Your search keyword '"Virginia L. Gillespie"' showing total 6 results

1. Comparison of Transgenic and Adenovirus hACE2 Mouse Models for SARS-CoV-2 Infection

Author

Fatima Amanat, Shirin Strohmeier, Lynda Coughlan, Virginia L. Gillespie, Florian Krammer, Melissa B. Uccellini, Michael Schotsaert, Adolfo García-Sastre, and Raveen Rathnasinghe

Subjects

0301 basic medicine, Chemokine, Epidemiology, viruses, ACE2, Disease, Virus Replication, medicine.disease_cause, Transgenic Model, Mice, Chlorocebus aethiops, Drug Discovery, Lung, Plaque-forming unit, Mice, Inbred BALB C, adenovirus, General Medicine, Titer, Infectious Diseases, medicine.anatomical_structure, Severe acute respiratory syndrome-related coronavirus, Female, Angiotensin-Converting Enzyme 2, Coronavirus Infections, Research Article, Transgene, Pneumonia, Viral, 030106 microbiology, Immunology, Virus Attachment, Mice, Transgenic, Peptidyl-Dipeptidase A, Biology, Microbiology, Article, Virus, Adenoviridae, Cell Line, Betacoronavirus, 03 medical and health sciences, Virology, medicine, Animals, Humans, mouse models, Pandemics, Vero Cells, SARS-CoV-2, COVID-19, Mice, Inbred C57BL, Disease Models, Animal, 030104 developmental biology, Viral replication, A549 Cells, Cell culture, biology.protein, Parasitology

Abstract

Severe acute respiratory syndrome CoV-2 (SARS-CoV-2) is currently causing a worldwide pandemic with high morbidity and mortality. Development of animal models that recapitulate important aspects of coronavirus disease 2019 (COVID-19) is critical for the evaluation of vaccines and antivirals, and understanding disease pathogenesis. SARS-CoV-2 has been shown to use the same entry receptor as SARS-CoV-1, human angiotensin-converting enzyme 2 (hACE2)(1-3). Due to amino acid differences between murine and hACE2, inbred mouse strains fail to support high titer viral replication of SARS-CoV-2 virus. Therefore, a number of transgenic and knock-in mouse models, as well as viral vector-mediated hACE2 delivery systems have been developed. Here we compared the K18-hACE2 transgenic model to adenovirus-mediated delivery of hACE2 to the mouse lung. We show that K18-hACE2 mice replicate virus to high titers in both the lung and brain leading to lethality. In contrast, adenovirus-mediated delivery results in viral replication to lower titers limited to the lung, and no clinical signs of infection with a challenge dose of 104 plaque forming units. The K18-hACE2 model provides a stringent model for testing the ability of vaccines and antivirals to protect against disease, whereas the adenovirus delivery system has the flexibility to be used across multiple genetic backgrounds and modified mouse strains.

Published

2020

2. Navtemadlin (KRT-232), a Small Molecule MDM2 Inhibitor, Is More Effective Than Decitabine Against Myeloproliferative Neoplasm-Blast Phase in a Patient-Derived Xenograft Model

Author

Ronald Hoffman, Cecile M. Krejsa, Xiaoli Wang, Virginia L. Gillespie, and Cing Siang Hu

Subjects

biology, Chemistry, Immunology, Decitabine, Cell Biology, Hematology, Blast Phase, medicine.disease, Biochemistry, Small molecule, biology.protein, medicine, Cancer research, Mdm2, Tumor xenograft, Myeloproliferative neoplasm, medicine.drug

