Your search keyword '"Christopher E. Mason"' showing total 27 results

1. Detection and genetic characterization of multidrug-resistant staphylococci isolated from public areas in an international airport

Author

Dewa A.P. Rasmika Dewi, Hazim O. Khalifa, Haque Khandar, Junzo Hisatsune, Shoko Kutuno, Liansheng Yu, Wataru Hayashi, Shizuo Kayama, Christopher E. Mason, Motoyuki Sugai, Haruo Suzuki, and Tetsuya Matsumoto

Subjects

Methicillin-resistant staphylococci, mecA gene, LA-MRSA, Whole genome sequencing, Public areas, International airport, Medicine, Science

Abstract

Abstract The environmental realm has been acknowledged as a pivotal arena for the emergence and propagation of antimicrobial resistance. To further explore insight into antimicrobial resistance dynamics beyond clinical and veterinary settings, we embarked on an environmental surveillance initiative targeting the prevalence of antibiotic-resistant bacteria within the bustling confines of an international airport in Japan. Our findings illuminate a high prevalence of methicillin-resistant staphylococci (46.3%) on frequently contacted surfaces in the public domain. Notably, Staphylococcus haemolyticus and S. epidermidis emerged as the preeminent carriers of the mecA gene. Intriguingly, we encountered a virulent strain of livestock-associated MRSA harboring a PVL-positive ST1232 clone, CC398 lineage. Further scrutiny unveiled a repertoire of resistance mechanisms, the methicillin-resistant isolates exhibited two or more resistance genes conferring resistance against different types of antibiotics, including beta-lactams, macrolides, lincosamides, aminoglycosides, chloramphenicol, and fosfomycin. Revealing multidrug-resistant CoNS and a LA-MRSA across various surfaces in urban public areas unearths a looming public health hazard. Thus, implementation of molecular surveillance is imperative, augmenting our capacity for early detection and mitigation of the insidious spread and potential transfer of antibiotic resistance genes and virulence factors amidst urban settings, notably within pivotal nodes such as airports.

Published

2024

2. Diverse and specialized metabolic capabilities of microbes in oligotrophic built environments

Author

Xinzhao Tong, Danli Luo, Marcus H. Y. Leung, Justin Y. Y. Lee, Zhiyong Shen, Wengyao Jiang, Christopher E. Mason, and Patrick K. H. Lee

Subjects

Built environment, Metabolic capabilities, Oligotrophic conditions, Metagenome-assembled genomes, Microbial ecology, QR100-130

Abstract

Abstract Background Built environments (BEs) are typically considered to be oligotrophic and harsh environments for microbial communities under normal, non-damp conditions. However, the metabolic functions of microbial inhabitants in BEs remain poorly understood. This study aimed to shed light on the functional capabilities of microbes in BEs by analyzing 860 representative metagenome-assembled genomes (rMAGs) reconstructed from 738 samples collected from BEs across the city of Hong Kong and from the skin surfaces of human occupants. The study specifically focused on the metabolic functions of rMAGs that are either phylogenetically novel or prevalent in BEs. Results The diversity and composition of BE microbiomes were primarily shaped by the sample type, with Micrococcus luteus and Cutibacterium acnes being prevalent. The metabolic functions of rMAGs varied significantly based on taxonomy, even at the strain level. A novel strain affiliated with the Candidatus class Xenobia in the Candidatus phylum Eremiobacterota and two novel strains affiliated with the superphylum Patescibacteria exhibited unique functions compared with their close relatives, potentially aiding their survival in BEs and on human skins. The novel strains in the class Xenobia possessed genes for transporting nitrate and nitrite as nitrogen sources and nitrosative stress mitigation induced by nitric oxide during denitrification. The two novel Patescibacteria strains both possessed a broad array of genes for amino acid and trace element transport, while one of them carried genes for carotenoid and ubiquinone biosynthesis. The globally prevalent M. luteus in BEs displayed a large and open pangenome, with high infraspecific genomic diversity contributed by 11 conspecific strains recovered from BEs in a single geographic region. The versatile metabolic functions encoded in the large accessory genomes of M. luteus may contribute to its global ubiquity and specialization in BEs. Conclusions This study illustrates that the microbial inhabitants of BEs possess metabolic potentials that enable them to tolerate and counter different biotic and abiotic conditions. Additionally, these microbes can efficiently utilize various limited residual resources from occupant activities, potentially enhancing their survival and persistence within BEs. A better understanding of the metabolic functions of BE microbes will ultimately facilitate the development of strategies to create a healthy indoor microbiome. Video Abstract

Published

2024

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

Author

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

Subjects

Biology (General), QH301-705.5

Abstract

Abstract In the era of renewed space exploration, comprehending the effects of the space environment on human health, particularly for deep space missions, is crucial. While extensive research exists on the impacts of spaceflight, there is a gap regarding female reproductive risks. We hypothesize that space stressors could have enduring effects on female health, potentially increasing risks for future pregnancies upon return to Earth, particularly related to small-for-gestational-age (SGA) fetuses. To address this, we identify a shared microRNA (miRNA) signature between SGA and the space environment, conserved across humans and mice. These miRNAs target genes and pathways relevant to diseases and development. Employing a machine learning approach, we identify potential FDA-approved drugs to mitigate these risks, including estrogen and progesterone receptor antagonists, vitamin D receptor antagonists, and DNA polymerase inhibitors. This study underscores potential pregnancy-related health risks for female astronauts and proposes pharmaceutical interventions to counteract the impact of space travel on female health.

