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Displaying 41 to 60 of 120 results for biology

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  • Greider Lab

    The Greider lab uses biochemistry to study telomerase and cellular and organismal consequences of telomere dysfunction. Telomeres protect chromosome ends from being recognized as DNA damage and chromosomal rearrangements. Conventional replication leads to telomere shortening, but telomere length is maintained by the enzyme telomerase. Telomerase is required for cells that undergo many rounds of divisions, especially tumor cells and some stem cells. The lab has generated telomerase null mice that are viable and show progressive telomere shortening for up to six generations. In the later generations, when telomeres are short, cells die via apoptosis or senescence. Crosses of these telomerase null mice to other tumor prone mice show that tumor formation can be greatly reduced by short telomeres. The lab also is using the telomerase null mice to explore the essential role of telomerase stem cell viability. Telomerase mutations cause autosomal dominant dyskeratosis congenita. People with ...this disease die of bone marrow failure, likely due to stem cell loss. The lab has developed a mouse model to study this disease. Future work in the lab will focus on identifying genes that induce DNA damage in response to short telomeres, identifying how telomeres are processed and how telomere elongation is regulated. view more

    Research Areas: telomerase, biochemistry, stem cells, cell biology, DNA

  • Haig Kazazian Lab

    The Kazazian Lab focuses on the biology of LINE-1 (L1) retrotransposons. Retrotransposons are pieces of genomic DNA that have the ability to duplicate themselves and insert into a new genomic location. Current studies use innovative DNA sequencing to locate all human-specific L1s in any genome. By understanding L1 biology, we hope to better understand the role of these genomes and their behavior in complex human disease, such as cancer and mental disorders. The lab is also examining how to carry out gene therapy of hemophilia A using AAV vectors.

    Research Areas: cell biology, cancer, retrotransposons, DNA, genomics, mental disorders

    Lab Website

    Principal Investigator

    Haig Kazazian, M.D.

    Department

    Pediatrics

  • Herschel Wade Lab

    The emergence of structural genomics, proteomics and the large-scale sequencing of many genomes provides experimental access to regions of protein sequence-structure-function landscapes which have not been explored through traditional biochemical methods. Protein structure-function relationships can now be examined rigorously through the characterization of protein ensembles, which display structurally convergent--divergent solutions to analogous or very similar functional properties.

    In this modern biochemical context, the Herschel Wade Lab will use protein libraries, chemistry, biophysics, molecular biology and structural methods to examine the basis of molecular recognition in the context of several important biological problems, including structural and mechanistic aspects of multi-drug resistance, ligand-dependent molecular switches and metal ion homeostasis.

    Research Areas: biophysics, biochemistry, proteomics, genomics, drugs, molecular biology

  • Hey-Kyoung Lee Lab

    The Hey-Kyoung Lee Lab is interested in exploring the cellular and molecular changes that happen at synapses to allow memory storage. We use various techniques, including electrophysiological recording, biochemical and molecular analysis, and imaging, to understand the cellular and molecular changes that happen during synaptic plasticity.

    Currently, we are examining the molecular and cellular mechanisms of global homeostatic synaptic plasticity using sensory cortices as model systems. In particular, we found that loss of vision elicits global changes in excitatory synaptic transmission in the primary visual cortex. Vision loss also triggers specific synaptic changes in other primary sensory cortices, which we postulate underlies sensory compensation in the blind. One of our main research goals is to understand the mechanisms underlying such cross-modal synaptic plasticity.

    We are also interested in elucidating the events that occur in diseased brains. In collaboration with othe...r researchers, we are analyzing various mouse models of Alzheimer's disease, especially focusing on the possible alterations in synaptic plasticity mechanisms.
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    Research Areas: biochemistry, synaptic plasticity, memory, imaging, vision, molecular biology, Alzheimer's disease

    Principal Investigator

    Hey-Kyoung Lee, Ph.D.

    Department

    Neuroscience

  • Holland Lab

    Research in the Holland Lab focuses on the molecular mechanisms that control accurate chromosome distribution and the role that mitotic errors play in human health and disease. We use a combination of chemical biology, biochemistry, cell biology and genetically engineered mice to study pathways involved in mitosis and their effect on cell and organism physiology. One of our major goals is to develop cell and animal-based models to study the role of cell-division defects in genome instability and tumorigenesis.

    Research Areas: cancer, genomics, molecular biology

  • Inoue Lab

    Complexity in signaling networks is often derived from co-opting one set of molecules for multiple operations. Understanding how cells achieve such sophisticated processing using a finite set of molecules within a confined space--what we call the "signaling paradox"--is critical to biology and engineering as well as the emerging field of synthetic biology.

    In the Inoue Lab, we have recently developed a series of chemical-molecular tools that allow for inducible, quick-onset and specific perturbation of various signaling molecules. Using this novel technique in conjunction with fluorescence imaging, microfabricated devices, quantitative analysis and computational modeling, we are dissecting intricate signaling networks.

    In particular, we investigate positive-feedback mechanisms underlying the initiation of neutrophil chemotaxis (known as symmetry breaking), as well as spatio-temporally compartmentalized signaling of Ras and membrane lipids such as phosphoinositides. In parallel,... we also try to understand how cell morphology affects biochemical pathways inside cells. Ultimately, we will generate completely orthogonal machinery in cells to achieve existing, as well as novel, cellular functions. Our synthetic, multidisciplinary approach will elucidate the signaling paradox created by nature. view more

    Research Areas: biochemistry, cell biology, chemotaxis, cancer, signaling paradox, signaling networks, molecular biology, synthetic biology

    Lab Website

    Principal Investigator

    Takanari Inoue, Ph.D.

