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Displaying 51 to 74 of 74 results for genomics

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  • Peisong Gao Lab

    The Peisong Gao Lab’s major focus is to understand the immunological and genetic regulation of allergic diseases. We have been involved in the identification of the genetic basis for atopic dermatitis and eczema herpeticum (ADEH) as part of the NIH Atopic Dermatitis and Vaccinia Network-Clinical Studies Consortium. Major projects in the Gao Lab include immunogenetic analysis of human response to allergen, identification of candidate genes for specific immune responsiveness to cockroach allergen, and epigenetics of food allergy (FA).

    Research Areas: food allergies, eczema herpeticum, epigenetics, allergies, genomics, atopic dermatitis

    Principal Investigator

    Peisong Gao, M.D., Ph.D.

    Department

    Medicine

  • Phenotyping and Pathology Core

    The Phenotyping Core promotes functional genomics and other preclinical translational science at Johns Hopkins. We assist and collaborate in the characterization and use of genetically and phenotypically relevant animal models of disease and gene function.

    Research Areas: pathobiology, phenotyping, translational research, genomics

    Lab Website

    Principal Investigator

    Cory Brayton, D.V.M.

    Department

    Molecular and Comparative Pathobiology

  • Philip Wong Lab

    The Philip Wong Lab seeks to understand the molecular mechanisms and identification of new therapeutic targets of neurodegenerative diseases, particularly Alzheimer's disease (AD) and amyotrophic lateral sclerosis (ALS). Taking advantage of discoveries of genes linked to these diseases (mutant APP and PS in familial AD and mutant SOD1, dynactin p150glued ALS4and ALS2 in familial ALS), our laboratory is taking a molecular/cellular approach, including transgenic, gene targeting and RNAi strategies in mice, to develop models that facilitate our understanding of pathogenesis of disease and the identification and validation of novel targets for mechanism-based therapeutics. Significantly, these mouse models are instrumental for study of disease mechanisms, as well as for design and testing of therapeutic strategies for AD and ALS.

    Research Areas: neurodegenerative disorders, ALS, genomics, pathogenesis, Alzheimer's disease

    Lab Website

    Principal Investigator

    Philip Wong, Ph.D.

    Department

    Pathology

  • Rasika Mathias Lab

    Research in the Rasika Mathias Lab focuses on the genetics of asthma in people of African ancestry. Our work led to the first genomewide association study of its kind in 2009. Currently, we are analyzing the whole-genome sequence of more than 1,000 people of African ancestry from the Consortium on Asthma among African-ancestry Populations in the Americas (CAAPA). CAAPA’s goal is to use whole-genome sequencing to expand our understanding of how genetic variants affect asthma risk in populations of African ancestry and to provide a public catalog of genetic variation for the scientific community. We’re also involved in the study of coronary artery disease though the GeneSTAR Program, which aims to identify mechanisms of atherogenic vascular diseases and attendant comorbidities.

    Research Areas: heart disease, African Americans, asthma, genomics, health disparities

    Principal Investigator

    Rasika Mathias, Sc.D.

    Department

    Medicine

  • Reeves Lab

    The Reeves Lab complements genetic analyses in human beings with the creation and characterization of mouse models to understand why and how gene dosage imbalance disrupts development in Down syndrome (DS). These models then provide a basis to explore therapeutic approaches to amelioration of DS features. We use chromosome engineering in embryonic stem cells (ES) to create defined dosage imbalance in order to localize the genes contributing to these anomalies and to directly test hypotheses concerning Down syndrome "critical regions" on human chromosome 21.

    Research Areas: Down syndrome, stem cells, chromosome 21, genomics

    Lab Website

    Principal Investigator

    Roger Reeves, Ph.D.

    Department

    Physiology

  • Retrovirus Laboratory

    Research in the Retrovirus Laboratory focuses on the molecular virology and pathogenesis of lentivirus infections. In particular, we study the simian immunodeficiency virus (SIV) to determine the molecular basis for the development of HIV CNS, pulmonary and cardiac disease.

    Research projects include studies of viral molecular genetics and host cell genes and proteins involved in the pathogenesis of disease. We are also interested in studies of lentivirus replication in macrophages and astrocytes and their role in the development of disease. These studies have led us to identify the viral genes that are important in neurovirulence of SIV and the development of CNS disease including NEF and the TM portion of ENV. The mechanisms of the action of these proteins in the CNS are complex and are under investigation. We have also developed a rapid, consistent SIV/macaque model in which we can test the ability of various antiviral and neuroprotective agents to reduce the severity of CNS and ...pulmonary disease. view more

    Research Areas: HIV, genomics, pulmonology, SIV, cardiology, lentivirus

    Principal Investigator

    Janice Clements, Ph.D.

