Genetics and Environmental Mutagenesis Society 34th Annual Fall Meeting Mitochondrial DNA Mutagenesis and Human Health Impacts Wednesday, November 9, 2016 NC Biotechnology Center 15 T.W. Alexander Drive Durham, NC 27703 Supported in part by grants from CONTENTS Cover Page --------------------------------------------------------------------------------------- 1 2015 GEMS Officers---------------------------------------------------------------------------- 2 President’s Message --------------------------------------------------------------------------- 3 Program Agenda -------------------------------------------------------------------------------- 4 Bio-sketches and Abstracts of Invited Speakers ----------------------------------------- 5-6 Invited Talks Abstracts------------------------------------------------------------------------- 7-8 Short Talk Abstracts ---------------------------------------------------------------------------- 9-10 Poster Abstracts --------------------------------------------------------------------------------- 11-23 GEMS Sponsors -------------------------------------------------------------------------------- 24-28 GEMS WEBSITE (URL) and Notes--------------------------------------------------------- 29-30 2016 GEMS Officers President 2015-2016 Councilors: 2014-2016 Councilors: 2015-2017 Councilors: 2016-2018 Stephanie L. Smith-Roe George Woodall Michelle Campbell Nagalakshmi (Nagu) Keshava NTP at NIEHS US EPA NIEHS US EPA [email protected] [email protected] [email protected] [email protected] [email protected] President -Elect (2015-2016) Erin P. Hines Jenna Guynn Brian N. Chorley Nancy M. Hanley US EPA RJ Reynolds US EPA US EPA [email protected] [email protected] [email protected] [email protected] [email protected] Janice Lee Caren Weinhouse Secretary (2014-2016) US EPA Duke University Holly Mortensen Jennifer Nichols [email protected] [email protected] US EPA US EPA [email protected] [email protected] Corporate Sponsor [email protected] Carol Swartz Treasurer (2014-2016) ILS, Inc. John E. (Jef) French [email protected] NIEHS (ret.) [email protected] Ex Officio Member Thomas Hughes US EPA (ret.) [email protected] www.gems-nc.org 2 | P age PRESIDENT'S MESSAGE th Welcome to the 34 Annual GEMS Fall Meeting! Brian Chorley, Ph.D., President-Elect and Program Chair, has built an exceptional program around the theme of “Mitochondrial DNA Mutagenesis and Human Health Impacts.” For the Spring Meeting, Brian proposed and took on the monumental task of coordinating the first GEMS meeting to feature the ever increasing importance of science communication and outreach. Among many notable features of this meeting, Nobel laureate Oliver Smithies, Ph.D., gave an enthralling and inspirational talk on his scientific journey, attendees heard encouraging messages from several distinguished speakers to share their science with the public, and it was also the first time that high school students interested in pursuing scientific careers were invited to attend a GEMS meeting. Brian has also been dedicated to other aspects of strengthening the Society. GEMS is truly fortuitous to have had such a committed, enthusiastic, and energetic person to serve as President-Elect, and there is no doubt in my mind that Brian will be a legendary GEMS President. It has been an honor and a privilege to serve as the President of GEMS. During my tenure as President-Elect for GEMS, I had also served as a Councilor appointed to the Executive Board of the Environmental Mutagenesis and Genomics Society (EMGS). During that time, I learned a lot about the nuts and bolts that go into running a society. My goal as President was to apply what I had learned by promoting the implementation of an integrated membership management software system to streamline GEMS operations. Among other advantages, GEMS now has an information-rich website that includes a secure, online payment system for membership dues and meeting registration fees, with invoices for every transaction. It has never been easier to join GEMS and maintain membership, and members have the option of creating a profile. GEMS has only begun to tap into the potential of this system. I’m excited to see how it will be used by future Boards to boost networking and career development opportunities for area scientists, to enhance the community within GEMS, and to promote interaction between GEMS and other scientific organizations in the RTP. GEMS is a non-profit organization and we are indebted to our sponsors for their support of the Fall Meeting. We have benefited from the generous financial assistance of the NIEHS, the Burroughs Wellcome Fund, and many corporate sponsors. Please visit with company representatives during the meeting; they are here today to equip us with materials that can help us to do our work with greater speed and