Published

2024

4. Towards geospatially-resolved public-health surveillance via wastewater sequencing

Author

Braden T. Tierney, Jonathan Foox, Krista A. Ryon, Daniel Butler, Namita Damle, Benjamin G. Young, Christopher Mozsary, Kristina M. Babler, Xue Yin, Yamina Carattini, David Andrews, Alexander G. Lucaci, Natasha Schaefer Solle, Naresh Kumar, Bhavarth Shukla, Dušica Vidović, Benjamin Currall, Sion L. Williams, Stephan C. Schürer, Mario Stevenson, Ayaaz Amirali, Cynthia Campos Beaver, Erin Kobetz, Melinda M. Boone, Brian Reding, Jennifer Laine, Samuel Comerford, Walter E. Lamar, John J. Tallon, Jeremy Wain Hirschberg, Jacqueline Proszynski, Gabriel Al Ghalith, Kübra Can Kurt, Mark E. Sharkey, George M. Church, George S. Grills, Helena M. Solo-Gabriele, and Christopher E. Mason

Subjects

Science

Abstract

Abstract Wastewater is a geospatially- and temporally-linked microbial fingerprint of a given population, making it a potentially valuable tool for tracking public health across locales and time. Here, we integrate targeted and bulk RNA sequencing (N = 2238 samples) to track the viral, bacterial, and functional content over geospatially distinct areas within Miami Dade County, USA, from 2020-2022. We used targeted amplicon sequencing to track diverse SARS-CoV-2 variants across space and time, and we found a tight correspondence with positive PCR tests from University students and Miami-Dade hospital patients. Additionally, in bulk metatranscriptomic data, we demonstrate that the bacterial content of different wastewater sampling locations serving small population sizes can be used to detect putative, host-derived microorganisms that themselves have known associations with human health and diet. We also detect multiple enteric pathogens (e.g., Norovirus) and characterize viral diversity across sites. Moreover, we observed an enrichment of antimicrobial resistance genes (ARGs) in hospital wastewater; antibiotic-specific ARGs correlated to total prescriptions of those same antibiotics (e.g Ampicillin, Gentamicin). Overall, this effort lays the groundwork for systematic characterization of wastewater that can potentially influence public health decision-making.

Published

2024

5. Targeted DNA-seq and RNA-seq of Reference Samples with Short-read and Long-read Sequencing

Author

Binsheng Gong, Dan Li, Paweł P. Łabaj, Bohu Pan, Natalia Novoradovskaya, Danielle Thierry-Mieg, Jean Thierry-Mieg, Guangchun Chen, Anne Bergstrom Lucas, Jennifer S. LoCoco, Todd A. Richmond, Elizabeth Tseng, Rebecca Kusko, Scott Happe, Timothy R. Mercer, Carlos Pabón-Peña, Michael Salmans, Hagen U. Tilgner, Wenzhong Xiao, Donald J. Johann, Wendell Jones, Weida Tong, Christopher E. Mason, David P. Kreil, and Joshua Xu

Subjects

Science

Abstract

Abstract Next-generation sequencing (NGS) has revolutionized genomic research by enabling high-throughput, cost-effective genome and transcriptome sequencing accelerating personalized medicine for complex diseases, including cancer. Whole genome/transcriptome sequencing (WGS/WTS) provides comprehensive insights, while targeted sequencing is more cost-effective and sensitive. In comparison to short-read sequencing, which still dominates the field due to high speed and cost-effectiveness, long-read sequencing can overcome alignment limitations and better discriminate similar sequences from alternative transcripts or repetitive regions. Hybrid sequencing combines the best strengths of different technologies for a more comprehensive view of genomic/transcriptomic variations. Understanding each technology’s strengths and limitations is critical for translating cutting-edge technologies into clinical applications. In this study, we sequenced DNA and RNA libraries of reference samples using various targeted DNA and RNA panels and the whole transcriptome on both short-read and long-read platforms. This study design enables a comprehensive analysis of sequencing technologies, targeting protocols, and library preparation methods. Our expanded profiling landscape establishes a reference point for assessing current sequencing technologies, facilitating informed decision-making in genomic research and precision medicine.

Published

2024

6. Protective alleles and precision healthcare in crewed spaceflight

Author

Lindsay A. Rutter, Matthew J. MacKay, Henry Cope, Nathaniel J. Szewczyk, JangKeun Kim, Eliah Overbey, Braden T. Tierney, Masafumi Muratani, Ben Lamm, Daniela Bezdan, Amber M. Paul, Michael A. Schmidt, George M. Church, Stefania Giacomello, and Christopher E. Mason

Subjects

Science

Abstract

Abstract Common and rare alleles are now being annotated across millions of human genomes, and omics technologies are increasingly being used to develop health and treatment recommendations. However, these alleles have not yet been systematically characterized relative to aerospace medicine. Here, we review published alleles naturally found in human cohorts that have a likely protective effect, which is linked to decreased cancer risk and improved bone, muscular, and cardiovascular health. Although some technical and ethical challenges remain, research into these protective mechanisms could translate into improved nutrition, exercise, and health recommendations for crew members during deep space missions.

Published

2024

7. Aging and putative frailty biomarkers are altered by spaceflight

Author

Andrea Camera, Marshall Tabetah, Veronica Castañeda, JangKeun Kim, Aman Singh Galsinh, Alissen Haro-Vinueza, Ivonne Salinas, Allen Seylani, Shehbeel Arif, Saswati Das, Marcelo A. Mori, Anthony Carano, Lorraine Christine de Oliveira, Masafumi Muratani, Richard Barker, Victoria Zaksas, Chirag Goel, Eleni Dimokidis, Deanne M. Taylor, Jisu Jeong, Eliah Overbey, Cem Meydan, D. Marshall Porterfield, Juan Esteban Díaz, Andrés Caicedo, Jonathan C. Schisler, Evagelia C. Laiakis, Christopher E. Mason, Man S. Kim, Fathi Karouia, Nathaniel J. Szewczyk, and Afshin Beheshti

