Browsing by Author "Caudell, David L."
Now showing 1 - 8 of 8
Results Per Page
Sort Options
- Altered Kinetics of Non-Homologous End Joining Mediated DNA Repair in Mouse Models of Aging and LeukemiaPuthiyaveetil Abdulkader, Abdul Gafoor (Virginia Tech, 2012-09-25)DNA encodes the genetic instructions for the development and function of organisms and hence maintaining genomic integrity is essential for the propagation of life. However, DNA molecules are under constant threat of metabolic and environmental insults resulting in DNA damages including DNA double strand breaks (DSB), which are considered as a serious threat to cell survival. The majority of these DSB are repaired by Non-homologous end joining (NHEJ). Unrepaired DSB can lead to genomic instability resulting in cell cycle arrest, apoptosis, and mutations. Thus, delineating this DNA repair process is important in understanding the molecular mechanisms of aging and malignant progression. B lymphocytes undergo physiological DNA breaks and NHEJ-mediated DNA repair during their bone marrow differentiation and peripheral class switch recombination (CSR), thus lending them as a good model system in which to delineate the DNA repair mechanisms. To determine the effect of aging on NHEJ, B lymphocytes from old mice were analyzed. The results showed compromised DNA repair in cells from old mice compared to cells from adult mice. These results suggest that NHEJ is compromised during aging and might play critical roles in the aging process and age-associated conditions. To delineate the role of a CT in regulating the immune system, transgenic mice expressing NUP98-HOXD13 (NHD13) were analyzed for B lymphocyte differentiation, peripheral development, CSR, and antibody production. The results showed impaired B cell development and antibody production, which worsened with antigenic stimulation, suggesting the role of NHD13 in immune regulation. These studies explored the possibility of altered NHEJ-mediated DNA repair as a contributing reason for aging process and age-associated conditions. Also, the results from NHD13 study suggested that a primary CT can result in impaired NHEJ and regulate immune cell development and function. Furthermore, the results pointed to the possibility that a primary CT may lead to secondary mutations through altered NHEJ. Thus, these studies shed insight into the molecular mechanisms of altered NHEJ and may help in developing preventive or therapeutic strategies against accumulation of DNA damage, aging process and secondary mutations.
- Canine Snake-Eye Myelopathy: Clinical, Magnetic Resonance Imaging, and Pathologic Findings in Four CasesRossmeisl, John H. Jr.; Cecere, Thomas E.; Kortz, Gregg D.; Geiger, David A.; Shinn, Richard L.; Hinckley, Jonathan; Caudell, David L.; Stahle, Jessica A. (Frontiers, 2019-07-05)Intramedullary signal change (ISC) is a non-specific finding that is frequently observed on magnetic resonance imaging (MRI) examinations of the canine spinal cord. ISC can represent a variety of primary pathological processes such as neoplasms or myelitides or secondary changes such as edema, cysts, gliosis, or myelomalacia. An unusual phenotype of ISC is the "snake-eye" myelopathy (SEM), which refers to bilaterally symmetric T2 hyperintensities preferentially affecting the ventral horn gray matter on transverse MR images, which resemble a pair of snake's eyes. The pathophysiology of SEM is poorly understood in humans, and this imaging finding may be associated with cervical spondylotic myelopathy, spinal cord ischemia, ossification of the posterior longitudinal ligament, amyotrophic lateral sclerosis, and Hirayama disease. Here we describe four dogs with cervical MRI examinations consistent with an SEM-like phenotype. All dogs initially presented with a central cord syndrome or tetraparesis referable to a C6-T2 neuroanatomic localization, which was attributed to disc-associated spinal cord compression in three cases, while one dog had the SEM-like phenotype with no identifiable etiology. Once the SEM-like phenotype was present on MRI examinations, dogs demonstrated insidious clinical deterioration despite therapeutic interventions. Deterioration was characterized by lower motor neuron weakness and neurogenic muscle atrophy progressing to paralysis in the thoracic limbs, while neurological functions caudal to the level of the SEM-like lesion remained largely preserved for months to years thereafter. Neuropathological features of the SEM-like phenotype include multisegmental cavitations and poliomyelomalacia of laminae VI-IX of the caudal cervical spinal cord, although the lesion evolved into pan-necrosis of gray matter with extension into the adjacent white matter in one case with an 8 years history of progressive disease. Although the pathophysiology of SEM remains unknown, the topographical distribution and appearance of lesions is suggestive of a vascular disorder. As the SEM-like phenotype was uniformly characterized by longitudinally and circumferentially extensive neuronal necrosis, results of this small case series indicate that dogs with clinical signs of central cord syndrome and the SEM-like phenotype involving the cervicothoracic intumescence on MR examinations have a poor prognosis for the preservation or recovery of thoracic limb motor function.