success! GEMS was founded in the spirit of providing early career scientists and staff scientists with opportunities to showcase their work. Thank you to the talented and dedicated trainees and technicians who have shared their work today with the GEMS community. GEMS offers the opportunity to compete for the Best Talk Award, sponsored by a generous contribution from Mr. Tom Hughes, GEMS Past President. The awardee will also receive the EMGS Emerging Scientist Award. These awards provide support for the recipient to attend the 2017 EMGS Annual Meeting, which will be held in Raleigh. Poster presenters will compete for First, Second, and Third prizes, kindly sponsored by the Burroughs Wellcome Fund, which is committed to enhancing the professional development of early career scientists. In addition to providing a venue for early career scientists to shine and to hone their networking skills, GEMS celebrates the accomplishments and service of scientists who have advanced further in their careers with the Lifetime Achievement Award. There are many deserving candidates for this award, and this year, we had some catching up to do! Please congratulate Jack Bishop, Ph.D., John (Jef) French, Ph.D., RoseAnne McGee, B.S., and Kristine Witt, M.S. for their outstanding scientific contributions and for their exemplary dedication to GEMS. Please see the GEMS website to learn more about the award and to read inspiring interviews given by the Lifetime Achievement awardees. Running GEMS and putting on two meetings a year is a team effort! I have greatly enjoyed working with a truly delightful and dedicated Board of Directors. Please join me in thanking Holly Mortensen (Secretary), Jef French (Treasurer), Brian Chorley (President-Elect) and Councilors Michelle Campbell, Jenna Currier, Nagu Keshava, Janice Lee, Nancy Hanley, Erin Hines, Jennifer Nichols, Caren Weinhouse, and George Woodall for their many contributions. Carol Swartz, our Corporate Sponsor Coordinator, Kristine Witt, who has coordinated procuring our GEMS awards and mementos, and Carolyn Harris, who has for many years maintained our membership records, also deserve our recognition and thanks for their constant and much appreciated efforts. Please welcome our new Board of Directors members, including Holly Mortensen (President-Elect), Nisha Sipes (Secretary), Lisa Smeester (Treasurer), and Councilors Tom Hughes, Natalia Ryan (née Van Duyn), and Catherine Sprankle. I and many others have found our involvement with GEMS to be a greatly rewarding experience and I strongly encourage members to get involved by running for office. Last but not least, another way to get involved is to serve as a judge for the poster and platform competitions, and I would like to thank the volunteers who make the competitions possible! GEMS is a truly unique and vibrant society, nurtured by the outstanding scientific talent here in the RTP and surrounding areas. The continued success of the Society depends on the active support of members. Thank you for your support and enjoy the meeting! Stephanie L. Smith-Roe, Ph.D. GEMS President, 2015 - 2016 www.gems-nc.org 3 | P age AGENDA Mitochondrial DNA Mutagenesis and Human Health Impacts 8:00 - 8:45 a.m. Registration and Continental Breakfast 8:45 – 9:00 a.m. Welcome Stephanie Smith-Roe, Ph.D., President Brian Chorley, Ph.D., President-Elect 9:00 – 9:45 a.m. The Role of DNA Polymerase Gamma in Mitochondrial DNA Mutagenesis William C. Copeland, Ph.D., NIEHS, RTP, NC 9:45 – 10:30 a.m. Therapeutics for Mitochondrial DNA Instability Sherine S.L. Chan, Ph.D., Medical University of South Carolina, Charleston, SC 10:30 – 12:00 p.m. Poster Session and Sponsor Exhibits 10:30 – 11:15: Odd posters attended 11:15 – 12:00: Even posters attended 12:00 – 1:15 p.m. Lunch (provided with registration) Lifetime Achievement Awards Business Meeting 1:15 – 2:00 p.m. Mitochondria as a Target of Environmental Toxicants Joel N. Meyer, Ph.D., Duke University, Durham, NC 2:00 – 2:45 p.m. Trainee Platform Presentations 2:00 – 2:15: Axel J. Berky, Duke University, Durham, NC 2:15 – 2:30: Kirsten C. Verhein, NIEHS, RTP, NC 2:30 – 2:45: Colette N. Miller, US EPA, RTP, NC 2:45 – 3:15 p.m. Break (beverages and snacks) 3:15 – 4:00 p.m. Mitochondrial Regulation of the Epigenome and Transcriptome Janine H. Santos, Ph.D., NIEHS, RTP, NC 4:00 – 4:30 p.m. Awards and Closing Remarks; Adjourn at 4:30 p.m. www.gems-nc.org 4 | P age MEET OUR INVITED SPEAKERS William C. Copeland, Ph.D. Chief, Genome Integrity and Structural Biology Laboratory and Principal Investigator, Mitochondrial DNA Replication Group, Genomic Integrity and Structural Biology Laboratory, National Institute of Environmental Health Sciences, NIH, Research Triangle Park, North Carolina, 27709 I received my Ph.D. in chemistry/biochemistry from the University of Texas at Austin in 1988 