Subjects

Medicine, Science

Abstract

Abstract Human space exploration poses inherent risks to astronauts’ health, leading to molecular changes that can significantly impact their well-being. These alterations encompass genomic instability, mitochondrial dysfunction, increased inflammation, homeostatic dysregulation, and various epigenomic changes. Remarkably, these changes bear similarities to those observed during the aging process on Earth. However, our understanding of the connection between these molecular shifts and disease development in space remains limited. Frailty syndrome, a clinical syndrome associated with biological aging, has not been comprehensively investigated during spaceflight. To bridge this knowledge gap, we leveraged murine data obtained from NASA’s GeneLab, along with astronaut data gathered from the JAXA and Inspiration4 missions. Our objective was to assess the presence of biological markers and pathways related to frailty, aging, and sarcopenia within the spaceflight context. Through our analysis, we identified notable changes in gene expression patterns that may be indicative of the development of a frailty-like condition during space missions. These findings suggest that the parallels between spaceflight and the aging process may extend to encompass frailty as well. Consequently, further investigations exploring the utility of a frailty index in monitoring astronaut health appear to be warranted.

Published

2024

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

Author

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

Subjects

Science

Abstract

Abstract As spaceflight becomes more common with commercial crews, blood-based measures of crew health can guide both astronaut biomedicine and countermeasures. By profiling plasma proteins, metabolites, and extracellular vesicles/particles (EVPs) from the SpaceX Inspiration4 crew, we generated “spaceflight secretome profiles,” which showed significant differences in coagulation, oxidative stress, and brain-enriched proteins. While >93% of differentially abundant proteins (DAPs) in vesicles and metabolites recovered within six months, the majority (73%) of plasma DAPs were still perturbed post-flight. Moreover, these proteomic alterations correlated better with peripheral blood mononuclear cells than whole blood, suggesting that immune cells contribute more DAPs than erythrocytes. Finally, to discern possible mechanisms leading to brain-enriched protein detection and blood-brain barrier (BBB) disruption, we examined protein changes in dissected brains of spaceflight mice, which showed increases in PECAM-1, a marker of BBB integrity. These data highlight how even short-duration spaceflight can disrupt human and murine physiology and identify spaceflight biomarkers that can guide countermeasure development.

Published

2024

9. Direct RNA sequencing of astronaut blood reveals spaceflight-associated m6A increases and hematopoietic transcriptional responses

Author

Kirill Grigorev, Theodore M. Nelson, Eliah G. Overbey, Nadia Houerbi, JangKeun Kim, Deena Najjar, Namita Damle, Evan E. Afshin, Krista A. Ryon, Jean Thierry-Mieg, Danielle Thierry-Mieg, Ari M. Melnick, Jaime Mateus, and Christopher E. Mason

Subjects

Science

Abstract

Abstract The advent of civilian spaceflight challenges scientists to precisely describe the effects of spaceflight on human physiology, particularly at the molecular and cellular level. Newer, nanopore-based sequencing technologies can quantitatively map changes in chemical structure and expression at single molecule resolution across entire isoforms. We perform long-read, direct RNA nanopore sequencing, as well as Ultima high-coverage RNA-sequencing, of whole blood sampled longitudinally from four SpaceX Inspiration4 astronauts at seven timepoints, spanning pre-flight, day of return, and post-flight recovery. We report key genetic pathways, including changes in erythrocyte regulation, stress induction, and immune changes affected by spaceflight. We also present the first m6A methylation profiles for a human space mission, suggesting a significant spike in m6A levels immediately post-flight. These data and results represent the first longitudinal long-read RNA profiles and RNA modification maps for each gene for astronauts, improving our understanding of the human transcriptome’s dynamic response to spaceflight.

Published

2024

10. Spatial multi-omics of human skin reveals KRAS and inflammatory responses to spaceflight

Author

Jiwoon Park, Eliah G. Overbey, S. Anand Narayanan, JangKeun Kim, Braden T. Tierney, Namita Damle, Deena Najjar, Krista A. Ryon, Jacqueline Proszynski, Ashley Kleinman, Jeremy Wain Hirschberg, Matthew MacKay, Evan E. Afshin, Richard Granstein, Justin Gurvitch, Briana M. Hudson, Aric Rininger, Sean Mullane, Sarah E. Church, Cem Meydan, George Church, Afshin Beheshti, Jaime Mateus, and Christopher E. Mason

Subjects

Science

Abstract

Abstract Spaceflight can change metabolic, immunological, and biological homeostasis and cause skin rashes and irritation, yet the molecular basis remains unclear. To investigate the impact of short-duration spaceflight on the skin, we conducted skin biopsies on the Inspiration4 crew members before (L-44) and after (R + 1) flight. Leveraging multi-omics assays including GeoMx™ Digital Spatial Profiler, single-cell RNA/ATAC-seq, and metagenomics/metatranscriptomics, we assessed spatial gene expressions and associated microbial and immune changes across 95 skin regions in four compartments: outer epidermis, inner epidermis, outer dermis, and vasculature. Post-flight samples showed significant up-regulation of genes related to inflammation and KRAS signaling across all skin regions. These spaceflight-associated changes mapped to specific cellular responses, including altered interferon responses, DNA damage, epithelial barrier disruptions, T-cell migration, and hindered regeneration were located primarily in outer tissue compartments. We also linked epithelial disruption to microbial shifts in skin swab and immune cell activity to PBMC single-cell data from the same crew and timepoints. Our findings present the inaugural collection and examination of astronaut skin, offering insights for future space missions and response countermeasures.

