{"result":[{"lastName":"Gozani","clinicalFocus":[],"appointments":[{"appointment":"Assistant Professor,Biology (School of Humanities and Sciences)"},{"appointment":"Member,Cancer Center"}],"primaryAppointment":"Assistant Professor,Biology (School of Humanities and Sciences)","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=6423&type=small&showNoImage","displayName":"Or Gozani","firstName":"Or","href":"http://med.stanford.edu/profiles/Or_Gozani","researchInterest":"We study the molecular mechanisms by which chromatin-signaling networks effect nuclear and epigenetic programs, and how dysregulation of these pathways leads to disease.  Our work centers on the biology of lysine methylation, a principal chromatin-regulatory mechanism that directs epigenetic processes.  We study how lysine methylation events are generated, sensed, and transduced, and how these chemical marks integrate with other nuclear signaling systems to govern diverse cellular functions."},{"lastName":"Hong","clinicalFocus":[],"appointments":[{"appointment":"Postdoctoral Research fellow, School of Medicine"}],"primaryAppointment":"Postdoctoral Research fellow, School of Medicine","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=10153&type=small&showNoImage","displayName":"Tao Hong","firstName":"Tao","href":"http://med.stanford.edu/profiles/Tao_Hong","researchInterest":""},{"lastName":"Chang","clinicalFocus":[{"focus":"Dermatology"}],"appointments":[{"appointment":"Associate Professor,Dermatology"},{"appointment":"Member,Bio-X"},{"appointment":"Member,Cancer Center"}],"primaryAppointment":"Associate Professor,Dermatology","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=6089&type=small&showNoImage","displayName":"Howard Y. Chang","firstName":"Howard","href":"http://med.stanford.edu/profiles/Howard_Chang","researchInterest":"The Chang group is focused on two fundamental questions in epithelial biology: (1) the basis of positional identities in epidermal structures throughout the body, and (2) how those signals and boundaries may be abrogated to allow cancer metastasis. We are investigating the roles of site-specific fibroblast differentiation in patterning the epidermis, and dissecting the mechanisms of wound healing programs in cancer metastasis."},{"lastName":"Berg","clinicalFocus":[],"appointments":[{"appointment":"Emeritus (Active) Professor,Biochemistry"},{"appointment":"Emeritus Faculty, Acad Council,Biochemistry"}],"primaryAppointment":"Emeritus (Active) Professor,Biochemistry","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=6263&type=small&showNoImage","displayName":"Paul Berg","firstName":"Paul","href":"http://med.stanford.edu/profiles/Paul_Berg","researchInterest":"For about 10 years until 2000, my lab\u0092s research activities were focused on the mechanism of recombinational repair of double-strand breaks in DNA. We focused our efforts on two model systems:  one involved the repair of restriction enzyme cleavages at specific mammalian chromosomal loci and the second explored the biochemical properties of purified yeast Rad51 protein, an essential catalyst for synapsing the broken ends of DNA with an intact homologue of that sequence.  We also explored the ro"},{"lastName":"Brunet","clinicalFocus":[],"appointments":[{"appointment":"Assistant Professor,Genetics"},{"appointment":"Member,Bio-X"},{"appointment":"Member,Cancer Center"}],"primaryAppointment":"Assistant Professor,Genetics","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=6012&type=small&showNoImage","displayName":"Anne Brunet","firstName":"Anne","href":"http://med.stanford.edu/profiles/Anne_Brunet","researchInterest":"Our lab studies the molecular basis of longevity. We are interested in the mechanism of action of known longevity genes, including FOXO and SIRT, in the mammalian nervous system. We are particularly interested in the role of these longevity genes in neural stem cells. We are also discovering novel genes and processes involved in aging using two model systems, the invertebrate C. elegans and an extremely short-lived vertebrate, the African killifish N. furzeri."},{"lastName":"Brown","clinicalFocus":[],"appointments":[{"appointment":"Professor,Biochemistry"},{"appointment":"Member,Cancer Center"}],"primaryAppointment":"Professor,Biochemistry","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=4284&type=small&showNoImage","displayName":"Patrick O. Brown","firstName":"Patrick","href":"http://med.stanford.edu/profiles/Patrick_Brown","researchInterest":"Dr. Brown's research group uses diverse experimental and computational methods to investigate the logic and mechanisms that control a genome's expression program.  