under the supervision of Dr. Jon Robertus studying histidine decarboxylase. I then completed my postdoctoral training at Stanford University School of Medicine, Department of Pathology with Dr. Teresa Wang, studying the human DNA polymerase alpha/primase complex. In 1993, I joined the National Institutes of Environmental Health Sciences, NIH, in Research Triangle Park, NC and am currently the head of the Mitochondrial DNA Replication Group in the Genome Integrity and Structural Biology Laboratory within the Intramural Research Division. I am also the Chief of the Genome Integrity and Structural Biology department at the NIEHS. The primary goal of the Mitochondrial DNA Replication Group is to understand the role of the replication apparatus in the production and prevention of mutations in mtDNA. Because the genetic stability of mtDNA depends on the accuracy of DNA polymerase gamma (pol γ), this project focuses on understanding the role of human pol γ in mtDNA mutagenesis. Furthermore, nearly 300 disease mutations in the POLG gene for the catalytic subunit of pol γ have been linked to several mitochondrial disorders, including progressive external ophthalmoplegia, sensory and ataxic neuropathy, Alpers syndrome, and male infertility. We are studying the molecular effects of disease mutations in pol γ, its accessory subunit and the mitochondrial DNA helicase. The current projects address the role of human pol γ in mtDNA mutagenesis; study of the molecular effects of disease mutations in pol γ; and are elucidating the role of the human pol γ in induced mitochondrial toxicity caused by anti-HIV nucleoside analogs. My group has over 20 years of experience in research of mitochondrial DNA replication and this group has pioneered the characterization of the human DNA polymerase complex. Sherine S. L. Chan, Ph.D. Associate Professor, Drug Discovery and Biomedical Sciences, College of Pharmacy, Medical University of South Carolina, Charleston, SC 29425 I have been in the mitochondrial field since 1996. I first worked with Dr. Jim Cummins at Murdoch University, Australia, investigating the roles of mitochondrial DNA (mtDNA) mutagenesis in male infertility. Later, I joined Dr. Bill Copeland’s laboratory at NIEHS/NIH in Research Triangle Park, NC, where I focused on mtDNA-related mitochondrial diseases using in vitro biochemistry, studies of mitochondrial disease patient cells, and in vivo mouse models of mitochondrial dysfunction. I started my lab at the Medical University of South Carolina in 2009, where we have developed new zebrafish models of mitochondrial dysfunction that recapitulate human disease. These models are now used for studying disease progression, drug discovery and for toxicology studies. We have developed many new assays for studying mitochondrial dysfunction in vivo in the zebrafish. We are focused on understanding certain tissues are more susceptible to mtDNA instability, and how common environmental exposures modulate disease outcome. The long-term goal of my laboratory at the Medical University of South Carolina is to manipulate the mechanisms required to maintain mitochondrial homeostasis to prevent or treat mitochondrial dysfunction. I am also the Co-Founder of Neuroene Therapeutics, a startup drug discovery company based on new non-toxic compounds that improve mitochondrial health. www.gems-nc.org 5 | P age Joel N. Meyer, Ph.D. Associate Professor, Nicholas School of the Environment, Integrated Toxicology and Environmental Health Program, Duke Cancer Institute Duke University Durham, NC 27708 Dr. Meyer received a B.S. from Juniata College in 1992 (Environmental Studies, Peace and Conflict Studies), and then moved to Guatemala where he worked in a number of fields including appropriate technology and high school teaching. Working with cookstoves and water pollution led to an interest in environmental health, and he earned a Ph.D. in Environmental Toxicology from Duke University in 2003. This led to an interest in toxic effects on mitochondria and DNA and postdoctoral research with Dr. Bennett Van Houten at NIEHS (2003 to 2006). Dr. Meyer joined the Nicholas School of the Environment at Duke University in 2007. He is currently an associate professor at the Nicholas School of the Environment, faculty member of the Integrated Toxicology and Environmental Health Program and the Duke Cancer Institute, and has a secondary appointment in Duke Civil and Environmental Engineering. His group studies the effects of pollutants on health, with a particular focus on mitochondria and DNA and how the effects of pollutant exposures are different when exposures occur early in life, or in the context of genetic differences. His group studies these effects using the nematode model organism Caenorhabditis elegans, cell culture, and collaboratively in samples from people, fish, and