- Evaluation of the actin architecture in dysplastic megakaryocytes expressing the NUP98-HOXD13 leukemic fusion geneOkyere, Benjamin (Virginia Tech, 2013-08-30)Some myelodysplastic syndrome (MDS) patients present with macrothrombocytopenia due to impaired megakaryocyte (MK) differentiation. Transgenic mice that express the NUP98-HOXD13 (NHD13) fusion gene is a model for MDS and recapitulates the key features of MDS. The study investigated the hypothesis that expression of NHD13 disrupts actin architecture during MK differentiation leading to macrothrombocytopenia. To test the hypothesis, sternums were stained with hematoxylin and eosin, and evaluated by light microscopy to analyze MK morphology in vivo. NHD13 bone marrow (BM) contained many dysplastic MK. BM from wild type (WT) and NHD13 mice were also flushed, cultured in media supplemented with thrombopoietin only or with estrogen to induce proplatelet formation, and MK harvested after 5 days. Harvested MK and BM cores were processed and analyzed by transmission electron microscopy (TEM) to detail the ultrastructural features. TEM of MK revealed that NHD13 leads to formation of an irregular demarcation membrane system and fewer proplatelets. Cultured WT and NHD13 MK were also cytospun onto glass slides, labeled with fluorescent-tagged F-actin, α/β-tubulin and myosin IIa, and their cytoskeleton compared. Interestingly WT MK had actin either distributed evenly or predominantly in the periphery of the cytoplasm, NHD13 MK displayed only the former phenotype. Additionally, proplatelets lacked actin cytoplasmic extensions. The results from the present thesis demonstrate actin expression and architecture are impaired in dysplastic MK expressing the NHD13 leukemic fusion gene and leads to macrothromcytopenia. Understanding the molecular mechanisms of abnormal MK differentiation in MDS is important as many MDS patients die of hemorrhagic complications.
- Identification of a Common Lupus Disease-Associated microRNA Expression Pattern in Three Different Murine Models of LupusDai, Rujuan; Zhang, Yan; Khan, Deena; Heid, Bettina; Caudell, David L.; Crasta, Oswald R.; Ahmed, Sattar Ansar (PLOS, 2010-12-10)Background Recent reports have shown that microRNAs (miRNAs) regulate vital immunological processes and have emerged as key regulators of immune system development and function. Therefore, it is important to determine miRNA dysregulation and its pathogenic contribution in autoimmune diseases, an aspect not adequately addressed thus far. Methodology/Principal Findings In this study, we profiled miRNA expressions in splenic lymphocytes from three murine lupus models (MRL-lpr, B6-lpr and NZB/WF1) with different genetic background by miRNA microarray assays and Real-time RT-PCR. Despite the genetic differences among these three lupus stains, a common set of dysregulated miRNAs (miR-182-96-183 cluster, miR-31, and miR-155) was identified in splenocytes when compared with age-matched control mice. The association of these miRNAs with the disease was highlighted by our observation that this miRNA expression pattern was evident in NZB/W mice only at an age when lupus disease is manifested. Further, we have shown that the miRNA dysregulation in MRL-lpr mice was not simply due to the activation of splenocytes. By Real-time RT-PCR, we confirmed that these miRNAs were upregulated in both purified splenic B and T cells from MRL-lpr mice. miR-127 and miR-379, which were greatly upregulated in splenocytes from lpr mice, were moderately increased in diseased NZB/W mice. In addition, Real-time RT-PCR revealed that miR-146a, miR-101a, and miR-17-92 were also markedly upregulated in splenic T, but not B cells from MRL-lpr mice. Conclusions/Significance The identification of common lupus disease-associated miRNAs now forms the basis for the further investigation of the pathogenic contribution of these miRNAs in autoimmune lupus, which will advance our knowledge of the role of miRNAs in autoimmunity. Given that miRNAs are conserved, with regard to both evolution and function, our observation of a common lupus disease-associated miRNA expression pattern in murine lupus models is likely to have significant pathogenic, diagnostic, and/or therapeutic implications in human lupus.