    Department

    Molecular and Comparative Pathobiology

  • Ryuya Fukunaga Lab

    The Fukunaga Lab uses multidisciplinary approaches to understand the cell biology, biogenesis and function of small silencing RNAs from the atomic to the organismal level.

    The lab studies how small silencing RNAs, including microRNAs (miRNAs), small interfering RNAs (siRNAs) and piwi-interacting RNAs (piRNAs), are produced and how they function. Mutations in the small RNA genes or in the genes involved in the RNA pathways cause many diseases, including cancers. We use a combination of biochemistry, biophysics, fly genetics, cell culture, X-ray crystallography and next-generation sequencing to answer fundamental biological questions and also potentially lead to therapeutic applications to human diseases.

    Research Areas: biophysics, biochemistry, cell biology, cell culture, genomics, RNA

    Principal Investigator

    Ryuya Fukunaga, Ph.D.

    Department

    Biological Chemistry

  • Salzberg Lab

    Research in the Salzberg Lab focuses on the development of new computational methods for analysis of DNA from the latest sequencing technologies. Over the years, we have developed and applied software to many problems in gene finding, genome assembly, comparative genomics, evolutionary genomics and sequencing technology itself. Our current work emphasizes analysis of DNA and RNA sequenced with next-generation technology.

    Research Areas: computational biology, DNA, genomics, sequencing technology, biostatistics, RNA

  • Seth Blackshaw Lab

    The Seth Blackshaw Lab uses functional genomics and proteomics to rapidly identify the molecular mechanisms that regulate cell specification and survival in both the retina and hypothalamus. We have profiled gene expression in both these tissues, from the start to the end of neurogenesis, characterizing the cellular expression patterns of more than 1,800 differentially expressed transcripts in both tissues. Working together with the lab of Heng Zhu in the Department of Pharmacology, we have also generated a protein microarray comprised of nearly 20,000 unique full-length human proteins, which we use to identify biochemical targets of developmentally important genes of interest.

    Research Areas: retina, central nervous system, biochemistry, hypothalamus, proteomics, genomics

    Lab Website

    Principal Investigator

    Seth Blackshaw, Ph.D.

    Department

    Neuroscience

  • Seydoux Lab

    The Seydoux Lab studies the earliest stages of embryogenesis to understand how single-celled eggs develop into complex multicellular embryos. We focus on the choice between soma and germline, one of the first developmental decisions faced by embryos. Our goal is to identify and characterize the molecular mechanisms that activate embryonic development, polarize embryos, and distinguish between somatic and germline cells, using Caenorhabditis elegans as a model system. Our research program is divided into three areas: oocyte-to-embryo transition, embryonic polarity and soma-germline dichotomy.

    Research Areas: cell biology, soma cells, genomics, germ cells, embryo, molecular biology

  • Shanthini Sockanathan Laboratory

    The Shanthini Sockanathan Laboratory uses the developing spinal cord as our major paradigm to define the mechanisms that maintain an undifferentiated progenitor state and the molecular pathways that trigger their differentiation into neurons and glia. The major focus of the lab is the study of a new family of six-transmembrane proteins (6-TM GDEs) that play key roles in regulating neuronal and glial differentiation in the spinal cord. We recently discovered that the 6-TM GDEs release GPI-anchored proteins from the cell surface through cleavage of the GPI-anchor. This discovery identifies 6-TM GDEs as the first vertebrate membrane bound GPI-cleaving enzymes that work at the cell surface to regulate GPI-anchored protein function. Current work in the lab involves defining how the 6-TM GDEs regulate cellular signaling events that control neuronal and glial differentiation and function, with a major focus on how GDE dysfunction relates to the onset and progression of disease. To solve the...se questions, we use an integrated approach that includes in vivo models, imaging, molecular biology, biochemistry, developmental biology, genetics and behavior. view more

    Research Areas: glia, biochemistry, neurons, imaging, developmental biology, genomics, spinal cord, behavior, molecular biology

    Lab Website

    Principal Investigator

    Shanthini Sockanathan, D.Phil.