other species. Janine H. Santos, Ph.D. Mammalian Genome Group, Genomic Integrity and Structural Biology National Institute of Environmental Health Sciences, NIH Research Triangle Park, North Carolina, 27709 Janine H. Santos received her Ph.D. in Genetics and Molecular Biology from the Federal University of Rio Grande do Sul in Porto Alegre, Brazil. During her Ph.D. studies. Dr. Santos worked on Genetic Toxicology using Drosophila melanogaster as a model system to understand the effects of dietary compounds under conditions of genotoxic stress. She then moved to NC for her post-doctoral fellowship at NIEHS to work on mitochondrial DNA metabolism. In 2006, Dr. Santos became faculty at the New Jersey Medical School and in 2013 returned to NIEHS. Her current line of research involves defining the impact of mitochondrial metabolism to the epigenome and transcriptome in order to better understand the effects of environmental agents that target this organelle. www.gems-nc.org 6 | P age ABSTRACTS Invited Talks Gene-Environment Interactions and mitochondrial DNA mutagenesis in POLG Diseases William C Copeland, Ph.D. Mitochondrial DNA Replication Group, Genomic Integrity and Structural Biology Laboratory, National Institute of Environmental Health Sciences, NIH, Research Triangle Park, North Carolina, 27709. Mitochondrial DNA (mtDNA) is replicated by DNA polymerase gamma which is composed of three subunits encoded by two genes: POLG encoding the catalytic subunit (p140) and POLG2 encoding the homodimeric accessory subunit (p55). Mutations in POLG are one of the most common causes of mitochondrial disorders and give rise to mtDNA depletion, deletions and point mutations. To date, there are nearly 300 disease mutations in POLG that are linked to mitochondrial diseases such as myocerebrohepatopathy, Alpers-Huttenlocher syndrome, myoclonic epilepsy myopathy sensory ataxia, ataxia neuropathy spectrum and progressive external ophthalmoplegia (PEO). Mutations in POLG2 and the Twinkle helicase have also been shown to cause PEO and similar disorders. Using biochemical analysis, structural modeling, yeast genetics and mouse models, we are determining the consequences of disease mutations in POLG, POLG2, and the Twinkle helicase. Whereas documenting the biochemical defects of POLG, POLG2, and Twinkle disease variants in vitro can be straightforward, predicting the age of phenotypic onset for POLG related diseases can be more challenging. Indeed, large differences in age of onset can occur in people bearing the same POLG mutations, indicating the existence of confounding factors beyond more obvious biochemical defects. To better address these discrepancies, we are investigating environmental modulators of disease variants, and we have identified unique gene- environment interactions with certain POLG disease mutations that sensitize mtDNA to enhanced mutagenesis. We have also developed model systems with cultured cells to monitor the sub-cellular localization of disease variant proteins and their effects on cellular bioenergetics. Therapeutics for Mitochondrial DNA Instability Sherine S. L. Chan, Ph.D. Drug Discovery and Biomedical Sciences, College of Pharmacy, Medical University of South Carolina, Charleston, SC 29425. Mitochondrial dysfunction is an important contributor to many common human diseases. A key component that is often affected and leads to disease states is mitochondrial DNA (mtDNA) stability. A recent study showed that 90% of currently healthy humans harbor at least one mutation in their mtDNA, and 20% harbor a pathogenic mtDNA mutation. Normal mtDNA replication is an important source of mutation, and more than 2% of the population carries a pathogenic mutation in nuclear-encoded mtDNA maintenance genes. Furthermore, we have a poor understanding of why certain tissues are more affected than others, and there is a lack of relevant animal models that can be used both for understanding disease pathogenesis and progression, as well as for toxicology and drug discovery. Because of these issues, we still do not have effective treatments for mtDNA instability. My lab has developed and validated new and unique zebrafish models of mtDNA instability that we are now using for drug discovery. These genetic models show that severe depletion of mtDNA and the presence of deletions precede alterations in energetics, and that there are tissue-specific differences for both parameters that recapitulate the human condition. We are screening compounds that improve mtDNA stability in vivo, and are developing active compounds as novel therapies for mitochondrial disease. www.gems-nc.org 7 | P age Roles of mitochondrial fusion, fission, and autophagy in response to environmental mitotoxicants Joel N Meyer, Ph.D. Nicholas School of the Environment, faculty member of the Integrated Toxicology & Environmental Health Program and the Duke Cancer Institute, Duke University, Durham, NC 27708-0328. Many mitochondrial homeostasis genes are human disease genes, and deficiencies in these genes may sensitize to exposures. Mitochondrial DNA (mtDNA) lacks some repair pathways that are present in the nucleus, such that damage formed after exposure to important genotoxins including ultraviolet C (UVC) radiation and some polycyclic aromatic hydrocarbons is not repaired in mtDNA. We found that while persistent, such irreparable damage is slowly removed in a process dependent at least in part on mitochondrial fusion, fission, and autophagy. Furthermore, deficiencies in these processes sensitive the model organisms Caenorhabditis elegans to exposures that generate irreparable mtDNA damage. This may have implications for human health, because these processes are dependent on proteins encoded by human disease genes, and are also modulated by lifestyle factors such as diet and exercise. Mutations in mitochondrial fusion, fission and autophagy genes exacerbate the toxic effects of other environmental and pharmaceutical agents, not all of which are genotoxic, including arsenic, cisplatin, rotenone, and paraquat. Others have reported that inhibition of mitochondrial dynamics affects transmission of mtDNA mutations. Finally, we have found that in some cases, developmental exposures to mitochondrial toxicants can result in lifelong and heritable (to offspring) alterations in mitochondrial function. Metabolomic data suggest that this occurs as a result of persistent diversion of metabolic intermediates towards protection against mitochondrial oxidative stress, a model that we are currently testing. Overall, our results suggest a potent gene- environment interaction in which the effects of mtDNA damage are exacerbated by decreased mitochondrial homeostasis. Mitochondrial regulation of the epigenome and transcriptome Janine H. Santos, Ph.D. Genome Integrity and Structural Biology, Biostatistics and Bioinformatics Branch, National Institute of Environmental Health Sciences, National Institutes of Health, Durham, NC 27709. Mitochondria are well-recognized for their role in ATP and reactive oxygen species generation, in addition to producing intermediate metabolites through the TCA (tricarboxylic acid) cycle. The crosstalk between metabolism and epigenetic modifications in the nucleus is becoming increasingly evident but the extent to which mitochondrial metabolites are required for these effects remains largely unknown. We recently showed using a cell culture model of acute mitochondrial DNA (mtDNA) depletion that electron flow sustains a functional oxidative TCA cycle, which in turn is necessary to maintain histone acetylation in the nucleus. Following this work, we have interrogated the degree of gene expression changes associated with modulation in histone acetylation and in DNA methylation driven by mitochondrial dysfunction. Results will be discussed in light of our recent findings. www.gems-nc.org 8 | P age ABSTRACTS Short Talks T1 Epidemiological Survey on Mitochondrial DNA Copy Number and Mitochondrial DNA Damage in the Peruvian Amazon Axel J. Berky2, Ian T. Ryde2, Ernesto J. Ortiz1, Beth J. Feingold3, Heileen Hsu-Kim2,4, Joel N. Meyer2, William K. Pan1,2 1Duke Global Health Institute, Duke University, Durham, NC 27710; 2Nicholas School of the Environment, Duke University, Durham, NC 27708; 3University of Albany, School of Public Health, Albany, NY 12114; 4Duke Pratt School of Engineering, Duke University, Durham, NC 27708 The purpose of the study is to determine the impact of Hg exposure, nutrition and health behaviors on mitochondrial DNA copy number (mtDNA CN) and mitochondrial DNA (mtDNA) damage in peripheral white blood cells (n = 85 participants) in indigenous and non-indigenous communities in the Peruvian Amazon. Nine communities along the Madre de Dios River in Southeastern Peru were sampled in 2014 for mercury in hair, hemoglobin, anthropometry, mtDNA damage and mtDNA CN. Three communities are rural and located in pristine jungle in the river’s headwaters upriver from artisanal gold mining (the putative source of mercury exposure), three are urban communities located downriver from artisanal gold mining, while the last three are rural communities located far downriver near the Peruvian border with Bolivia. Households in each community were selected randomly and invited to participate in the study until four houses were enrolled. mtDNA lesions were measured by quantitative long-range PCR, which measures any damage that inhibits the DNA polymerase used in the assay. Copy number was measured using real-time PCR. mtDNA CN was not associated with total Hg exposure in hair, but was positively associated with vegetable consumption (p<0.06). mtDNA damage was significantly associated