- Inhibition of Heat Shock Protein 90 Reduces Inflammatory Signal Transduction in Murine J774 Macrophage Cells and Lessens Disease in Autoimmune MRL/lpr Mice: What in vitro, in vivo, and in silico Models RevealShimp, Samuel Kline (Virginia Tech, 2012-04-30)Heat shock protein 90 (HSP90) is a molecular chaperone protein that protects proteins from degradation, repairs damaged proteins, and assists proteins in carrying out their functions. HSP90 has hundreds of clients, many of which are inflammatory signaling kinases. The mechanism by which HSP90 enables inflammatory pathways is an active area of investigation. The HSP90 inhibitors such as geldanamycin (GA) and its derivative 17-dimethylaminoethylamino-17-demethoxygeldanamycin (17-DMAG) have been shown to reduce inflammation. It was hypothesized that inhibiting HSP90 would reduce inflammatory signal cascade levels. To test this, J774 mouse macrophage cells were treated with 17-DMAG and immune-stimulated with lipopolysaccharide (LPS). 17-DMAG treatment reduced nitric oxide (NO) production and the expression of pro-inflammatory cytokines interleukin (IL)-6, IL-12, and TNF-α. Inhibition of HSP90 also prevented nuclear translocation of NF-κB. To investigate the anti-inflammatory effects of HSP90 inhibition in vivo, MRL/lpr lupus mice were administered 5 mg/kg 17-DMAG for six weeks via intraperitoneal injection. Mice treated with 17-DMAG were found to have reduced proteinuria and reduced splenomegaly. Flow cytometric analysis of splenocytes showed that 17-DMAG decreased double negative T (DNT) cells. Renal expression of HSP90 was also measured and found to be increased in MRL/lpr mice that did not receive 17-DMAG. The mechanistic interactions between HSP90 and the pro-inflammatory nuclear factor-κB (NF-κB) pathway were studied and a computational model was developed. The model predicts cellular response of inhibitor of κB kinase (IKK) activation and NF-κB activation to LPS stimulation. Model parameters were fit to IKK activation data. Parameter sensitivity was assessed through simulation studies and showed a strong dependence on IKK-HSP90 binding. The model also accounts for the effect of a general HSP90 inhibitor to disrupt the IKK-HSP90 interaction for reduced activation of NF-κB. Model simulations were validated with experimental data. In conclusion, HSP90 facilitates inflammation through multiple signal pathways including Akt and IKK. Inhibition of HSP90 by 17-DMAG reduced disease in the MRL/lpr lupus mouse model. A computational model supported the hypothesis that HSP90 is required for IKK to activate the NF-κB pathway. Taken together, HSP90 is a prime target for therapeutic regulation of many inflammatory processes and warrants further study to understand its mechanism of regulating cell signaling cascades.
