Your search keyword '"Guarnieri, Joseph W."' showing total 27 results

1. Author Correction: To boldly go where no microRNAs have gone before: spaceflight impact on risk for small-for-gestational-age infants

Author

Corti, Giada, Kim, JangKeun, Enguita, Francisco J., Guarnieri, Joseph W., Grossman, Lawrence I., Costes, Sylvain V., Fuentealba, Matias, Scott, Ryan T., Magrini, Andrea, Sanders, Lauren M., Singh, Kanhaiya, Sen, Chandan K., Juran, Cassandra M., Paul, Amber M., Furman, David, Calleja-Agius, Jean, Mason, Christopher E., Galeano, Diego, Bottini, Massimo, and Beheshti, Afshin

Published

2024

2. To boldly go where no microRNAs have gone before: spaceflight impact on risk for small-for-gestational-age infants

Author

Corti, Giada, Kim, JangKeun, Enguita, Francisco J., Guarnieri, Joseph W., Grossman, Lawrence I., Costes, Sylvain V., Fuentealba, Matias, Scott, Ryan T., Magrini, Andrea, Sanders, Lauren M., Singh, Kanhaiya, Sen, Chandan K., Juran, Cassandra M., Paul, Amber M., Furman, David, Calleja-Agius, Jean, Mason, Christopher E., Galeano, Diego, Bottini, Massimo, and Beheshti, Afshin

Published

2024

3. Space radiation damage rescued by inhibition of key spaceflight associated miRNAs

Author

McDonald, J. Tyson, Kim, JangKeun, Farmerie, Lily, Johnson, Meghan L., Trovao, Nidia S., Arif, Shehbeel, Siew, Keith, Tsoy, Sergey, Bram, Yaron, Park, Jiwoon, Overbey, Eliah, Ryon, Krista, Haltom, Jeffrey, Singh, Urminder, Enguita, Francisco J., Zaksas, Victoria, Guarnieri, Joseph W., Topper, Michael, Wallace, Douglas C., Meydan, Cem, Baylin, Stephen, Meller, Robert, Muratani, Masafumi, Porterfield, D. Marshall, Kaufman, Brett, Mori, Marcelo A., Walsh, Stephen B., Sigaudo-Roussel, Dominique, Mebarek, Saida, Bottini, Massimo, Marquette, Christophe A., Wurtele, Eve Syrkin, Schwartz, Robert E., Galeano, Diego, Mason, Christopher E., Grabham, Peter, and Beheshti, Afshin

Published

2024

4. Secretome profiling reveals acute changes in oxidative stress, brain homeostasis, and coagulation following short-duration spaceflight

Author

Houerbi, Nadia, Kim, JangKeun, Overbey, Eliah G., Batra, Richa, Schweickart, Annalise, Patras, Laura, Lucotti, Serena, Ryon, Krista A., Najjar, Deena, Meydan, Cem, Damle, Namita, Chin, Christopher, Narayanan, S. Anand, Guarnieri, Joseph W., Widjaja, Gabrielle, Beheshti, Afshin, Tobias, Gabriel, Vatter, Fanny, Hirschberg, Jeremy Wain, Kleinman, Ashley, Afshin, Evan E., MacKay, Matthew, Chen, Qiuying, Miller, Dawson, Gajadhar, Aaron S., Williamson, Lucy, Tandel, Purvi, Yang, Qiu, Chu, Jessica, Benz, Ryan, Siddiqui, Asim, Hornburg, Daniel, Gross, Steven, Shirah, Bader, Krumsiek, Jan, Mateus, Jaime, Mao, Xiao, Matei, Irina, and Mason, Christopher E.

Published

2024

5. A comprehensive SARS-CoV-2 and COVID-19 review, Part 2: host extracellular to systemic effects of SARS-CoV-2 infection

Author

Narayanan, S. Anand, Jamison, Jr, David A., Guarnieri, Joseph W., Zaksas, Victoria, Topper, Michael, Koutnik, Andrew P., Park, Jiwoon, Clark, Kevin B., Enguita, Francisco J., Leitão, Ana Lúcia, Das, Saswati, Moraes-Vieira, Pedro M., Galeano, Diego, Mason, Christopher E., Trovão, Nídia S., Schwartz, Robert E., Schisler, Jonathan C., Coelho-dos-Reis, Jordana G. A., Wurtele, Eve Syrkin, and Beheshti, Afshin

Published

2024

6. SARS-CoV-2 mitochondrial metabolic and epigenomic reprogramming in COVID-19

Author

Guarnieri, Joseph W., Haltom, Jeffrey A., Albrecht, Yentli E. Soto, Lie, Timothy, Olali, Arnold Z., Widjaja, Gabrielle A., Ranshing, Sujata S., Angelin, Alessia, Murdock, Deborah, and Wallace, Douglas C.

