanoparticles for clinical translationTargeted-nanotherapeutics (NP) have largely failed to translate clinically in showcasing improved disease-specific localization and associated drug delivery efficacy, stemming from a lack of insight into the influence, the type of targeting ligand/ligand density has on nano-bio interactions such as the serum protein corona formation that dictate NP fate in vivo [1]. We have previously developed a therapeutic nano-formulation with decreased adhesivity to blood and non-specific tumor tissue components while maintaining a strong cell surface receptor-specific binding affinity (termed DART nanoparticles) [2]. Recently, we demonstrated in vivo, the efficacy of paclitaxel-loaded DART nanoparticles directed to the cell surface receptor: fibroblast growth factor inducible 14 (Fn14), in primary as well as metastatic triplenegative breast cancer models [3]. In this present work, we investigated the impact of varying the Fn14- specific targeting moiety type- full-length monoclonal antibody (ITEM4 mAb) or fragment, antigen binding (ITEM4 Fab)- on DART NPs surface; On NP-Fn14 target-specificity and the subsequent cellular-uptake profiles by human glioma cell lines. We extensively examined the relationship between the targeting moiety type (ITEM4-mAb vs ITEM4-Fab) and the associated NP-ligand surface density on 1) Fn14 specific binding profiles and affinities 2) The resulting cellular-uptake rates on human glioma cell lines, and the influence of NP-serum protein corona formation on these processes
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Polycystins regulate ezrin function and cleavage to control renal cell and tubular morphologyBackground: Renal cyst formation in ADPKD requires altered cell and tubular morphology. Previously, we used inducible inactivation of Pkd2 in a 3D-tubuloid model to measure acute changes in tubuloid shape after Pkd2 loss and observed alterations in tubule morphology before changes in overall volume, arguing that morphological changes are among the first consequences of polycystin loss. We hypothesized a direct role for the polycystin complex in regulating the apical cytoskeleton protein, ezrin (EZR), to control cell and tubular morphology. Methods: We used clonal cell lines derived from the kidneys of Pkd1 or Pkd2 Pax8rtTA TetOCre mice crossed with the SV40 immorto-mouse: Pkd1-iKO (#312) and Pkd2-iKO (#125). Pkd1/2 can be efficiently deleted with addition of Doxycyline (DOX) to the cell media. Results: We observed a strong correlation between the loss of Pkd1/2 and increased apical cell area, as defined by ZO1, in 2D Pkd1/2-iKO cells. The acute loss of Pkd1/2 also resulted in decreased ezrin abundance and altered localization. Although Pkd1/2 deletion resulted in decreased ezrin we found upregulation of Ezr mRNA in both the DOX treated Pkd2-iKO cells and in human ADPKD cystic tissue, leading us to hypothesize that PC1/2 regulates ezrin protein more directly. Immunoprecipitation experiments of HEK293 cells transfected with ezrin, Myc-PC2 or Flag-PC1 showed both PC1 and PC2 successfully pulled down ezrin suggesting a protein interaction. Interestingly, the pull down efficiency was greater with the full length PC1 than the CTF- PC1 fragment. To confirm an endogenous interaction between ezrin and PC1 we isolated primary renal epithelial cells from a transgenic Pkd1-HA mouse and found again HA-PC1 successfully pulled down ezrin. Mechanistically, ezrin activity is regulated by cystine proteases calpain 1 and 2. We observed a substantial increase in the N-terminal 55KDa ezrin cleavage product after acute Pkd2 loss in the DOX treated Pkd2- iKO cells as well in human APDKD cystic tissue. Chemical inhibition of either calpain 1 or calpain 2 led to increased ezrin cleavage in control cells mimicking Pkd2 loss. However, inhibition of both calpain 1 and 2 reduced ezrin cleavage in DOX treated Pkd2-iKO cells to levels comparable to control cells. Conclusion: The polycystin proteins regulate ezrin function and cleavage to control renal cell and tubular morphology.