- Isoform-Selective HDAC Inhibition for the Treatment of Lupus NephritisRegna, Nicole Lynn (Virginia Tech, 2014-06-19)Systemic lupus erythematosus (SLE) is a prototypic autoimmune disease requiring a genetic predisposition coupled with an environmental trigger in order for initiation of disease. While the exact pathoaetiology has yet to be determined, both B and T cell dysregulation are thought to contribute to disease. Histone deacetylases (HDACs) are a class of enzymes that hydrolyze the lysine bound acetyl group in both histone and non-histone proteins thereby altering protein structure and function. While the use of pan-HDAC inhibitors has proven to be effective for the treatment of a number of acute diseases, they may not be viable as therapeutics for chronic disease due to cytotoxicity and adverse side effects following long term treatment. We sought to determine whether treatment with a class I and II HDAC inhibitor (HDACi) or a specific HDAC6i would be able to ameliorate disease in lupus-prone NZB/W mice. We found that both the class I and II HDACi (ITF2357) and the HDAC6i (ACY-738) were able to decrease SLE markers of disease including splenomegaly, proteinuria, and anti-dsDNA and IgG production in the sera. Treatment with ITF2357 resulted in an increase in the number of immunosuppressive regulatory T (Treg) cells and a decrease in the pro-inflammatory Th17 phenotype. Furthermore, ITF2357 was found to increase Foxp3 acetylation leading to increased Foxp3 stability allowing for differentiation into the Treg phenotype. ACY-738 treatment was able to correct aberrant bone marrow B cell differentiation while also increasing the number of splenic Treg cells in NZB/W mice. These results suggest that HDAC inhibition is able to ameliorate SLE in NZB/W mice by altering aberrant T and B cell differentiation. Additional studies were performed to further examine the expression and function of different HDAC isoforms in immune cells. Due to the ability of HDAC inhibition to decrease markers of SLE disease as well as alter B and T cell development and differentiation, we sought to determine if specific HDAC isoforms are altered in lupus vs non lupus mice in early and late disease states. We determined the level of class IIb HDAC (HDACs 6, 9, and 10) expression in bone marrow B cells, splenic B and T cells, and glomerular cells from early- and late-disease MRL/lpr lupus-prone mice compared to healthy, age-matched C57BL/6 control mice. Expression of HDAC6 and HDAC9 were significantly increased in all of the tissues tested from MRL/lpr mice. Furthermore, both cytoplasmic and nuclear HDAC activity was increased in diseased MRL/lpr mice, and HDAC activity and expression continued to increase as disease progressed. In vitro treatment with ACY-738, a selective HDAC6i, was able to decrease cytoplasmic HDAC activity and inhibit iNOS production. Furthermore, ACY-738 was able to alter apoptosis through increased Bax expression in B cells. Treatment with ACY-738 was also able to inhibit Hsp90 expression and decrease NF-κB nuclear translocation, which are both upregulated during active SLE. Our studies indicate that HDAC activity contributes to SLE pathogenesis and that the use of isoform-selective HDAC inhibitors may be a viable treatment for SLE.