Published

2024

7. A comprehensive SARS-CoV-2 and COVID-19 review, Part 1: Intracellular overdrive for SARS-CoV-2 infection

Author

Jamison, Jr., David A., Anand Narayanan, S., Trovão, Nídia S., Guarnieri, Joseph W., Topper, Michael J., Moraes-Vieira, Pedro M., Zaksas, Viktorija, Singh, Keshav K., Wurtele, Eve Syrkin, and Beheshti, Afshin

Published

2022

8. Lethal COVID-19 associates with RAAS-induced inflammation for multiple organ damage including mediastinal lymph nodes.

Author

Topper, Michael J., Guarnieri, Joseph W., Haltom, Jeffrey A., Chadburn, Amy, Cope, Henry, Frere, Justin, An, Julia, Borczuk, Alain, Sinha, Saloni, Kim, JangKeun, Park, Jiwoon, Butler, Daniel, Meydan, Cem, Foox, Jonathan, Bram, Yaron, Richard, Stephanie A., Epsi, Nusrat J., Agan, Brian, Chenoweth, Josh G., and Simons, Mark P.

Subjects

*RENIN-angiotensin system, *SARS-CoV-2, *CYTOKINE release syndrome, *LYMPH nodes, *RNA sequencing

Abstract

Lethal COVID-19 outcomes are attributed to classic cytokine storm. We revisit this using RNA sequencing of nasopharyngeal and 40 autopsy samples from patients dying of SARS-CoV-2. Subsets of the 100 top-upregulated genes in nasal swabs are upregulated in the heart, lung, kidney, and liver, but not mediastinal lymph nodes. Twenty-two of these are "noncanonical" immune genes, which we link to components of the renin-angiotensin-activation-system that manifest as increased fibrin deposition, leaky vessels, thrombotic tendency, PANoptosis, and mitochondrial dysfunction. Immunohistochemistry of mediastinal lymph nodes reveals altered architecture, excess collagen deposition, and pathogenic fibroblast infiltration. Many of the above findings are paralleled in animal models of SARS-CoV-2 infection and human peripheral blood mononuclear and whole blood samples from individuals with early and later SARS-CoV-2 variants. We then redefine cytokine storm in lethal COVID-19 as driven by upstream immune gene and mitochondrial signaling producing downstream RAAS (renin-angiotensin-aldosterone system) overactivation and organ damage, including compromised mediastinal lymph node function. [ABSTRACT FROM AUTHOR]

Published

2024

9. Role of miR-2392 in driving SARS-CoV-2 infection

Author

Wallet, Shannon M., Maile, Robert, Wolfgang, Matthew C., Hagan, Robert S., Mock, Jason R., Bowman, Natalie M., Torres-Castillo, Jose L., Love, Miriya K., Meinig, Suzanne L., Lovell, Will, Rice, Colleen, Mitchem, Olivia, Burgess, Dominique, Suggs, Jessica, Jacobs, Jordan, McDonald, J. Tyson, Enguita, Francisco J., Taylor, Deanne, Griffin, Robert J., Priebe, Waldemar, Emmett, Mark R., Sajadi, Mohammad M., Harris, Anthony D., Clement, Jean, Dybas, Joseph M., Aykin-Burns, Nukhet, Guarnieri, Joseph W., Singh, Larry N., Grabham, Peter, Baylin, Stephen B., Yousey, Aliza, Pearson, Andrea N., Corry, Peter M., Saravia-Butler, Amanda, Aunins, Thomas R., Sharma, Sadhana, Nagpal, Prashant, Meydan, Cem, Foox, Jonathan, Mozsary, Christopher, Cerqueira, Bianca, Zaksas, Viktorija, Singh, Urminder, Wurtele, Eve Syrkin, Costes, Sylvain V., Davanzo, Gustavo Gastão, Galeano, Diego, Paccanaro, Alberto, Altinok, Selin, Sapoval, Nicolae, Treangen, Todd J., Moraes-Vieira, Pedro M., Vanderburg, Charles, Wallace, Douglas C., Schisler, Jonathan C., Mason, Christopher E., Chatterjee, Anushree, Meller, Robert, and Beheshti, Afshin

Published

2021

10. PET Imaging with [ 18 F]ROStrace Detects Oxidative Stress and Predicts Parkinson's Disease Progression in Mice.

Author

Zhu, Yi, Kohli, Neha, Young, Anthony, Sheldon, Malkah, Coni, Jani, Rajasekaran, Meera, Robinson, Lozen, Chroneos, Rea, Riley, Shaipreeah, Guarnieri, Joseph W., Jose, Joshua, Patel, Nisha, Wallace, Douglas C., Li, Shihong, Lee, Hsiaoju, Mach, Robert H., and McManus, Meagan J.