Published

2024

11. Spatiotemporal expression and control of haemoglobin in space

Author

Josef Borg, Conor Loy, JangKeun Kim, Alfred Buhagiar, Christopher Chin, Namita Damle, Iwijn De Vlaminck, Alex Felice, Tammy Liu, Irina Matei, Cem Meydan, Masafumi Muratani, Omary Mzava, Eliah Overbey, Krista A. Ryon, Scott M. Smith, Braden T. Tierney, Guy Trudel, Sara R. Zwart, Afshin Beheshti, Christopher E. Mason, and Joseph Borg

Subjects

Science

Abstract

Abstract It is now widely recognised that the environment in space activates a diverse set of genes involved in regulating fundamental cellular pathways. This includes the activation of genes associated with blood homeostasis and erythropoiesis, with a particular emphasis on those involved in globin chain production. Haemoglobin biology provides an intriguing model for studying space omics, as it has been extensively explored at multiple -omic levels, spanning DNA, RNA, and protein analyses, in both experimental and clinical contexts. In this study, we examined the developmental expression of haemoglobin over time and space using a unique suite of multi-omic datasets available on NASA GeneLab, from the NASA Twins Study, the JAXA CFE study, and the Inspiration4 mission. Our findings reveal significant variations in globin gene expression corresponding to the distinct spatiotemporal characteristics of the collected samples. This study sheds light on the dynamic nature of globin gene regulation in response to the space environment and provides valuable insights into the broader implications of space omics research.

Published

2024

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

Author

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

Subjects

Science

Abstract

Abstract Our previous research revealed a key microRNA signature that is associated with spaceflight that can be used as a biomarker and to develop countermeasure treatments to mitigate the damage caused by space radiation. Here, we expand on this work to determine the biological factors rescued by the countermeasure treatment. We performed RNA-sequencing and transcriptomic analysis on 3D microvessel cell cultures exposed to simulated deep space radiation (0.5 Gy of Galactic Cosmic Radiation) with and without the antagonists to three microRNAs: miR-16-5p, miR-125b-5p, and let-7a-5p (i.e., antagomirs). Significant reduction of inflammation and DNA double strand breaks (DSBs) activity and rescue of mitochondria functions are observed after antagomir treatment. Using data from astronaut participants in the NASA Twin Study, Inspiration4, and JAXA missions, we reveal the genes and pathways implicated in the action of these antagomirs are altered in humans. Our findings indicate a countermeasure strategy that can potentially be utilized by astronauts in spaceflight missions to mitigate space radiation damage.

Published

2024

13. Single-cell analysis identifies conserved features of immune dysfunction in simulated microgravity and spaceflight

Author

Fei Wu, Huixun Du, Eliah Overbey, JangKeun Kim, Priya Makhijani, Nicolas Martin, Chad A. Lerner, Khiem Nguyen, Jordan Baechle, Taylor R. Valentino, Matias Fuentealba, Juliet M. Bartleson, Heather Halaweh, Shawn Winer, Cem Meydan, Francine Garrett-Bakelman, Nazish Sayed, Simon Melov, Masafumi Muratani, Akos A. Gerencser, Herbert G. Kasler, Afshin Beheshti, Christopher E. Mason, David Furman, and Daniel A. Winer

Subjects

Science

Abstract

Abstract Microgravity is associated with immunological dysfunction, though the mechanisms are poorly understood. Here, using single-cell analysis of human peripheral blood mononuclear cells (PBMCs) exposed to short term (25 hours) simulated microgravity, we characterize altered genes and pathways at basal and stimulated states with a Toll-like Receptor-7/8 agonist. We validate single-cell analysis by RNA sequencing and super-resolution microscopy, and against data from the Inspiration-4 (I4) mission, JAXA (Cell-Free Epigenome) mission, Twins study, and spleens from mice on the International Space Station. Overall, microgravity alters specific pathways for optimal immunity, including the cytoskeleton, interferon signaling, pyroptosis, temperature-shock, innate inflammation (e.g., Coronavirus pathogenesis pathway and IL-6 signaling), nuclear receptors, and sirtuin signaling. Microgravity directs monocyte inflammatory parameters, and impairs T cell and NK cell functionality. Using machine learning, we identify numerous compounds linking microgravity to immune cell transcription, and demonstrate that the flavonol, quercetin, can reverse most abnormal pathways. These results define immune cell alterations in microgravity, and provide opportunities for countermeasures to maintain normal immunity in space.

Published

2024

14. Ethical considerations for the age of non-governmental space exploration

Author

Allen Seylani, Aman Singh Galsinh, Alexia Tasoula, Anu R I, Andrea Camera, Jean Calleja-Agius, Joseph Borg, Chirag Goel, JangKeun Kim, Kevin B. Clark, Saswati Das, Shehbeel Arif, Michael Boerrigter, Caroline Coffey, Nathaniel Szewczyk, Christopher E. Mason, Maria Manoli, Fathi Karouia, Hansjörg Schwertz, Afshin Beheshti, and Dana Tulodziecki

Subjects

Science

Abstract

Abstract Mounting ambitions and capabilities for public and private, non-government sector crewed space exploration bring with them an increasingly diverse set of space travelers, raising new and nontrivial ethical, legal, and medical policy and practice concerns which are still relatively underexplored. In this piece, we lay out several pressing issues related to ethical considerations for selecting space travelers and conducting human subject research on them, especially in the context of non-governmental and commercial/private space operations.

Published

2024

15. Single-cell multi-ome and immune profiles of the Inspiration4 crew reveal conserved, cell-type, and sex-specific responses to spaceflight

Author

JangKeun Kim, Braden T. Tierney, Eliah G. Overbey, Ezequiel Dantas, Matias Fuentealba, Jiwoon Park, S. Anand Narayanan, Fei Wu, Deena Najjar, Christopher R. Chin, Cem Meydan, Conor Loy, Begum Mathyk, Remi Klotz, Veronica Ortiz, Khiem Nguyen, Krista A. Ryon, Namita Damle, Nadia Houerbi, Laura I. Patras, Nathan Schanzer, Gwyneth A. Hutchinson, Jonathan Foox, Chandrima Bhattacharya, Matthew Mackay, Evan E. Afshin, Jeremy Wain Hirschberg, Ashley S. Kleinman, Julian C. Schmidt, Caleb M. Schmidt, Michael A. Schmidt, Afshin Beheshti, Irina Matei, David Lyden, Sean Mullane, Amran Asadi, Joan S. Lenz, Omary Mzava, Min Yu, Saravanan Ganesan, Iwijn De Vlaminck, Ari M. Melnick, Darko Barisic, Daniel A. Winer, Sara R. Zwart, Brian E. Crucian, Scott M. Smith, Jaime Mateus, David Furman, and Christopher E. Mason