    Department

    Neuroscience

  • Susan Michaelis Lab

    The Michaelis Laboratory's research goal is to dissect fundamental cellular processes relevant to human health and disease, using yeast and mammalian cell biology, biochemistry and high-throughput genomic approaches. Our team studies the cell biology of lamin A and its role in the premature aging disease Hutchinson-Gilford progeria syndrome (HGPS). Other research focuses on the core cellular machinery involved in recognition of misfolded proteins. Understanding cellular protein quality control machinery will ultimately help researchers devise treatments for protein misfolding diseases in which degradation is too efficient or not enough.

    Research Areas: biochemistry, cell biology, protein folding, lamin A, aging, genomics, Hutchinson-Gilford progeria syndrome, yeast

    Principal Investigator

    Susan Michaelis, Ph.D.

    Department

    Cell Biology

  • Tamara O'Connor Lab

    The O'Connor Lab studies the molecular basis of infectious disease using Legionella pneumophila pathogenesis as a model system.

    We are looking at the network of molecular interactions acting at the host-pathogen interface. Specifically, we use L. pneumophila pathogenesis to examine the numerous mechanisms by which an intracellular bacterial pathogen can establish infection, how it exploits host cell machinery to accomplish this, and how individual proteins and their component pathways coordinately contribute to disease.

    We are also studying the role of environmental hosts in the evolution of human pathogens. Using genetics and functional genomics, we compare and contrast the repertoires of virulence proteins required for growth in a broad assortment of hosts, how the network of molecular interactions differs between hosts, and the mechanisms by which L. pneumophila copes with this variation.

    Research Areas: infectious disease, Legionella pneumophila, genomics, pathogenesis, molecular biology

    Principal Investigator

    Tamara O'Connor, Ph.D.

    Department

    Biological Chemistry

  • Ted Dawson Laboratory

    The Ted Dawson Laboratory uses genetic, cell biological and biochemical approaches to explore the pathogenesis of Parkinson's disease (PD) and other neurologic disorders. We also investigate several discrete mechanisms involved in cell death, including the role of nitric oxide as an endogenous messenger, the function of poly (ADP-ribose) polymerase-1 and apoptosis inducing factor in cell death, and how endogenous cell survival mechanisms protect neurons from death.

    Research Areas: nitric oxide, neuronal signaling, genomics, pathogenesis, Parkinson's disease, cell death

    Lab Website

    Principal Investigator

    Ted Dawson, M.D., Ph.D.

    Department

    Neurology

  • The Arking Lab

    The Arking Lab studies the genomics of complex human disease, with the primary goal of identifying and characterizing genetics variants that modify risk for human disease. The group has pioneered the use of genome-wide association studies (GWAS), which allow for an unbiased screen of virtually all common genetic variants in the genome. The lab is currently developing improved GWAS methodology, as well as exploring the integration of additional genome level data (RNA expression, DNA methylation, protein expression) to improve the power to identify specific genetic influences of disease.

    The Arking Lab is actively involved in researching:
    • autism, a childhood neuropsychiatric disorder
    • cardiovascular genomics, with a focus on electrophysiology and sudden cardiac death (SCD)
    • electrophysiology is the study of the flow of ions in biological tissues

    Dan E. Arking, PhD, is an associate professor at the McKusick-Nathans Institute of Genetic Medicine and Department of Medicine, D...ivision of Cardiology, Johns Hopkins University. view more

    Research Areas: autism, genetics, aging, cardiovascular diseases, sudden cardiac death

    Principal Investigator

    Dan Arking, Ph.D.

    Department

    Medicine

  • The Cohen Lab

    Combining microbiology and bioinformatics, the Cohen Lab conducts translational research on mycobacteria. By application of advanced genomic techniques to the problems of tuberculosis and nontuberculous mycobacteria, the Cohen Lab aims to develop improved tools for the diagnosis and management of mycobacterial disease.

    Research Areas: nontuberculous mycobacteria, genomics, drug resistance, tuberculosis

    Principal Investigator

    Keira Cohen, M.D.

    Department

    Medicine

  • Tom Woolf Lab

    The Tom Woolf Lab studies the quarter of the genome devoted to membrane proteins. This rapidly growing branch of bioinformatics, which includes computational biophysics, represents the main research direction of our group. We aim to provide insight into critical issues for membrane systems. In pursuit of these goals, we use extensive computer calculations to build an understanding of the relations between microscopic motions and the world of experimental measurements. Our calculations use our own Beowulf computer cluster as well as national supercomputer centers. An especially strong focus has been on the computed motions of proteins and all-atom models of the lipid bilayers that mediate their influence. To compute these motions, we use the molecular dynamics program CHARMM. We hope to use our understanding of the molecular motions for the prediction of membrane protein structures using new computational methods.