Subjects

PARKINSON'S disease, TRANSCRIPTION factors, POSITRON emission tomography, RADIOACTIVE tracers, REACTIVE oxygen species

Abstract

Although the precise molecular mechanisms responsible for neuronal death and motor dysfunction in late-onset Parkinson's disease (PD) are unknown, evidence suggests that mitochondrial dysfunction and neuroinflammation occur early, leading to a collective increase in reactive oxygen species (ROS) production and oxidative stress. However, the lack of methods for tracking oxidative stress in the living brain has precluded its use as a potential biomarker. The goal of the current study is to address this need through the evaluation of the first superoxide (O2•−)-sensitive radioactive tracer, [18F]ROStrace, in a model of late-onset PD. To achieve this goal, MitoPark mice with a dopaminergic (DA) neuron-specific deletion of transcription factor A mitochondrial (Tfam) were imaged with [18F]ROStrace from the prodromal phase to the end-stage of PD-like disease. Our data demonstrate [18F]ROStrace was sensitive to increased oxidative stress during the early stages of PD-like pathology in MitoPark mice, which persisted throughout the disease course. Similarly to PD patients, MitoPark males had the most severe parkinsonian symptoms and metabolic impairment. [18F]ROStrace retention was also highest in MitoPark males, suggesting oxidative stress as a potential mechanism underlying the male sex bias of PD. Furthermore, [18F]ROStrace may provide a method to identify patients at risk of Parkinson's before irreparable neurodegeneration occurs and enhance clinical trial design by identifying patients most likely to benefit from antioxidant therapies. [ABSTRACT FROM AUTHOR]

Published

2024

11. A pan-tissue, pan-disease compendium of human orphan genes

Author

Singh, Urminder, primary, Haltom, Jeffrey A., additional, Guarnieri, Joseph W., additional, Li, Jing, additional, Seetharam, Arun, additional, Beheshti, Afshin, additional, Aronow, Bruce, additional, and Wurtele, Eve Syrkin, additional

Published

2024

12. Mitochondrial antioxidants abate SARS-COV-2 pathology in mice.

Author

Guarnieri, Joseph W., Lie, Timothy, Soto Albrecht, Yentli E., Hewin, Peter, Jurado, Kellie A., Widjaja, Gabrielle A., Yi Zhu, McManus, Meagan J., Kilbaugh, Todd J., Keith, Kelsey, Potluri, Prasanth, Taylor, Deanne, Angelin, Alessia, Murdock, Deborah G., and Wallace, Douglas C.

Subjects

*SARS-CoV-2, *ANGIOTENSIN converting enzyme, *MITOCHONDRIAL DNA, *VIRAL proteins, *GENE expression

Abstract

Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2) infection inhibits mito-chondrial oxidative phosphorylation (OXPHOS) and elevates mitochondrial reactive oxygen species (ROS, mROS) which activates hypoxia-inducible factor-1alpha (HIF-1a), shifting metabolism toward glycolysis to drive viral biogenesis but also causing the release of mitochondrial DNA (mtDNA) and activation of innate immunity. To determine whether mitochondrially targeted antioxidants could mitigate these viral effects, we challenged mice expressing human angiotensin-converting enzyme 2 (ACE2) with SARS-CoV-2 and intervened using transgenic and pharmacological mitochondrially targeted catalytic antioxidants. Transgenic expression of mitochondrially targeted catalase (mCAT) or systemic treatment with EUK8 decreased weight loss, clinical severity, and circulating levels of mtDNA; as well as reduced lung levels of HIF-1α, viral proteins, and inflammatory cytokines. RNA-sequencing of infected lungs revealed that mCAT and Eukarion 8 (EUK8) up-regulated OXPHOS gene expression and down-regulated HIF-1α and its target genes as well as innate immune gene expression. These data demonstrate that SARS-CoV-2 pathology can be mitigated by catalytically reducing mROS, potentially providing a unique host-directed pharmacological therapy for COVID-19 which is not subject to viral mutational resistance. [ABSTRACT FROM AUTHOR]

Published

2024

13. A comprehensive SARS-CoV-2 and COVID-19 review, Part 2: host extracellular to systemic effects of SARS-CoV-2 infection

Author

Narayanan, S. Anand, primary, Jamison, David A., additional, Guarnieri, Joseph W., additional, Zaksas, Victoria, additional, Topper, Michael, additional, Koutnik, Andrew P., additional, Park, Jiwoon, additional, Clark, Kevin B., additional, Enguita, Francisco J., additional, Leitão, Ana Lúcia, additional, Das, Saswati, additional, Moraes-Vieira, Pedro M., additional, Galeano, Diego, additional, Mason, Christopher E., additional, Trovão, Nídia S., additional, Schwartz, Robert E., additional, Schisler, Jonathan C., additional, Coelho-dos-Reis, Jordana G. A., additional, Wurtele, Eve Syrkin, additional, and Beheshti, Afshin, additional