with mercury exposure when considering fruit consumption in random effects models. Being obese led to 0.2 fewer lesion/10kb (p<0.018). To our knowledge, this is the first study done in the Peruvian Amazon in which indigenous and non-indigenous communities have well-quantified mercury exposure and detailed information for other mitochondrial health risk factors. T2 Inter-Strain Variation in Mouse Mitochondrial Genome and Effects of Oxidative Stress Kirsten C. Verhein1, Adam Burkholder2, Jennifer Nichols1, Zachary McCaw1, Jacqui Marzec1, Wesley Gladwell1, Nicole Reeves3, Jason Malphurs3, Greg Solomon3, Tim Wiltshire4, David Fargo2, Bennett Van Houten5, Steven R. Kleeberger1 1Immunity, Inflammation & Disease Laboratory, 2Integrative Bioinformatics Support Group, 3Epigenetics & Stem Cell Laboratory, National Institute of Environmental Health Sciences, RTP, NC 27709; 4Eschelman School of Pharmacy, UNC Chapel Hill, NC 27599; 5Department of Chemical Biology, University of Pittsburgh, Pittsburgh, PA 15261. Reactive oxygen species contribute to the pathogenesis of many acute and chronic pulmonary disorders, including bronchopulmonary dysplasia (BPD), a respiratory condition affecting preterm infants. BPD treatment often involves respiratory support with high oxygen, and oxidative stress is an adverse effect associated with impaired lung development and function in a subset of infants. Genetic polymorphisms in a few candidate genes have been www.gems-nc.org 9 | P age associated with BPD susceptibility, however the genetic basis of differential susceptibility remains poorly understood. To mimic features of BPD we developed a mouse model where one day after birth neonatal mice from 29 inbred strains were exposed for 72 hr to normoxia (room air, 20% O ) or hyperoxia (>95% O ). 2 2 Hyperoxia induced phenotypes similar to BPD when compared to normal postnatal lung development in normoxia. We ultra-deep sequenced neonatal lung mitochondrial DNA from these mice and found three major haplotype groups among 27 strains that were sequenced, with classical inbred strains in haplotype 1, NZB and NZO in haplotype 2, and PWD/PhJ and PWK/PhJ in haplotype 3. Wild derived strains had more variation than classical inbred strains. We found exposure to low (20%) and high (>95%) concentrations of oxygen early in life cause lesions in mouse lung mtDNA and nucDNA that are strain dependent. Ultra-deep sequencing also identified mtDNA sequence variation and differences in heteroplasmy and indels across inbred mouse strains that associate with disease phenotypes. Through these combined approaches, we have identified novel candidate susceptibility genes that may improve our understanding of neonatal lung injury and development. T3 Sex Differences in Placental Mitochondrial Function Associated with Ozone-Induced Fetal Growth Restriction. Colette N. Miller1, Katelyn S. Lavrich2, Danielle Freeborn3, Janice A. Dye1, Prasada R. Kodavanti3, Urmila P. Kodavanti1 1EPHD, 3TAD, NHEERL, US EPA, Research Triangle Park, NC 27711; 2CIT, UNC Chapel Hill, Chapel Hill, NC 27599 Fetal growth restriction is a major underlying cause of infant mortality worldwide. Unfortunately little is known about the mechanisms that drive compromised growth and the role of placental maladaptation on fetal development. In the current study placentas from male and female rat pups were harvested on gestational day (GD) 21 from Long Evans dams exposed to filtered air or 0.8 ppm ozone, 4hr/day during the implantation period on GD 5 and 6. At GD21, pups from ozone exposed dams had reduced weight compared to air control pups. Bioenergetics, measured as oxygen consumption rate (OCR), on mitochondria were measured using the Seahorse XF96 analyzer. Baseline OCR in the female placentas were elevated compared to males. While maternal ozone exposure did not impact female placental OCR at baseline, placentas of ozone-exposed males had increased OCR relative to controls. Following stimulation of the electron transport chain with ADP, a near significant effect of ozone to increase OCR was observed. Gene expression experiments confirmed elevated mitochondrial biogenesis in ozone-exposed male and female placentas. Further, female placentas from ozone-exposed dams had reduced Sod1 and increased Bcl2 expression compared to air-exposed female placentas. This difference was not observed in males. Together our data supports the hypothesis that placental mitochondrial dysfunction is related to reduced fetal weight. We demonstrate clear sex differences in the placental mitochondria of both healthy and growth compromised pups. Our findings support the emerging importance of mitochondrial function in the etiology of fetal growth restriction. This abstract does not reflect US EPA policy. www.gems-nc.org 10 | P age
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