The Brown laboratory is systematically characterizing the genetic scripts that control the expression of our genes, in normal development and physiology and in diseases like cancer, with a particular focus on post-transcriptional regulation. The Brown lab also develops strategies and assays for early detection and diagnosis of cancer."},{"lastName":"Cimprich","clinicalFocus":[],"appointments":[{"appointment":"Associate Professor,Chemical and Systems Biology"},{"appointment":"Associate Professor (By courtesy),Chemistry"},{"appointment":"Member,Bio-X"},{"appointment":"Member,Cancer Center"}],"primaryAppointment":"Associate Professor,Chemical and Systems Biology","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=4417&type=small&showNoImage","displayName":"Karlene Cimprich","firstName":"Karlene","href":"http://med.stanford.edu/profiles/Karlene_Cimprich","researchInterest":"The use of genetic, biochemical and chemical approaches to understand the DNA damage-induced cell cycle checkpoints and the processes that contribute to maintenance of genomic stability."},{"lastName":"Wysocka","clinicalFocus":[],"appointments":[{"appointment":"Assistant Professor,Chemical and Systems Biology"},{"appointment":"Assistant Professor,Developmental Biology"}],"primaryAppointment":"Assistant Professor,Chemical and Systems Biology","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=7764&type=small&showNoImage","displayName":"Joanna Wysocka","firstName":"Joanna","href":"http://med.stanford.edu/profiles/Joanna_Wysocka","researchInterest":"Research in our lab focuses on mechanisms of epigenetic regulation in differentiation and development. In particular, we are studying the function of histone modifying enzymes in embryonic stem cell self-renewal and in early cell fate decisions. We are interested in the role of chromatin modifications in establishment and maintenance of gene expression patterns during normal and pathological development, and in nuclear reprogramming."},{"lastName":"Chu","clinicalFocus":[{"focus":"Oncology"}],"appointments":[{"appointment":"Professor,Medicine - Oncology"},{"appointment":"Professor,Biochemistry"},{"appointment":"Member,Bio-X"},{"appointment":"Member,Cancer Center"}],"primaryAppointment":"Professor,Medicine - Oncology","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=4149&type=small&showNoImage","displayName":"Gilbert Chu","firstName":"Gilbert","href":"http://med.stanford.edu/profiles/Gilbert_Chu","researchInterest":"Our laboratory focuses on understanding how cells respond to DNA damage. Our research currently involves areas that interact with each other: repair of radiation damage, and transcriptional responses to DNA damage."},{"lastName":"Reijo-Pera","clinicalFocus":[],"appointments":[{"appointment":"Professor,Obstetrics & Gynecology - OB GYN Institutes"},{"appointment":"Member,Cancer Center"},{"appointment":"Member,Bio-X"}],"primaryAppointment":"Professor,Obstetrics & Gynecology - OB GYN Institutes","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=8036&type=small&showNoImage","displayName":"Renee A. Reijo Pera, Ph.D.","firstName":"Renee","href":"http://med.stanford.edu/profiles/Renee_Reijo-Pera","researchInterest":"The Reijo Pera Laboratory is focused on understanding key cell fates in the embryo, including the generation of pluripotent stem cells, somatic and germ cell lineages"},{"lastName":"Davis","clinicalFocus":[],"appointments":[{"appointment":"Professor,Biochemistry"},{"appointment":"Professor,Genetics"},{"appointment":"Member,Bio-X"},{"appointment":"Member,Cancer Center"}],"primaryAppointment":"Professor,Biochemistry","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=4117&type=small&showNoImage","displayName":"Ronald Davis","firstName":"Ronald","href":"http://med.stanford.edu/profiles/Ronald_Davis","researchInterest":"We are using Saccharomyces cerevisiae and Human to conduct whole genome analysis projects. The yeast genome sequence has approximately 6,000 genes. We have made a set of haploid and diploid strains (21,000) containing a complete deletion of each gene. In order to facilitate whole genome analysis each deletion is molecularly tagged with a unique 20-mer DNA sequence. This sequence acts as a molecular bar code and makes it easy to identify the presence of each deletion."},{"lastName":"Morrison","clinicalFocus":[],"appointments":[{"appointment":"Assistant Professor,Biology (School of Humanities and Sciences)"},{"appointment":"Member,Cancer Center"}],"primaryAppointment":"Assistant Professor,Biology (School of Humanities and Sciences)","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=14873&type=small&showNoImage","displayName":"Ashby Morrison","firstName":"Ashby","href":"http://med.stanford.edu/profiles/Ashby_Morrison","researchInterest":"Our research interests are to elucidate the contribution of chromatin to mechanisms that promote genomic integrity."