Published

2023

14. LETHAL COVID-19 ASSOCIATES WITH RAAS-INDUCED INFLAMMATION FOR MULTIPLE ORGAN DAMAGE INCLUDING MEDIASTINAL LYMPH NODES

Author

Guarnieri, Joseph W, primary, Topper, Michael, additional, Beigel, Katherine, additional, Haltoom, Jeff A, additional, Chadburn, Amy, additional, Frere, Justin, additional, An, Julia, additional, Cope, Henry, additional, Borczuk, Alain, additional, Sinha, Saloni, additional, Lim, Christine, additional, Kim, JangKeun, additional, Park, Jiwoon, additional, Meydan, Cem, additional, Foox, Jonathan, additional, Mozsary, Christopher, additional, Bram, Yaron, additional, Richard, Stephanie, additional, Epsi, Nusrat, additional, Agan, Brian, additional, Chenoweth, Josh, additional, Simons, Mark, additional, Tribble, David, additional, Burgess, Timothy, additional, Dalgard, Clifton L., additional, Heise, Mark T., additional, Moorman, Nathaniel, additional, Baxter, Victoria, additional, Madden, Emily A., additional, Taft-Benz, Sharon, additional, Anderson, Elizabeth, additional, Sanders, Wes A., additional, Dickmander, Rebekah J., additional, Widjaja, Gabrielle A., additional, Janssen, Kevin, additional, Lie, Timothy, additional, Murdock, Deborah G, additional, Angelin, Alessia, additional, Albrecht, Yentli E. S., additional, Olali, Arnold, additional, Dybas, Joseph M., additional, Priebe, Waldemar, additional, Emmett, Mark R., additional, Best, Sonja, additional, Johnson, Maya Kelsey, additional, Trovao, Nidia S., additional, Clark, Kevin B., additional, Zaksiene, Viktoria, additional, Miller, Rob, additional, Grabhamr, Peter, additional, Schisler, Jonathan C, additional, Moraes-vieira, Pedro, additional, Pollett, Simon, additional, Mason, Christopher E., additional, Wurtele, Eve Syrkin, additional, Taylor, Deanne, additional, Schwartz, Robert E., additional, Beheshti, Afshin, additional, Wallace, Douglas C., additional, and Baylin, Stephen B., additional

Published

2023

15. Core mitochondrial genes are down-regulated during SARS-CoV-2 infection of rodent and human hosts

Author

Guarnieri, Joseph W., primary, Dybas, Joseph M., additional, Fazelinia, Hossein, additional, Kim, Man S., additional, Frere, Justin, additional, Zhang, Yuanchao, additional, Soto Albrecht, Yentli, additional, Murdock, Deborah G., additional, Angelin, Alessia, additional, Singh, Larry N., additional, Weiss, Scott L., additional, Best, Sonja M., additional, Lott, Marie T., additional, Zhang, Shiping, additional, Cope, Henry, additional, Zaksas, Victoria, additional, Saravia-Butler, Amanda, additional, Meydan, Cem, additional, Foox, Jonathan, additional, Mozsary, Christopher, additional, Bram, Yaron, additional, Kidane, Yared, additional, Priebe, Waldemar, additional, Emmett, Mark R., additional, Meller, Robert, additional, Demharter, Sam, additional, Stentoft-Hansen, Valdemar, additional, Salvatore, Marco, additional, Galeano, Diego, additional, Enguita, Francisco J., additional, Grabham, Peter, additional, Trovao, Nidia S., additional, Singh, Urminder, additional, Haltom, Jeffrey, additional, Heise, Mark T., additional, Moorman, Nathaniel J., additional, Baxter, Victoria K., additional, Madden, Emily A., additional, Taft-Benz, Sharon A., additional, Anderson, Elizabeth J., additional, Sanders, Wes A., additional, Dickmander, Rebekah J., additional, Baylin, Stephen B., additional, Wurtele, Eve Syrkin, additional, Moraes-Vieira, Pedro M., additional, Taylor, Deanne, additional, Mason, Christopher E., additional, Schisler, Jonathan C., additional, Schwartz, Robert E., additional, Beheshti, Afshin, additional, and Wallace, Douglas C., additional