Subjects

Science

Abstract

Abstract Spaceflight induces an immune response in astronauts. To better characterize this effect, we generated single-cell, multi-ome, cell-free RNA (cfRNA), biochemical, and hematology data for the SpaceX Inspiration4 (I4) mission crew. We found that 18 cytokines/chemokines related to inflammation, aging, and muscle homeostasis changed after spaceflight. In I4 single-cell multi-omics data, we identified a “spaceflight signature” of gene expression characterized by enrichment in oxidative phosphorylation, UV response, immune function, and TCF21 pathways. We confirmed the presence of this signature in independent datasets, including the NASA Twins Study, the I4 skin spatial transcriptomics, and 817 NASA GeneLab mouse transcriptomes. Finally, we observed that (1) T cells showed an up-regulation of FOXP3, (2) MHC class I genes exhibited long-term suppression, and (3) infection-related immune pathways were associated with microbiome shifts. In summary, this study reveals conserved and distinct immune disruptions occurring and details a roadmap for potential countermeasures to preserve astronaut health.

Published

2024

16. Astronaut omics and the impact of space on the human body at scale

Author

Lindsay A. Rutter, Henry Cope, Matthew J. MacKay, Raúl Herranz, Saswati Das, Sergey A. Ponomarev, Sylvain V. Costes, Amber M. Paul, Richard Barker, Deanne M. Taylor, Daniela Bezdan, Nathaniel J. Szewczyk, Masafumi Muratani, Christopher E. Mason, and Stefania Giacomello

Subjects

Science

Abstract

Abstract Future multi-year crewed planetary missions will motivate advances in aerospace nutrition and telehealth. On Earth, the Human Cell Atlas project aims to spatially map all cell types in the human body. Here, we propose that a parallel Human Cell Space Atlas could serve as an openly available, global resource for space life science research. As humanity becomes increasingly spacefaring, high-resolution omics on orbit could permit an advent of precision spaceflight healthcare. Alongside the scientific potential, we consider the complex ethical, cultural, and legal challenges intrinsic to the human space omics discipline, and how philosophical frameworks may benefit from international perspectives.

Published

2024

17. Collection of biospecimens from the inspiration4 mission establishes the standards for the space omics and medical atlas (SOMA)

Author

Eliah G. Overbey, Krista Ryon, JangKeun Kim, Braden T. Tierney, Remi Klotz, Veronica Ortiz, Sean Mullane, Julian C. Schmidt, Matthew MacKay, Namita Damle, Deena Najjar, Irina Matei, Laura Patras, J. Sebastian Garcia Medina, Ashley S. Kleinman, Jeremy Wain Hirschberg, Jacqueline Proszynski, S. Anand Narayanan, Caleb M. Schmidt, Evan E. Afshin, Lucinda Innes, Mateo Mejia Saldarriaga, Michael A. Schmidt, Richard D. Granstein, Bader Shirah, Min Yu, David Lyden, Jaime Mateus, and Christopher E. Mason

Subjects

Science

Abstract

Abstract The SpaceX Inspiration4 mission provided a unique opportunity to study the impact of spaceflight on the human body. Biospecimen samples were collected from four crew members longitudinally before (Launch: L-92, L-44, L-3 days), during (Flight Day: FD1, FD2, FD3), and after (Return: R + 1, R + 45, R + 82, R + 194 days) spaceflight, spanning a total of 289 days across 2021-2022. The collection process included venous whole blood, capillary dried blood spot cards, saliva, urine, stool, body swabs, capsule swabs, SpaceX Dragon capsule HEPA filter, and skin biopsies. Venous whole blood was further processed to obtain aliquots of serum, plasma, extracellular vesicles and particles, and peripheral blood mononuclear cells. In total, 2,911 sample aliquots were shipped to our central lab at Weill Cornell Medicine for downstream assays and biobanking. This paper provides an overview of the extensive biospecimen collection and highlights their processing procedures and long-term biobanking techniques, facilitating future molecular tests and evaluations.As such, this study details a robust framework for obtaining and preserving high-quality human, microbial, and environmental samples for aerospace medicine in the Space Omics and Medical Atlas (SOMA) initiative, which can aid future human spaceflight and space biology experiments.

Published

2024

18. Cosmic kidney disease: an integrated pan-omic, physiological and morphological study into spaceflight-induced renal dysfunction