Abstract

Patients with myeloproliferative neoplasm-blast phase (MPN-BP) have a particularly dismal prognosis with a median survival of less than 6 months with currently available therapies (Mesa Blood 2015). Decitabine is the standard of care for MPN-BP. Recently, using xenotransplantation assays, we have shown that MPN-BP originates at the hematopoietic stem cell (SC) level (Wang Blood 2018) and that MPN-BP CD34 + cells contain higher levels of MDM2 protein compared with their normal counterparts (% of MDM2 + CD34 + cells: MPN-BP: 76.4±3.3; Normal: 17.5±6.4. P We firstestablished the dynamics of leukemia cell recovery following a single cycle of navtemadlin treatment. Spleen cells with wild type (WT) TP53 and mutations in KRAS, RAD21, KMT2A and ASXL1 were collected from the 4 th generation of MPN-BP PDX mice. Forty days after injection of these spleen cells (4×10 5/mouse) into sublethally irradiated NSG mice, peripheral blood (PB) leukemic burden (hCD34 + cells: 0.39±0.09%) was demonstrated by flow cytometric analysis. Mice were treated with vehicle alone (n=3) or high doses of navtemadlin (100 mg/kg, n=4) by daily oral gavage on day (D) 1-7. Without navtemadlin treatment, leukemia engraftment and leukemic burden continued to increase until the mice died on D15-D23. By contrast, hCD34 + leukemic blasts were almost undetectable on D8 and remained at significantly lower levels in PB of mice treated with navtemadlin on D15, than were detected in mice receiving vehicle alone (D8: Vehicle: 1.8±1.3%; Navtemadlin: 0.1±0.1%. D15: Vehicle: 19.9±6.0%; Navtemadlin: 0.5±0.1%). These findings suggest that navtemadlin monotherapy has the potential to deplete MPN-BP blast cells and prolong survival in MPN-BP PDX mice. To achieve long-term remission and to prevent relapse, we treated MPN-BP PDX mice with multiple cycles of low (50 mg/kg, n=4) and high dose navtemadlin (100 mg/kg, n=5) at three-week intervals based on the dynamics of leukemia cell recovery following a single cycle of navtemadlin treatment. hCD34 + cells, which contain MPN-BP SCs, and hCD45 dimCD33 + leukemic blasts were reduced in the spleen, but not in the marrows of mice during 3 cycles of 100 mg/kg navtemadlin treatment. However, reduced leukemia cell burden in PB persisted during 3 cycles of navtemadlin treatment and was associated with a prolongation in survival, which was dose-dependent (Mean survival after transplantation: Vehicle: 64.0 days; 50mg/kg navtemadlin: 86.0 days; 100mg/kg navtemadlin: 98.3 days). We then examined if a combination of navtemadlin and decitabine is more effective than single agent therapy in depleting MPN-BP SCs. Again, navtemadlin at 100 mg/kg significantly reduced the leukemia cell burden in mouse PB on C1D8 (hCD34 + cells: Vehicle: 4.1±0.8%; Navtemadlin: 0.6±0.2%, an 85% decrease. hCD45 dimCD33 + cells: Vehicle: 1.4±0.3%; Navtemadlin: 0.04±0.03%, a 97% decrease. P Disclosures Krejsa: Kartos Therapeutics, Inc.: Current Employment. Hoffman: AbbVie Inc.: Other: Data Safety Monitoring Board, Research Funding; Kartos Therapeutics, Inc.: Research Funding; Protagonist Therapeutics, Inc.: Consultancy; Novartis: Other: Data Safety Monitoring Board, Research Funding.

Published

2021

3. Germline deletion of Krüppel-like factor 14 does not increase risk of diet induced metabolic syndrome in male C57BL/6 mice

Author

Mariana P. Amaro, Jacob Hagen, Carmen Argmann, Tetyana Dodatko, Christoph Buettner, Sander M. Houten, Eric E. Schadt, Sara Violante, Virginia L. Gillespie, and Laboratory Genetic Metabolic Diseases

Subjects

Male, 0301 basic medicine, medicine.medical_specialty, medicine.medical_treatment, Kruppel-Like Transcription Factors, KLF14, White adipose tissue, Type 2 diabetes, Biology, Diet, High-Fat, Article, Transcriptome, Mice, 03 medical and health sciences, Receptors, Glucocorticoid, Insulin resistance, Internal medicine, medicine, Animals, Humans, Insulin, Molecular Biology, Metabolic Syndrome, Mice, Knockout, Apolipoprotein A-I, Sequence Analysis, RNA, Gene Expression Profiling, Cholesterol, HDL, medicine.disease, Mice, Inbred C57BL, Cholesterol, Glucose, 030104 developmental biology, Endocrinology, Molecular Medicine, Insulin Resistance, Metabolic syndrome, Genome-Wide Association Study, Extracellular matrix organization