Published

2023

16. SARS-COV-2 viroporins activate the NLRP3-inflammasome by the mitochondrial permeability transition pore

Author

Guarnieri, Joseph W., primary, Angelin, Alessia, additional, Murdock, Deborah G., additional, Schaefer, Patrick, additional, Portluri, Prasanth, additional, Lie, Timothy, additional, Huang, Jessica, additional, and Wallace, Douglas C., additional

Published

2023

17. SARS-CoV-2 Viroporins Activate The NLRP3-Inflammasome Via The Mitochondrial Permeability Transition Pore

Author

Guarnieri, Joseph W., primary, Angelin, Alessia, additional, Murdock, Deborah G., additional, Portluri, Prasanth, additional, Lie, Timothy, additional, and Wallace, Douglas C., additional

Published

2022

18. Targeted Down Regulation Of Core Mitochondrial Genes During SARS-CoV-2 Infection

Author

Guarnieri, Joseph W., primary, Dybas, Joseph M., additional, Fazelinia, Hossein, additional, Kim, Man S., additional, Frere, Justin, additional, Zhang, Yuanchao, additional, Albrecht, Yentli Soto, additional, Murdock, Deborah G., additional, Angelin, Alessia, additional, Singh, Larry N., additional, Weiss, Scott L., additional, Best, Sonja M., additional, Lott, Marie T., additional, Cope, Henry, additional, Zaksas, Viktorija, additional, Saravia-Butler, Amanda, additional, Meydan, Cem, additional, Foox, Jonathan, additional, Mozsary, Christopher, additional, Kidane, Yared H., additional, Priebe, Waldemar, additional, Emmett, Mark R., additional, Meller, Robert, additional, Singh, Urminder, additional, Bram, Yaron, additional, tenOever, Benjamin R., additional, Heise, Mark T., additional, Moorman, Nathaniel J., additional, Madden, Emily A., additional, Taft-Benz, Sharon A., additional, Anderson, Elizabeth J., additional, Sanders, Wes A., additional, Dickmander, Rebekah J., additional, Baxter, Victoria K., additional, Baylin, Stephen B., additional, Wurtele, Eve Syrkin, additional, Moraes-Vieira, Pedro M., additional, Taylor, Deanne, additional, Mason, Christopher E., additional, Schisler, Jonathan C., additional, Schwartz, Robert E., additional, Beheshti, Afshin, additional, and Wallace, Douglas C., additional

Published

2022

19. Role of miR-2392 in driving SARS-CoV-2 infection

Author

McDonald, J. Tyson, primary, Enguita, Francisco J., additional, Taylor, Deanne, additional, Griffin, Robert J., additional, Priebe, Waldemar, additional, Emmett, Mark R., additional, Sajadi, Mohammad M., additional, Harris, Anthony D., additional, Clement, Jean, additional, Dybas, Joseph M., additional, Aykin-Burns, Nukhet, additional, Guarnieri, Joseph W., additional, Singh, Larry N., additional, Grabham, Peter, additional, Baylin, Stephen B., additional, Yousey, Aliza, additional, Pearson, Andrea N., additional, Corry, Peter M., additional, Saravia-Butler, Amanda, additional, Aunins, Thomas R., additional, Sharma, Sadhana, additional, Nagpal, Prashant, additional, Meydan, Cem, additional, Foox, Jonathan, additional, Mozsary, Christopher, additional, Cerqueira, Bianca, additional, Zaksas, Viktorija, additional, Singh, Urminder, additional, Wurtele, Eve Syrkin, additional, Costes, Sylvain V., additional, Davanzo, Gustavo Gastão, additional, Galeano, Diego, additional, Paccanaro, Alberto, additional, Meinig, Suzanne L., additional, Hagan, Robert S., additional, Bowman, Natalie M., additional, Wolfgang, Matthew C., additional, Altinok, Selin, additional, Sapoval, Nicolae, additional, Treangen, Todd J., additional, Moraes-Vieira, Pedro M., additional, Vanderburg, Charles, additional, Wallace, Douglas C., additional, Schisler, Jonathan C., additional, Mason, Christopher E., additional, Chatterjee, Anushree, additional, Meller, Robert, additional, Beheshti, Afshin, additional, Wallet, Shannon M., additional, Maile, Robert, additional, Mock, Jason R., additional, Torres-Castillo, Jose L., additional, Love, Miriya K., additional, Lovell, Will, additional, Rice, Colleen, additional, Mitchem, Olivia, additional, Burgess, Dominique, additional, Suggs, Jessica, additional, and Jacobs, Jordan, additional

Published

2021

20. Viral and Lipid Regulation of Hepatocyte Signaling Pathways

Author

Guarnieri, Joseph W.