Author

Keith Siew, Kevin A. Nestler, Charlotte Nelson, Viola D’Ambrosio, Chutong Zhong, Zhongwang Li, Alessandra Grillo, Elizabeth R. Wan, Vaksha Patel, Eliah Overbey, JangKeun Kim, Sanghee Yun, Michael B. Vaughan, Chris Cheshire, Laura Cubitt, Jessica Broni-Tabi, Maneera Yousef Al-Jaber, Valery Boyko, Cem Meydan, Peter Barker, Shehbeel Arif, Fatemeh Afsari, Noah Allen, Mohammed Al-Maadheed, Selin Altinok, Nourdine Bah, Samuel Border, Amanda L. Brown, Keith Burling, Margareth Cheng-Campbell, Lorianna M. Colón, Lovorka Degoricija, Nichola Figg, Rebecca Finch, Jonathan Foox, Pouya Faridi, Alison French, Samrawit Gebre, Peter Gordon, Nadia Houerbi, Hossein Valipour Kahrood, Frederico C. Kiffer, Aleksandra S. Klosinska, Angela Kubik, Han-Chung Lee, Yinghui Li, Nicholas Lucarelli, Anthony L. Marullo, Irina Matei, Colleen M. McCann, Sayat Mimar, Ahmed Naglah, Jérôme Nicod, Kevin M. O’Shaughnessy, Lorraine Christine De Oliveira, Leah Oswalt, Laura Ioana Patras, San-huei Lai Polo, María Rodríguez-Lopez, Candice Roufosse, Omid Sadeghi-Alavijeh, Rebekah Sanchez-Hodge, Anindya S. Paul, Ralf Bernd Schittenhelm, Annalise Schweickart, Ryan T. Scott, Terry Chin Choy Lim Kam Sian, Willian A. da Silveira, Hubert Slawinski, Daniel Snell, Julio Sosa, Amanda M. Saravia-Butler, Marshall Tabetah, Erwin Tanuwidjaya, Simon Walker-Samuel, Xiaoping Yang, Yasmin, Haijian Zhang, Jasminka Godovac-Zimmermann, Pinaki Sarder, Lauren M. Sanders, Sylvain V. Costes, Robert A. A. Campbell, Fathi Karouia, Vidya Mohamed-Alis, Samuel Rodriques, Steven Lynham, Joel Ricky Steele, Sergio Baranzini, Hossein Fazelinia, Zhongquan Dai, Akira Uruno, Dai Shiba, Masayuki Yamamoto, Eduardo A.C.Almeida, Elizabeth Blaber, Jonathan C. Schisler, Amelia J. Eisch, Masafumi Muratani, Sara R. Zwart, Scott M. Smith, Jonathan M. Galazka, Christopher E. Mason, Afshin Beheshti, and Stephen B. Walsh

Subjects

Science

Abstract

Abstract Missions into Deep Space are planned this decade. Yet the health consequences of exposure to microgravity and galactic cosmic radiation (GCR) over years-long missions on indispensable visceral organs such as the kidney are largely unexplored. We performed biomolecular (epigenomic, transcriptomic, proteomic, epiproteomic, metabolomic, metagenomic), clinical chemistry (electrolytes, endocrinology, biochemistry) and morphometry (histology, 3D imaging, miRNA-ISH, tissue weights) analyses using samples and datasets available from 11 spaceflight-exposed mouse and 5 human, 1 simulated microgravity rat and 4 simulated GCR-exposed mouse missions. We found that spaceflight induces: 1) renal transporter dephosphorylation which may indicate astronauts’ increased risk of nephrolithiasis is in part a primary renal phenomenon rather than solely a secondary consequence of bone loss; 2) remodelling of the nephron that results in expansion of distal convoluted tubule size but loss of overall tubule density; 3) renal damage and dysfunction when exposed to a Mars roundtrip dose-equivalent of simulated GCR.

Published

2024

19. Spaceflight induces changes in gene expression profiles linked to insulin and estrogen

Author

Begum Aydogan Mathyk, Marshall Tabetah, Rashid Karim, Victoria Zaksas, JangKeun Kim, R. I. Anu, Masafumi Muratani, Alexia Tasoula, Ruth Subhash Singh, Yen-Kai Chen, Eliah Overbey, Jiwoon Park, Henry Cope, Hossein Fazelinia, Davide Povero, Joseph Borg, Remi V. Klotz, Min Yu, Steven L. Young, Christopher E. Mason, Nathaniel Szewczyk, Riley M. St Clair, Fathi Karouia, and Afshin Beheshti

Subjects

Biology (General), QH301-705.5

Abstract

Abstract Organismal adaptations to spaceflight have been characterized at the molecular level in model organisms, including Drosophila and C. elegans. Here, we extend molecular work to energy metabolism and sex hormone signaling in mice and humans. We found spaceflight induced changes in insulin and estrogen signaling in rodents and humans. Murine changes were most prominent in the liver, where we observed inhibition of insulin and estrogen receptor signaling with concomitant hepatic insulin resistance and steatosis. Based on the metabolic demand, metabolic pathways mediated by insulin and estrogen vary among muscles, specifically between the soleus and extensor digitorum longus. In humans, spaceflight induced changes in insulin and estrogen related genes and pathways. Pathway analysis demonstrated spaceflight induced changes in insulin resistance, estrogen signaling, stress response, and viral infection. These data strongly suggest the need for further research on the metabolic and reproductive endocrinologic effects of space travel, if we are to become a successful interplanetary species.

Published

2024

20. Telomeric RNA (TERRA) increases in response to spaceflight and high-altitude climbing

Author

Taghreed M. Al-Turki, David G. Maranon, Christopher B. Nelson, Aidan M. Lewis, Jared J. Luxton, Lynn E. Taylor, Noelia Altina, Fei Wu, Huixun Du, JangKeun Kim, Namita Damle, Eliah Overbey, Cem Meydan, Kirill Grigorev, Daniel A. Winer, David Furman, Christopher E. Mason, and Susan M. Bailey

Subjects

Biology (General), QH301-705.5

Abstract

Abstract Telomeres are repetitive nucleoprotein complexes at chromosomal termini essential for maintaining genome stability. Telomeric RNA, or TERRA, is a previously presumed long noncoding RNA of heterogeneous lengths that contributes to end-capping structure and function, and facilitates telomeric recombination in tumors that maintain telomere length via the telomerase-independent Alternative Lengthening of Telomeres (ALT) pathway. Here, we investigated TERRA in the radiation-induced DNA damage response (DDR) across astronauts, high-altitude climbers, healthy donors, and cellular models. Similar to astronauts in the space radiation environment and climbers of Mt. Everest, in vitro radiation exposure prompted increased transcription of TERRA, while simulated microgravity did not. Data suggest a specific TERRA DDR to telomeric double-strand breaks (DSBs), and provide direct demonstration of hybridized TERRA at telomere-specific DSB sites, indicative of protective TERRA:telomeric DNA hybrid formation. Targeted telomeric DSBs also resulted in accumulation of TERRA foci in G2-phase, supportive of TERRA’s role in facilitating recombination-mediated telomere elongation. Results have important implications for scenarios involving persistent telomeric DNA damage, such as those associated with chronic oxidative stress (e.g., aging, systemic inflammation, environmental and occupational radiation exposures), which can trigger transient ALT in normal human cells, as well as for targeting TERRA as a therapeutic strategy against ALT-positive tumors.