- MicroRNA-mediated Attenuation of Inflammation in NZB/W Lupus MiceChafin, Cristen Brooke (Virginia Tech, 2013-10-08)Systemic lupus erythematosus (SLE) is an autoimmune disease characterized by the production and deposition of nuclear self-antigen-containing immune complexes. Epigenetic factors, including altered microRNA (miRNA) expression, may contribute to aberrant immune cell function in SLE. miRNAs are small, noncoding RNAs that bind to the 3’ untranslated region of target mRNAs resulting in post-transcriptional gene modulation. IL-6, an inflammatory cytokine overproduced by mesangial cells in SLE, contains a potential binding site for miR-let-7a. In order to examine if alterations in miR-let-7a expression can influence inflammatory mediator production in SLE, we isolated mesangial cell miRNAs from 8 and 32- week-old female New Zealand Black/White (NZB/W) mice. We found miR-let-7a expression was significantly increased in the mesangial cells of pre-diseased and actively diseased NZB/W mice compared to age-matched female New Zealand White (NZW) controls. Overexpression of miR-let-7a in vitro increased IL-6 production in LPS/IFN-γ-stimulated mesangial cells compared to the stimulated control. Due to the crucial role of miR-let-7a in cell division and inflammation, we investigated miR-let-7a-mediated proliferation and NFκB activation in J774A.1 macrophages and MES 13 mesangial cells in vitro. Cell proliferation, retinoblastoma protein (Rb) phosphorylation, and NFκB activation were increased in cells transfected with miR-let-7a and stimulated with LPS/IFN-γ. Expression and production of the cell cycle inhibitor E2F5 was decreased in stimulated cells overexpressing miR-let-7a. We found that the cell cycle promoter E2F2 and NFκB target the miR-let-7a promoter. Next we sought to determine alterations in iii specific disease-associated miRNAs in female NZB/W mice treated with hydroxychloroquine (HCQ) or prednisone (PRED) for 12 weeks beginning at 20 weeks-of-age. We found that treatment with HCQ or PRED induced unique changes to miRNA expression in multiple tissues. In order to identify specific miRNAs as disease-modifying agents and not merely disease correlates, further in vitro analyses confirmed HCQ or PRED-mediated inhibition of miRNAs is critical to alter the inflammatory response. Taken together, our results suggest that overexpression of miR-let-7a may contribute to hyperplasia and the proinflammatory response in SLE. Our studies indicate that lupus therapeutics may work, in part, by altering the expression of disease-associated miRNAs in immune cells and the urine.
- Selective HDAC6 Inhibition in Systemic Lupus ErythematosusVieson, Miranda Diane (Virginia Tech, 2017-01-30)Systemic lupus erythematosus (SLE) is a prototypic autoimmune disease characterized by abnormalities in multiple components of the immune system resulting in progressive damage to multiple organs. Current treatments for SLE are often intensive and result in side effects and the potential for continued flares and progression of disease. Histone deacetylase (HDAC) enzymes control multiple cellular functions by removing acetyl groups from lysine residues in various proteins. HDAC inhibitors have been investigated as a potential treatment for SLE with promising results, however selective HDAC6 inhibition (HDAC6i) has become a leading candidate for pharmacologic inhibition to reduce the potential for side effects. We hypothesize that HDAC6i will decrease SLE disease by targeting substrates of HDAC6 in multiple components of immunity and organ systems. NZB/W mice were treated with ACY-738 or ACY-1083, followed by evaluation of multiple disease parameters and mechanisms involved in disease pathogenesis within the kidney, bone marrow, and spleen. Within the kidney, HDAC6i decreased glomerular pathology scores, proteinuria, and IgG and C3 deposition. Within glomerular cells, HDAC6i increased alpha-tubulin acetylation and decreased nuclear NF-κB. Within the spleen, there was a dose-dependent decrease in the frequency of Th17 cells and a mild decrease in the frequency of Treg cells. Concurrently, there were decreased levels of IL-12/IL-23 and minimal decreases in TGF-β in the serum. Within the bone marrow, B cell development through Hardy fractions exhibited accelerated progression through later stages as NZB/W mice aged. This accelerated progression may allow B cells to bypass important regulatory checkpoints in maintaining immune tolerance and contribute to autoimmunity. Treatment with an HDAC6i corrected the aberrant B cell development in the bone marrow and RNAseq analysis unveiled six genes (Cebpb, Ccr9, Spib, Nfil3, Lgals1, and Pou2af1) that may play a role in the aforementioned abnormalities. Overall, these findings show that HDAC6i decreased disease in NZB/W mice by targeting multiple components of the immune response, including glomerular cells, T cell subsets in the spleen, and bone marrow B cells. In conclusion, selective HDAC6i is an excellent candidate for pharmacologic therapy for SLE because it targets multiple immune abnormalities involved in SLE pathogenesis while remaining selective and safe.