Subjects

Cellular signal transduction, FOS: Biological sciences, Genetics, Cytology, Molecular Biology, digestive system diseases, Liver cells

Abstract

Primary liver cancer is the sixth most common cancer and the third highest cause of cancer-related deaths, globally. Hepatocellular carcinoma (HCC) is the predominate form of primary liver cancer, comprising 75-85% of the cases. Approximately 60% of HCCs are associated with a chronic hepatitis B virus (HBV) infection. Additionally, the increasing number of obese individuals in the United States has been linked to an increase in obesity-associated liver diseases such as non-alcoholic fatty liver disease (NAFLD). In Western countries, the incidence of NAFLD associated HCC is also on the rise and has been linked to 4–22% of HCC. In studies described here, we examined whether localization of the Hepatitis B Virus (HBV) HBx protein with mitochondria affects HBV replication and separately analyzed the interplay of changes in the gut microbiome and the liver transcriptome in the context of NAFLD development. HBx is required for efficient HBV replication and is thought to contribute to the development of HBV-associated HCC. Several studies have shown that a fraction of cytosolic HBx localizes to mitochondria in established cell lines and primary hepatocytes. Numerous studies have shown that HBx localizes to mitochondria and affects mitochondrial physiology. However, prior to our study, it was not known whether HBx affects on mitochondria or on HBV replication requires HBx localization to mitochondria. We now report that HBx localization to mitochondria is associated with efficient HBV replication in HepG2 cells and cultured primary rat hepatocytes. We also show that HBx localization to mitochondria is associated with activating signaling pathways directly or indirectly linked with HBx-induced elevation of cytosolic calcium levels, an essential function of HBx that is also required for HBV replication. Cumulatively, our research suggests that HBx association with mitochondria contributes to efficient HBV replication and is responsible for activating signaling pathways associated with HBx-induced elevation of calcium. NAFLD arises from the accumulation of lipids in hepatocytes, the major cell type of the liver, and the resulting liver inflammation as immune cells enter the liver in response to lipid accumulation. Recently, studies in mice and humans have shown that there are alterations in the composition of the gut microbiome in individuals with NAFLD as compared to healthy individuals. However, the mechanism by which the gut microbiome contributes to NAFLD is unclear. While previous studies characterized microbiome changes during NAFLD development, no previous studies have correlated changes in the gut microbiome with changes in liver gene expression. Feeding mice a high-fat diet (HFD) is a model system for studying obesity and associated metabolic disorders such as NAFLD. We characterized changes in gut bacteria and liver gene expression associated with the development of NAFLD in both male and female mice fed a HFD. We also analyzed the effect of non-fermentable fiber on the development of NAFLD. We analyzed the effect of supplementing the HFD and a standard diet (SD) with non-fermentable fiber on liver lipid content. Our research demonstrated that only SD supplemented with non-fermentable fiber resulted in decreased liver lipid content as compared to HFD, with or without non-fermentable fiber supplementation, and SD without non-fermentable fiber supplementation. While numerous studies have shown positive effects of supplementing diets with fiber, before our study, it was unknown whether supplementing diets with non-fermentable fiber could affect the accumulation of lipids in the liver and, consequently, the development of NAFLD. Our results suggest that fiber content, specifically non-fermentable fiber, in the diet is important in preventing the accumulation of lipids in hepatocytes and the development of NAFLD.

Published

2019

21. Viral and Lipid Regulation of Hepatocyte Signaling Pathways

Author

Guarnieri, Joseph W., primary

22. ZNFX1 functions as a master regulator of epigenetically induced pathogen mimicry and inflammasome signaling in cancer.

Author

Stojanovic L, Abbotts R, Tripathi K, Coon CM, Rajendran S, Abbasi Farid E, Hostetter G, Guarnieri JW, Wallace DC, Liu S, Wan J, Calendo G, Marker R, Gohari Z, Inayatullah MMA, Tiwari VK, Kader T, Santagata S, Drapkin R, Kommoss S, Pfisterer J, Konecny GE, Coopergard R, Issa JJ, Winterhoff BJN, Topper MJ, Sandusky GE, Miller KD, Baylin SB, Nephew KP, and Rassool FV

Abstract

DNA methyltransferase and poly (ADP-ribose) polymerase inhibitors (DNMTis, PARPis) induce a stimulator of interferon genes (STING)-dependent pathogen mimicry response (PMR) in ovarian and other cancers. Here, we showed that combining DNMTis and PARPis upregulates expression of the nucleic-acid sensor NFX1-type zinc finger-containing 1 protein (ZNFX1). ZNFX1 mediated induction of PMR in mitochondria, serving as a gateway for STING-dependent interferon/inflammasome signaling. Loss of ZNFX1 in ovarian cancer cells promoted proliferation and spheroid formation in vitro and tumor growth in vivo. In patient ovarian cancer databases, expression of ZNFX1 was elevated in advanced stage disease, and ZNFX1 expression alone significantly correlated with an increase in overall survival in a phase 3 trial for therapy-resistant ovarian cancer patients receiving bevacizumab in combination with chemotherapy. RNA-sequencing revealed an association between inflammasome signaling through ZNFX1 and abnormal vasculogenesis. Together, this study identified that ZNFX1 as a tumor suppressor that controls PMR signaling through mitochondria and may serve as a biomarker to facilitate personalized therapy in ovarian cancer patients.