Published

2024

21. Transcriptomics analysis reveals molecular alterations underpinning spaceflight dermatology

Author

Henry Cope, Jonas Elsborg, Samuel Demharter, J. Tyson McDonald, Chiara Wernecke, Hari Parthasarathy, Hriday Unadkat, Mira Chatrathi, Jennifer Claudio, Sigrid Reinsch, Pinar Avci, Sara R. Zwart, Scott M. Smith, Martina Heer, Masafumi Muratani, Cem Meydan, Eliah Overbey, Jangkeun Kim, Christopher R. Chin, Jiwoon Park, Jonathan C. Schisler, Christopher E. Mason, Nathaniel J. Szewczyk, Craig R. G. Willis, Amr Salam, and Afshin Beheshti

Subjects

Medicine

Abstract

Abstract Background Spaceflight poses a unique set of challenges to humans and the hostile spaceflight environment can induce a wide range of increased health risks, including dermatological issues. The biology driving the frequency of skin issues in astronauts is currently not well understood. Methods To address this issue, we used a systems biology approach utilizing NASA’s Open Science Data Repository (OSDR) on space flown murine transcriptomic datasets focused on the skin, biochemical profiles of 50 NASA astronauts and human transcriptomic datasets generated from blood and hair samples of JAXA astronauts, as well as blood samples obtained from the NASA Twins Study, and skin and blood samples from the first civilian commercial mission, Inspiration4. Results Key biological changes related to skin health, DNA damage & repair, and mitochondrial dysregulation are identified as potential drivers for skin health risks during spaceflight. Additionally, a machine learning model is utilized to determine gene pairings associated with spaceflight response in the skin. While we identified spaceflight-induced dysregulation, such as alterations in genes associated with skin barrier function and collagen formation, our results also highlight the remarkable ability for organisms to re-adapt back to Earth via post-flight re-tuning of gene expression. Conclusion Our findings can guide future research on developing countermeasures for mitigating spaceflight-associated skin damage.

Published

2024

22. Genomic and morphological characterization of Knufia obscura isolated from the Mars 2020 spacecraft assembly facility

Author

Atul Munish Chander, Marcus de Melo Teixeira, Nitin K. Singh, Michael P. Williams, Ceth W. Parker, Patrick Leo, Jason E. Stajich, Tamas Torok, Scott Tighe, Christopher E. Mason, and Kasthuri Venkateswaran

Subjects

Black fungi, Extremophile, Trichomeriaceae, Chaetothyriales, Genomics, Medicine, Science

Abstract

Abstract Members of the family Trichomeriaceae, belonging to the Chaetothyriales order and the Ascomycota phylum, are known for their capability to inhabit hostile environments characterized by extreme temperatures, oligotrophic conditions, drought, or presence of toxic compounds. The genus Knufia encompasses many polyextremophilic species. In this report, the genomic and morphological features of the strain FJI-L2-BK-P2 presented, which was isolated from the Mars 2020 mission spacecraft assembly facility located at the Jet Propulsion Laboratory in Pasadena, California. The identification is based on sequence alignment for marker genes, multi-locus sequence analysis, and whole genome sequence phylogeny. The morphological features were studied using a diverse range of microscopic techniques (bright field, phase contrast, differential interference contrast and scanning electron microscopy). The phylogenetic marker genes of the strain FJI-L2-BK-P2 exhibited highest similarities with type strain of Knufia obscura (CBS 148926T) that was isolated from the gas tank of a car in Italy. To validate the species identity, whole genomes of both strains (FJI-L2-BK-P2 and CBS 148926T) were sequenced, annotated, and strain FJI-L2-BK-P2 was confirmed as K. obscura. The morphological analysis and description of the genomic characteristics of K. obscura FJI-L2-BK-P2 may contribute to refining the taxonomy of Knufia species. Key morphological features are reported in this K. obscura strain, resembling microsclerotia and chlamydospore-like propagules. These features known to be characteristic features in black fungi which could potentially facilitate their adaptation to harsh environments.

Published

2024

23. Inspiration4 data access through the NASA Open Science Data Repository

Author

Lauren M. Sanders, Kirill A. Grigorev, Ryan T. Scott, Amanda M. Saravia-Butler, San-huei Lai Polo, Rachel Gilbert, Eliah G. Overbey, JangKeun Kim, Christopher E. Mason, and Sylvain V. Costes

Subjects

Biotechnology, TP248.13-248.65, Physiology, QP1-981

Abstract

Abstract The increasing accessibility of commercial and private space travel necessitates a profound understanding of its impact on human health. The NASA Open Science Data Repository (OSDR) provides transparent and FAIR access to biological studies, notably the SpaceX Inspiration4 (I4) mission, which amassed extensive data from civilian astronauts. This dataset encompasses omics and clinical assays, facilitating comprehensive research on space-induced biological responses. These data allow for multi-modal, longitudinal assessments, bridging the gap between human and model organism studies. Crucially, community-driven data standards established by NASA’s OSDR Analysis Working Groups empower artificial intelligence and machine learning to glean invaluable insights, guiding future mission planning and health risk mitigation. This article presents a concise guide to access and analyze I4 data in OSDR, including programmatic access through GLOpenAPI. This pioneering effort establishes a precedent for post-mission health monitoring programs within space agencies, propelling research in the burgeoning field of commercial space travel’s impact on human physiology.