},{"lastName":"Artandi","clinicalFocus":[{"focus":"Medical Oncology"}],"appointments":[{"appointment":"Associate Professor,Medicine - Hematology"},{"appointment":"Member,Bio-X"},{"appointment":"Member,Cancer Center"}],"primaryAppointment":"Associate Professor,Medicine - Hematology","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=3848&type=small&showNoImage","displayName":"Steven Artandi","firstName":"Steven","href":"http://med.stanford.edu/profiles/Steven_Artandi","researchInterest":"Telomeres are nucleoprotein complexes that protect chromosome ends and shorten with cell division and aging.  We are interested in how telomere shortening influences cancer, stem cell function and genomic stability.  Telomerase is a reverse transcriptase that synthesizes telomere repeats and is expressed in stem cells and in cancer.  We have found that telomerase also regulates stem cells and we are pursuing the function of telomerase through diverse genetic and biochemical approaches."},{"lastName":"Fraser","clinicalFocus":[],"appointments":[{"appointment":"Assistant Professor,Biology (School of Humanities and Sciences)"},{"appointment":"Member,Cancer Center"}],"primaryAppointment":"Assistant Professor,Biology (School of Humanities and Sciences)","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=15112&type=small&showNoImage","displayName":"Hunter Fraser","firstName":"Hunter","href":"http://med.stanford.edu/profiles/Hunter_Fraser","researchInterest":""},{"lastName":"Choi","clinicalFocus":[],"appointments":[{"appointment":"Postdoctoral Research fellow, Medicine"}],"primaryAppointment":"Postdoctoral Research fellow, Medicine","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=13431&type=small&showNoImage","displayName":"Jinkuk Choi","firstName":"Jinkuk","href":"http://med.stanford.edu/profiles/Jinkuk_Choi","researchInterest":""},{"lastName":"Boxer","clinicalFocus":[{"focus":"Hematology"},{"focus":"Multiple Myeloma"},{"focus":"Multiple Myeloma - Medical Oncology"},{"focus":"Plasmacytoma"},{"focus":"Plasmacytoma - Hematology"},{"focus":"Plasmacytoma - Medical Oncology"}],"appointments":[{"appointment":"Professor,Medicine - Hematology"},{"appointment":"Member,Bio-X"},{"appointment":"Member,Cancer Center"}],"primaryAppointment":"Professor,Medicine - Hematology","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=4658&type=small&showNoImage","displayName":"Linda Boxer","firstName":"Linda","href":"http://med.stanford.edu/profiles/Linda_Boxer","researchInterest":"Regulation of expression of oncogenes in normal and malignant hematologic cells."},{"lastName":"Collins","clinicalFocus":[],"appointments":[{"appointment":"Postdoctoral Research fellow, Chemical and Systems Biology"}],"primaryAppointment":"Postdoctoral Research fellow, Chemical and Systems Biology","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=10605&type=small&showNoImage","displayName":"Sean Collins","firstName":"Sean","href":"http://med.stanford.edu/profiles/Sean_Collins","researchInterest":""},{"lastName":"Tran","clinicalFocus":[],"appointments":[{"appointment":"Member,Cancer Center"}],"primaryAppointment":"Member,Cancer Center","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=8562&type=small&showNoImage","displayName":"Phuoc T. Tran","firstName":"Phuoc","href":"http://med.stanford.edu/profiles/Phuoc_Tran","researchInterest":""},{"lastName":"Attardi","clinicalFocus":[],"appointments":[{"appointment":"Associate Professor,Radiation Oncology - Radiation Biology"},{"appointment":"Associate Professor,Genetics"},{"appointment":"Member,Bio-X"},{"appointment":"Member,Cancer Center"}],"primaryAppointment":"Associate Professor,Radiation Oncology - Radiation Biology","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=3851&type=small&showNoImage","displayName":"Laura Attardi","firstName":"Laura","href":"http://med.stanford.edu/profiles/Laura_Attardi","researchInterest":"Our research is aimed at defining the pathways of p53-mediated apoptosis and tumor suppression, using a combination of biochemical, cell biological, and mouse genetic approaches. Our strategy is to start by generating hypotheses about p53 mechanisms of action using primary mouse embryo fibroblasts (MEFs), and then to test them using gene targeting technology in the mouse."