Published

2025

23. Methodologies for Mitochondrial Omic Profiling During Spaceflight.

Author

Guarnieri JW, Kim J, Wallace DC, Mason CE, Muratani M, and Beheshti A

Subjects

Humans, Animals, Metabolomics methods, Proteomics methods, Weightlessness, Space Flight, Mitochondria metabolism

Abstract

To be able to understand how spaceflight can affect human biology, there is a need for maximizing the amount of information that can be obtained from experiments flown to space. Recently there has been an influx of data obtained from astronauts through multi-omics approaches based on both governmental and commercial spaceflight missions. In addition to data from humans, mitochondrial specific data is gathered for other experiments from rodents and other organisms that are flown in space. This data has started to universally demonstrate that mitochondrial dysfunction is the key regulator associated with increasing health risks associated with spaceflight. This mitochondrial dysfunction can have influence downstream on immune suppression, inflammation, circadian rhythm issues, and more. Due to the space environment, standard methodologies have to be altered for performing mitochondrial specific analysis and in general sample collection for omics. To perform mitochondrial specific analysis and data collection from samples flown to space we will outline the current sample collection methods, processing of the samples, and specific analysis. Specifically we will highlight the different mitochondrial methodologies and challenges involved with research associated with spaceflight., (© 2025. The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.)

Published

2025

24. ZNFX1 is a Novel Master Regulator in Epigenetically-induced Pathogen Mimicry and Inflammasome Signaling in Cancer.

Author

Stojanovic L, Abbotts R, Tripathi K, Coon CM, Rajendran S, Farid EA, Hostetter G, Guarnieri JW, Wallace DC, Liu S, Wan J, Calendo G, Marker R, Gohari Z, Inayatullah MMA, Tiwari VK, Kader T, Santagata S, Drapkin R, Kommoss S, Pfisterer J, Konecny GE, Coopergard R, Issa JP, Winterhoff BJN, Topper MJ, Sandusky GE, Miller KD, Baylin SB, Nephew KP, and Rassool FV

Abstract

DNA methyltransferase and poly(ADP-ribose) polymerase inhibitors (DNMTis, PARPis) induce a stimulator of interferon (IFN) genes (STING)-dependent pathogen mimicry response (PMR) in ovarian (OC) and other cancers. We now show that combining DNMTis and PARPis upregulates expression of a little-studied nucleic-acid sensor, NFX1-type zinc finger-containing 1 protein (ZNFX1). We demonstrate that ZNFX1 is a novel master regulator for PMR induction in mitochondria, serving as a gateway for STING-dependent PMR. In patient OC databases, high ZNFX1 expression levels correlate with advanced stage disease. ZNFX1 expression alone significantly correlates with an increase in overall survival in a phase 3 trial for therapy-resistant OC patients receiving bevacizumab in combination with chemotherapy. In correlative RNA-seq data, inflammasome signaling through ZNFX1 correlates with abnormal vasculogenesis. ZNFX1 controls PMR signaling through the mitochondria and may serve as a biomarker to facilitate offering personalized therapy in OC patients, highlighting the strong translational significance of our findings., Competing Interests: Disclosure of Conflicts of Interest F.V.R. and S.B.B. share co-inventorship on US Provisional Patent Application Number: 61/929,680 for the concept of the combinatorial therapy. The opinions expressed in this article are the author’s own and do not reflect the view of the National Institutes of Health, the Department of Health and Human Services, or the United States government. All other authors declare no potential conflicts of interest.

Published

2024

25. Mitochondrial Hyperactivity and Reactive Oxygen Species Drive Innate Immunity to the Yellow Fever Virus-17D Live-Attenuated Vaccine.