Published

2024

24. Loss of CREBBP and KMT2D cooperate to accelerate lymphomagenesis and shape the lymphoma immune microenvironment

Author

Jie Li, Christopher R. Chin, Hsia-Yuan Ying, Cem Meydan, Matthew R. Teater, Min Xia, Pedro Farinha, Katsuyoshi Takata, Chi-Shuen Chu, Yiyue Jiang, Jenna Eagles, Verena Passerini, Zhanyun Tang, Martin A. Rivas, Oliver Weigert, Trevor J. Pugh, Amy Chadburn, Christian Steidl, David W. Scott, Robert G. Roeder, Christopher E. Mason, Roberta Zappasodi, Wendy Béguelin, and Ari M. Melnick

Subjects

Science

Abstract

Abstract Despite regulating overlapping gene enhancers and pathways, CREBBP and KMT2D mutations recurrently co-occur in germinal center (GC) B cell-derived lymphomas, suggesting potential oncogenic cooperation. Herein, we report that combined haploinsufficiency of Crebbp and Kmt2d induces a more severe mouse lymphoma phenotype (vs either allele alone) and unexpectedly confers an immune evasive microenvironment manifesting as CD8+ T-cell exhaustion and reduced infiltration. This is linked to profound repression of immune synapse genes that mediate crosstalk with T-cells, resulting in aberrant GC B cell fate decisions. From the epigenetic perspective, we observe interaction and mutually dependent binding and function of CREBBP and KMT2D on chromatin. Their combined deficiency preferentially impairs activation of immune synapse-responsive super-enhancers, pointing to a particular dependency for both co-activators at these specialized regulatory elements. Together, our data provide an example where chromatin modifier mutations cooperatively shape and induce an immune-evasive microenvironment to facilitate lymphomagenesis.

Published

2024

25. Enhanced astronaut hygiene and mission efficiency: a novel approach to in-suit waste management and water recovery in spacewalks

Author

Sofia Etlin, Luca Bielski, Julianna Rose, Karen Morales, Avery Belman, Emma Alexander, Emma Li, Richard Lin, Krishna Patel, Stephanie Rakhmonova, Claire Walter, and Christopher E. Mason

Subjects

space medical capabilities, space, medical technical devices, technology, innovation, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

The current waste management system within the Extravehicular Mobility Unit (EMU) consists of a disposable diaper—the Maximum Absorbency Garment (MAG)—that collects urine and feces during extravehicular activities (EVAs) that last up to 8 h. Such exposure to waste for prolonged periods of time contributes to hygiene-related medical events, including urinary tract infections and gastrointestinal distress. Historically, prior to using the MAG, astronauts have limited their food intake or eaten a low-residue diet before embarking on physically demanding spacewalks, reducing their work performance index (WPI) and posing a health risk. Furthermore, the current 0.95 L In-suit Drink Bag (IDB) does not provide sufficient water for more frequent, longer-range spacewalks, which carry greater potential for contingency scenarios requiring extended time away from a vehicle. High transport costs per pound to space and resource scarcity exacerbate these challenges, underscoring the need for water-efficient waste management. This paper introduces a novel in-suit urine collection and filtration system developed in the Mason Lab at Weill Cornell Medical College that could address these hygiene and hydration concerns. The device would collect astronaut urine via an external catheter and filter it using forward and reverse osmosis (FO-RO) into potable water, creating a sustainable and hygienic circular water economy, enhancing astronaut wellbeing. This research aims to achieve an 85% urine collection rate using a modified MAG. The modified MAG will be made of a flexible compression material lined with antimicrobial fabric, and urine is collected through a silicone urine collection cup, which differs for male and female astronauts to conform to anatomy. Urine collection via a vacuum pump is triggered by a humidity sensor that detects the presence of urine in the cup. The FO-RO filtration system targets a minimum of 75% water recovery, while consuming less than 10% of EMU energy. To meet health standards, the filtrate maintains low salt levels (

Published

2024

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

Author

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

Subjects

Biology (General), QH301-705.5

Published

2024

27. A Multiomics, Molecular Atlas of Breast Cancer Survivors

Author

Brent A. Bauer, Caleb M. Schmidt, Kathryn J. Ruddy, Janet E. Olson, Cem Meydan, Julian C. Schmidt, Sheena Y. Smith, Fergus J. Couch, John C. Earls, Nathan D. Price, Joel T. Dudley, Christopher E. Mason, Bodi Zhang, Stephen M. Phipps, and Michael A. Schmidt

Subjects

breast cancer survivors, breast cancer, multiomics, genomics, metagenomics, metabolomics, Microbiology, QR1-502

Abstract

Breast cancer imposes a significant burden globally. While the survival rate is steadily improving, much remains to be elucidated. This observational, single time point, multiomic study utilizing genomics, proteomics, targeted and untargeted metabolomics, and metagenomics in a breast cancer survivor (BCS) and age-matched healthy control cohort (N = 100) provides deep molecular phenotyping of breast cancer survivors. In this study, the BCS cohort had significantly higher polygenic risk scores for breast cancer than the control group. Carnitine and hexanoyl carnitine were significantly different. Several bile acid and fatty acid metabolites were significantly dissimilar, most notably the Omega-3 Index (O3I) (significantly lower in BCS). Proteomic and metagenomic analyses identified group and pathway differences, which warrant further investigation. The database built from this study contributes a wealth of data on breast cancer survivorship where there has been a paucity, affording the ability to identify patterns and novel insights that can drive new hypotheses and inform future research. Expansion of this database in the treatment-naïve, newly diagnosed, controlling for treatment confounders, and through the disease progression, can be leveraged to profile and contextualize breast cancer and breast cancer survivorship, potentially leading to the development of new strategies to combat this disease and improve the quality of life for its victims.

Published

2024