Abstract

Objective The transcription factor Kruppel-like factor 14 (KLF14) has been associated with type 2 diabetes and high-density lipoprotein-cholesterol (HDL-C) through genome-wide association studies. The mechanistic underpinnings of KLF14's control of metabolic processes remain largely unknown. We studied the physiological roles of KLF14 in a knockout (KO) mouse model. Methods Male whole body Klf14 KO mice were fed a chow or high fat diet (HFD) and diet induced phenotypes were analyzed. Additionally, tissue-specific expression of Klf14 was determined using RT-PCR, RNA sequencing, immunoblotting and whole mount lacZ staining. Finally, the consequences of KLF14 loss-of-function were studied using RNA sequencing in tissues with relatively high Klf14 expression levels. Results KLF14 loss-of-function did not affect HFD-induced weight gain or insulin resistance. Fasting plasma concentrations of glucose, insulin, cholesterol, HDL-C and ApoA-I were also comparable between Klf14 +/+ and Klf14 −/− mice on chow and HFD. We found that in mice expression of Klf14 was the highest in the anterior pituitary (adenohypophysis), lower but detectable in white adipose tissue and undetectable in liver. Loss of KLF14 function impacted on the pituitary transcriptome with extracellular matrix organization as the primary affected pathway and a predicted link to glucocorticoid receptor signaling. Conclusions Whole body loss of KLF14 function in male mice does not result in metabolic abnormalities as assessed under chow and HFD conditions. Mostly likely there is redundancy for the role of KLF14 in the mouse and a diverging function in humans.

Published

2017

4. Immune dysregulation in SHARPIN-deficient mice is dependent on CYLD-mediated cell death

Author

Rosalind L. Ang, John P. Sundberg, Huabao Xiong, Shao Cong Sun, Sergio A. Lira, Peter S. Heeger, Adrian T. Ting, and Virginia L. Gillespie

Subjects

0303 health sciences, Programmed cell death, biology, Chemistry, Immune dysregulation, medicine.disease_cause, Ubiquitin ligase, Cell biology, Deubiquitinating enzyme, 03 medical and health sciences, RIPK1, 0302 clinical medicine, Ubiquitin, biology.protein, medicine, Phosphorylation, Tumor necrosis factor alpha, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

SHARPIN, together with RNF31/HOIP and RBCK1/HOIL1, form the linear ubiquitin chain assembly complex (LUBAC) E3 ligase that catalyzes M1-linked poly-ubiquitination. Mutations in RNF31/HOIP and RBCK/HOIL1 in humans and Sharpin in mice lead to auto-inflammation and immunodeficiency but the mechanism underlying the immune dysregulation remains unclear. We now show that the phenotype of the Sharpin-/- mice is dependent on CYLD, the deubiquitinase that removes K63-linked poly-ubiquitin chains. The dermatitis, disrupted splenic architecture, and loss of Peyer’s patches in the Sharpin-/- mice were fully reversed in Sharpin-/-Cyld-/- mice. There is enhanced association of RIPK1 with the death-inducing signaling complex (DISC) following TNF stimulation in Sharpin-/- cells, and this is dependent on CYLD since it is reversed in Sharpin-/-Cyld-/- cells. Enhanced RIPK1 recruitment to the DISC in Sharpin-/- cells correlated with impaired phosphorylation of CYLD at serine 418, a modification reported to inhibit its enzymatic activity. The dermatitis in the Sharpin-/- mice was also ameliorated by the conditional deletion of Cyld using LysM-cre or Cx3cr1-cre indicating that CYLD-dependent death of myeloid cells is inflammatory. Our studies reveal that under physiological conditions, TNF- and RIPK1-dependent cell death is suppressed by the linear ubiquitin-dependent inhibition of CYLD. The Sharpin-/- phenotype illustrates the pathological consequences when CYLD inhibition fails.Short SummaryIn the absence of SHARPIN, cells fail to properly regulate the deubiquitinase CYLD, leading to RIPK1-mediated cell death. Deletion of Cyld reverses the sensitivity of Sharpin-/- cells to TNF-induced cell death, as well as the multi-organ inflammation and immune dysfunction observed in Sharpin-/- mice.

Published

2020

5. Morbid Obesity Resulting from Inactivation of the Ciliary Protein CEP19 in Humans and Mice

Author

Sehyun Kim, Adel Shalata, Ralph A. DeFronzo, Nazik Arar, Sandra Catalina Camacho, Marc J. Glucksman, Rui Zhang, Zvi Borochowitz, Ying Chen, Mwafaq Ibdah, Nolan Priedigkeit, Robert J. Desnick, Christoph Buettner, Muhammad A. Abdul-Ghani, Olga Camacho-Vanegas, Virginia L. Gillespie, Kevin Kelley, Claudia Lindtner, Feng Dong, Mohammed Mahroum, Maria Celeste M. Ramirez, John A. Martignetti, and Brian David Dynlacht