},{"lastName":"Felsher","clinicalFocus":[{"focus":"Hodgkin's Disease"},{"focus":"Hodgkin's Disease - Hematology"},{"focus":"Hodgkin's Disease - Medical Oncology"},{"focus":"Lymphoma "},{"focus":"Oncology"},{"focus":"Oncology (Cancer)"}],"appointments":[{"appointment":"Associate Professor,Medicine - Oncology"},{"appointment":"Associate Professor,Pathology"},{"appointment":"Member,Bio-X"},{"appointment":"Member,Cancer Center"}],"primaryAppointment":"Associate Professor,Medicine - Oncology","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=5931&type=small&showNoImage","displayName":"Dean W. Felsher","firstName":"Dean","href":"http://med.stanford.edu/profiles/Dean_Felsher","researchInterest":"My laboratory investigates how oncogenes initiate and sustain tumorigenesis. I have developed model systems whereby I can conditionally activate oncogenes in normal human and mouse cells in tissue culture or in specific tissues of transgenic mice. In particular using the tetracycline regulatory system, I have generated a conditional model system for MYC-induced tumors. I have shown that cancers caused by the conditional over-expression of the MYC proto-oncogene regress with its inactivation."},{"lastName":"Giaccia","clinicalFocus":[],"appointments":[{"appointment":"Professor,Radiation Oncology - Radiation Biology"},{"appointment":"Professor (By courtesy),Obstetrics & Gynecology"},{"appointment":"Professor (By courtesy),Surgery"},{"appointment":"Member,Cancer Center"}],"primaryAppointment":"Professor,Radiation Oncology - Radiation Biology","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=4141&type=small&showNoImage","displayName":"Amato Giaccia","firstName":"Amato","href":"http://med.stanford.edu/profiles/Amato_Giaccia","researchInterest":"Cellular response to hypoxia and ionizing radiation; cell-cycle control, apoptosis and angiogenesis in transformed cells."},{"lastName":"Hanawalt","clinicalFocus":[],"appointments":[{"appointment":"Professor,Biology (School of Humanities and Sciences)"},{"appointment":"Professor,Dermatology"},{"appointment":"Member,Bio-X"},{"appointment":"Member,Cancer Center"}],"primaryAppointment":"Professor,Biology (School of Humanities and Sciences)","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=5957&type=small&showNoImage","displayName":"Philip Hanawalt","firstName":"Philip","href":"http://med.stanford.edu/profiles/Philip_Hanawalt","researchInterest":"Hanawalt has been a productive researcher in the field of DNA repair since his pioneering discovery of repair replication in E. coli in 1963. He also first demonstrated repair replication in mycoplasmata and in a eukaryote and he has developed a number of important experimental approaches for studying repair, beginning with the BrdUrd density labeling method for resolving semiconservatively replicated DNA from parental DNA containing repair patches. Hanawalt\u0092s approach was used to validate the "},{"lastName":"Lorch","clinicalFocus":[],"appointments":[{"appointment":"Associate Professor (Research),Structural Biology"}],"primaryAppointment":"Associate Professor (Research),Structural Biology","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=4116&type=small&showNoImage","displayName":"Yahli Lorch","firstName":"Yahli","href":"http://med.stanford.edu/profiles/Yahli_Lorch","researchInterest":""},{"lastName":"Pringle","clinicalFocus":[],"appointments":[{"appointment":"Professor,Genetics"}],"primaryAppointment":"Professor,Genetics","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=7022&type=small&showNoImage","displayName":"John R. Pringle","firstName":"John","href":"http://med.stanford.edu/profiles/John_Pringle","researchInterest":"Much of our research exploits the power of yeast as an experimentally tractable model eukaryote to investigate fundamental problems in cell and developmental biology such as the mechanisms of cell polarization and cytokinesis.  In another project, we are developing the small sea anemone Aiptasia as a model system for study of the molecular and cellular biology of dinoflagellate-cnidarian symbiosis, which is critical for the survival of most corals but still very poorly understood."},{"lastName":"Nolan","clinicalFocus":[],"appointments":[{"appointment":"Professor,Microbiology & Immunology - Baxter Laboratory"},{"appointment":"Member,Bio-X"},{"appointment":"Member,Cancer Center"}],"primaryAppointment":"Professor,Microbiology & Immunology - Baxter Laboratory","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=4713&type=small&showNoImage","displayName":"Garry Nolan","firstName":"Garry","href":"http://med.stanford.edu/profiles/Garry_Nolan","researchInterest":"Dr. Nolan's group uses high throughput single cell analysis technology of kinase driven signaling cascades to interrogate autoimmunity, cancer, virology (influenza), bacterial pathogens (Listeria and Salmonella) as well as understanding normal immune system function.  Using advanced flow cytometric techniques and computational biology approaches, we focus on high throughput drug screening, mouse models of disease in patient materials, and understanding disease processes at the single cell level."}]}