Author

Muccilli SG, Schwarz B, Jessop F, Shannon JG, Bohrnsen E, Shue B, Hong SH, Hsu T, Ashbrook AW, Guarnieri JW, Lack J, Wallace DC, Bosio CM, MacDonald MR, Rice CM, Yewdell JW, and Best SM

Abstract

The yellow fever virus 17D (YFV-17D) live attenuated vaccine is considered one of the successful vaccines ever generated associated with high antiviral immunity, yet the signaling mechanisms that drive the response in infected cells are not understood. Here, we provide a molecular understanding of how metabolic stress and innate immune responses are linked to drive type I IFN expression in response to YFV-17D infection. Comparison of YFV-17D replication with its parental virus, YFV-Asibi, and a related dengue virus revealed that IFN expression requires RIG-I-like Receptor signaling through MAVS, as expected. However, YFV-17D uniquely induces mitochondrial respiration and major metabolic perturbations, including hyperactivation of electron transport to fuel ATP synthase. Mitochondrial hyperactivity generates reactive oxygen species (mROS) and peroxynitrite, blocking of which abrogated IFN expression in non-immune cells without reducing YFV-17D replication. Scavenging ROS in YFV-17D-infected human dendritic cells increased cell viability yet globally prevented expression of IFN signaling pathways. Thus, adaptation of YFV-17D for high growth uniquely imparts mitochondrial hyperactivity generating mROS and peroxynitrite as the critical messengers that convert a blunted IFN response into maximal activation of innate immunity essential for vaccine effectiveness., Competing Interests: Declaration of Interests The authors declare no competing interests.

Published

2024

26. TARGETED DOWN REGULATION OF CORE MITOCHONDRIAL GENES DURING SARS-COV-2 INFECTION.

Author

Guarnieri JW, Dybas JM, Fazelinia H, Kim MS, Frere J, Zhang Y, Albrecht YS, Murdock DG, Angelin A, Singh LN, Weiss SL, Best SM, Lott MT, Cope H, Zaksas V, Saravia-Butler A, Meydan C, Foox J, Mozsary C, Kidane YH, Priebe W, Emmett MR, Meller R, Singh U, Bram Y, tenOever BR, Heise MT, Moorman NJ, Madden EA, Taft-Benz SA, Anderson EJ, Sanders WA, Dickmander RJ, Baxter VK, Baylin SB, Wurtele ES, Moraes-Vieira PM, Taylor D, Mason CE, Schisler JC, Schwartz RE, Beheshti A, and Wallace DC

Abstract

Defects in mitochondrial oxidative phosphorylation (OXPHOS) have been reported in COVID-19 patients, but the timing and organs affected vary among reports. Here, we reveal the dynamics of COVID-19 through transcription profiles in nasopharyngeal and autopsy samples from patients and infected rodent models. While mitochondrial bioenergetics is repressed in the viral nasopharyngeal portal of entry, it is up regulated in autopsy lung tissues from deceased patients. In most disease stages and organs, discrete OXPHOS functions are blocked by the virus, and this is countered by the host broadly up regulating unblocked OXPHOS functions. No such rebound is seen in autopsy heart, results in severe repression of genes across all OXPHOS modules. Hence, targeted enhancement of mitochondrial gene expression may mitigate the pathogenesis of COVID-19.

Published

2022

27. The Great Deceiver: miR-2392's Hidden Role in Driving SARS-CoV-2 Infection.

Author

McDonald JT, Enguita FJ, Taylor D, Griffin RJ, Priebe W, Emmett MR, Sajadi MM, Harris AD, Clement J, Dybas JM, Aykin-Burns N, Guarnieri JW, Singh LN, Grabham P, Baylin SB, Yousey A, Pearson AN, Corry PM, Saravia-Butler A, Aunins TR, Sharma S, Nagpal P, Meydan C, Foox J, Mozsary C, Cerqueira B, Zaksas V, Singh U, Wurtele ES, Costes SV, Davanzo GG, Galeano D, Paccanaro A, Meinig SL, Hagan RS, Bowman NM, Wolfgang MC, Altinok S, Sapoval N, Treangen TJ, Moraes-Vieira PM, Vanderburg C, Wallace DC, Schisler J, Mason CE, Chatterjee A, Meller R, and Beheshti A

Abstract

MicroRNAs (miRNAs) are small non-coding RNAs involved in post-transcriptional gene regulation that have a major impact on many diseases and provides an exciting avenue towards antiviral therapeutics. From patient transcriptomic data, we have discovered a circulating miRNA, miR-2392, that is directly involved with SARS-CoV-2 machinery during host infection. Specifically, we show that miR-2392 is key in driving downstream suppression of mitochondrial gene expression, increasing inflammation, glycolysis, and hypoxia as well as promoting many symptoms associated with COVID-19 infection. We demonstrate miR-2392 is present in the blood and urine of COVID-19 positive patients, but not detected in COVID-19 negative patients. These findings indicate the potential for developing a novel, minimally invasive, COVID-19 detection method. Lastly, using in vitro human and in vivo hamster models, we have developed a novel miRNA-based antiviral therapeutic that targets miR-2392, significantly reduces SARS-CoV-2 viability in hamsters and may potentially inhibit a COVID-19 disease state in humans.

Published

2021