Subjects

Adult, Male, Genotype, Genetic Linkage, Nonsense mutation, Molecular Sequence Data, Locus (genetics), Cell Cycle Proteins, Biology, Article, Conserved sequence, Consanguinity, Mice, Young Adult, Gene Order, Genetics, medicine, Animals, Humans, Insulin, Genetics(clinical), Amino Acid Sequence, Gene Silencing, Cloning, Molecular, Gene, Genetics (clinical), Conserved Sequence, Genetic Association Studies, Mice, Knockout, Cilium, Gene targeting, Glucose Tolerance Test, Disease gene identification, medicine.disease, Physical Chromosome Mapping, Obesity, Morbid, Pedigree, Disease Models, Animal, Phenotype, Gene Targeting, Mutation, Female, Metabolic syndrome, Insulin Resistance, Signal Transduction

Abstract

Obesity is a major public health concern, and complementary research strategies have been directed toward the identification of the underlying causative gene mutations that affect the normal pathways and networks that regulate energy balance. Here, we describe an autosomal-recessive morbid-obesity syndrome and identify the disease-causing gene defect. The average body mass index of affected family members was 48.7 (range = 36.7–61.0), and all had features of the metabolic syndrome. Homozygosity mapping localized the disease locus to a region in 3q29; we designated this region the morbid obesity 1 (MO1) locus. Sequence analysis identified a homozygous nonsense mutation in CEP19, the gene encoding the ciliary protein CEP19, in all affected family members. CEP19 is highly conserved in vertebrates and invertebrates, is expressed in multiple tissues, and localizes to the centrosome and primary cilia. Homozygous Cep19-knockout mice were morbidly obese, hyperphagic, glucose intolerant, and insulin resistant. Thus, loss of the ciliary protein CEP19 in humans and mice causes morbid obesity and defines a target for investigating the molecular pathogenesis of this disease and potential treatments for obesity and malnutrition.

Published

2013

6. The C terminus of p53 regulates gene expression by multiple mechanisms in a target- and tissue-specific manner in vivo

Author

Nicolas J. Barthelery, Sathish Kumar Mungamuri, James J. Manfredi, Miriam Merad, Pierre-Jacques Hamard, Brandon Hogstad, Luis A. Carvajal, Stuart A. Aaronson, Virginia L. Gillespie, Crystal A. Tonnessen, and Emir Senturk

Subjects

Time Factors, Mutant, Apoptosis, Bone Marrow Cells, Plasma protein binding, Biology, medicine.disease_cause, Mice, Cerebellum, Gene expression, Genetics, medicine, Animals, Gene Knock-In Techniques, Transcription factor, Cellular Senescence, Sequence Deletion, Regulation of gene expression, Mutation, Thymocytes, Genes, p53, Molecular biology, Mice, Inbred C57BL, Haematopoiesis, Gene Expression Regulation, Liver, Growth and Development, Tumor Suppressor Protein p53, Cell aging, Protein Processing, Post-Translational, Developmental Biology, Research Paper, Protein Binding

Abstract

The p53 tumor suppressor is a transcription factor that mediates varied cellular responses. The C terminus of p53 is subjected to multiple and diverse post-translational modifications. An attractive hypothesis is that differing sets of combinatorial modifications therein determine distinct cellular outcomes. To address this in vivo, a Trp53ΔCTD/ΔCTD mouse was generated in which the endogenous p53 is targeted and replaced with a truncated mutant lacking the C-terminal 24 amino acids. These Trp53ΔCTD/ΔCTD mice die within 2 wk post-partum with hematopoietic failure and impaired cerebellar development. Intriguingly, the C terminus acts via three distinct mechanisms to control p53-dependent gene expression depending on the tissue. First, in the bone marrow and thymus, the C terminus dampens p53 activity. Increased senescence in the Trp53ΔCTD/ΔCTD bone marrow is accompanied by up-regulation of Cdkn1 (p21). In the thymus, the C-terminal domain negatively regulates p53-dependent gene expression by inhibiting promoter occupancy. Here, the hyperactive p53ΔCTD induces apoptosis via enhanced expression of the proapoptotic Bbc3 (Puma) and Pmaip1 (Noxa). In the liver, a second mechanism prevails, since p53ΔCTD has wild-type DNA binding but impaired gene expression. Thus, the C terminus of p53 is needed in liver cells at a step subsequent to DNA binding. Finally, in the spleen, the C terminus controls p53 protein levels, with the overexpressed p53ΔCTD showing hyperactivity for gene expression. Thus, the C terminus of p53 regulates gene expression via multiple mechanisms depending on the tissue and target, and this leads to specific phenotypic effects in vivo.

Published

2013