    Research Areas: proteomics, genomics, bioinformatics, computational biophysics

    Lab Website

    Principal Investigator

    Thomas Woolf, Ph.D.

    Department

    Physiology

  • Victor Velculescu Lab

    The lab currently focuses on identifying genetic alterations in cancer affecting sensitivity and resistance to targeted therapies, and connecting such changes to key clinical characteristics and novel therapeutic approaches. We have recently developed methods that allow noninvasive characterization of cancer, including the PARE method that provided the first whole genome analysis of tumor DNA in the circulation of cancer patients. These analyses provide a window into real-time genomic analyses of cancer patients and provide new avenues for personalized diagnostic and therapeutic intervention.

    Research Areas: cancer, genomics, immunotherapy

  • Wheelan Lab

    The Wheelan Lab focuses on DNA sequence analysis. Her team creates new techniques to mathematically analyze and biologically interpret high-throughput sequencing data and other high-dimensional biological datasets. The team examines spatial relationships across genomes and uses transposons to query genomic sequence/structure relationships.

    Research Areas: computational biology, DNA, genomics, sequencing

    Principal Investigator

    Sarah Wheelan, M.D., Ph.D.

    Department

    Oncology

  • William Bishai Laboratory

    The William Bishai Laboratory studies the molecular pathogenesis of tuberculosis. The overall goal of our laboratory is to better understand tuberculosis pathogenesis and then to employ this understanding toward improved drugs, vaccines and diagnostics. Since Mycobacterium tuberculosis senses and adapts to a wide array of conditions during the disease process, it is clear that the regulation of expression of virulence factors plays an important role in pathogenesis. As a result, a theme of our research is to assess mycobacterial genes important in gene regulation. We are also interested in cell division in mycobacteria and the pathogenesis of caseation and cavitation.

    Research Areas: vaccines, genomics, drugs, pathogenesis, tuberculosis

    Lab Website

    Principal Investigator

    William Bishai, M.D., Ph.D.

    Department

    Medicine

  • Wolberger Lab

    The Wolberger Lab is interested in the structural and mechanistic basis for transcriptional regulation and ubiquitin signaling as it relates to the integrity and expression of the genome. We use x-ray crystallography, enzymology, cell-based assays and a variety of biophysical tools to gain insights into the mechanisms underlying these essential cellular processes.

    Research Areas: biophysics, ubiquitin signaling, genomics, transcriptional regulation

  • Xiao Group

    The objective of the Xiao Group's research is to study the dynamics of cellular processes as they occur in real time at the single-molecule and single-cell level. The depth and breadth of our research requires an interdisciplinary approach, combining biological, biochemical and biophysical methods to address compelling biological problems quantitatively. We currently are focused on dynamics of the E. coli cell division complex assembly and the molecular mechanism in gene regulation.

    Research Areas: biophysics, biochemistry, E. coli, cell biology, genomics, molecular biology

  • Zhaozhu Qiu Laboratory

    Ion channels are pore-forming membrane proteins gating the flow of ions across the cell membrane. Among their many functions, ion channels regulate cell volume, control epithelial fluid secretion, and generate the electrical impulses in our brain. The Qiu Lab employs a multi-disciplinary approach including high-throughput functional genomics, electrophysiology, biochemistry, and mouse genetics to discover novel ion channels and to elucidate their role in health and disease.

    Research Areas: ion channel, neurological disease, electrophysiology, functional genomics, sensory neuroscience

    Lab Website

    Principal Investigator

    Zhaozhu Qiu, Ph.D.

    Department

    Neuroscience
    Physiology

  • Zhu Lab

    The Zhu lab is focused on characterizing the activities of large collection of proteins, building signaling networks for better understanding the mechanisms of biological processes, and identifying biomarkers in human diseases and cancers.

    More specifically, our group is interested in analyzing protein posttranslational modifications, and identifying important components involved in transcription networks and host-pathogen interactions on the proteomics level, and biomarkers in human IBD diseases.

    Research Areas: proteomics, biomarkers, cancer, genomics, protein chip, signaling networks

    Principal Investigator

    Heng Zhu, Ph.D.

    Department

    Pharmacology and Molecular Sciences

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