    Department

    Cell Biology

  • Institute for Computational Medicine

    The Institute for Computational Medicine's mission is to develop quantitative approaches for understanding the mechanisms, diagnosis and treatment of human disease through biological systems modeling, computational anatomy, and bioinformatics. Our disease focus areas include breast cancer, brain disease and heart disease.

    The institute builds on groundbreaking research at both the Johns Hopkins University Whiting School of Engineering and the School of Medicine.

    Research Areas: breast cancer, systems biology, brain, biomedical engineering, cardiology, bioinformatics, computational anatomy

  • James Barrow Laboratory

    The James Barrow Laboratory studies drug discovery at the Lieber Institute. He leads research related to medicinal chemistry, biology, and drug metabolism, with the goal of validating novel mechanisms and advancing treatments for disorders of brain development.

    Research Areas: brain development, drugs, chemistry, biology

  • Jantzie Lab

    Dr. Jantzie, associate professor, received her Ph.D. in Neurochemistry from the University of Alberta in 2008. In 2013 she completed her postdoctoral fellowship in the Department of Neurology at Boston Children's Hospital & Harvard Medical School and became faculty at the University of New Mexico. Dr. Jantzie then joined the faculty Departments of Pediatrics (Neonatal-Perinatal Medicine) and Neurology at Johns Hopkins University and the Kennedy Krieger Institute in January 2019. Her lab investigates the pathophysiology of encephalopathy of prematurity, and pediatric brain injury common to infants and toddlers. Dr. Jantzie is dedicated to understanding disease processes in the developing brain as a means to identifying new therapeutic strategies and treatment targets for perinatal brain injury. Her lab studies neural substrates of cognition and executive function, inhibitory circuit formation, the role of an abnormal intrauterine environment on brain development, mechanisms of neurorepa...ir and microglial activation and polarization. Using a diverse array of clinically relevant techniques such as MRI, cognitive assessment, and biomarker discovery, combined with traditional molecular and cellular biology, the Jantzie lab is on the front lines of translational pediatric neuroscience.? view less

    Research Areas: Neonatology, neuroscience

    Principal Investigator

    Lauren Jantzie, Ph.D.

    Department

    Pediatrics

  • Jeremy Nathans Laboratory

    The Jeremy Nathans Laboratory is focused on neural and vascular development, and the role of Frizzled receptors in mammalian development. We use gene manipulation in the mouse, cell culture models, and biochemical reconstitution to investigate the relevant molecular events underlying these processes, and to genetically mark and manipulate cells and tissues. Current experiments are aimed at defining additional Frizzled-regulated processes and elucidating the molecular mechanisms and cell biologic results of Frizzled signaling within these various contexts. Complementing these areas of biologic interest, we have ongoing technology development projects related to genetically manipulating and visualizing defined cell populations in the mouse, and quantitative analysis of mouse visual system function.

    Research Areas: vascular development, biochemistry, cell biology, neurodevelopment, genomics, Frizzled receptors, neuroscience

  • Joel Pomerantz Laboratory

    The Pomerantz Laboratory studies the molecular machinery used by cells to interpret extracellular signals and transduce them to the nucleus to affect changes in gene expression. The accurate response to extracellular signals results in a cell's decision to proliferate, differentiate or die, and it's critical for normal development and physiology. The dysregulation of this machinery underlies the unwarranted expansion or destruction of cell numbers that occurs in human diseases like cancer, autoimmunity, hyperinflammatory states and neurodegenerative disease.

    Current studies in the lab focus on signaling pathways that are important in innate immunity, adaptive immunity and cancer, with particular focus on pathways that regulate the activity of the pleiotropic transcription factor NF-kB.

    Research Areas: immunology, neurodegenerative disorders, cancer, autoimmune, hyperinflammatory states, molecular biology

    Principal Investigator

    Joel Pomerantz, Ph.D.

    Department

    Biological Chemistry

  • John Schroeder Lab

    The John Schroeder Lab focuses on understanding the role human basophils and mast cells play in allergic reactions, as it relates not only to their secretion of potent inflammatory mediators (e.g., histamine and leukotriene C4) but also to their production of pro-inflammatory cytokines. We have long utilized human cells rather than cell lines in order to address the parameters, signal transduction and pharmacological aspects underlying clinically relevant basophil and mast cell responses. As a result, the lab has established protocols for rapidly isolating large numbers of basophils at high purity from human blood and for growing culture-derived mast cells/basophils from human progenitor cells. A variety of assays and techniques are also in place for concurrently detecting cytokines and mediators following a wide range of stimuli. These have facilitated the in vitro testing of numerous anti-allergic drugs for inhibitory activity on basophil and mast cell activation. The lab also studie...s counter-regulation between the IgE and innate immune receptors on human immature dendritic cell subtypes. view more

    Research Areas: cell biology, allergies, inflammation

    Principal Investigator

    John Schroeder, Ph.D.

    Department

    Medicine

  • John T. Isaacs Laboratory

    While there has been an explosion of knowledge about human carcinogenesis over the last 2 decades, unfortunately, this has not translated into the development of effective therapies for either preventing or treating the common human cancers. The goal of the Isaacs’ lab is to change this situation by translating theory into therapy for solid malignancies, particularly Prostate cancer. Presently, a series of drugs discovered in the Isaacs’ lab are undergoing clinical trials in patients with metastatic cancer.

    The ongoing drug discovery in the lab continues to focus upon developing agents to eliminate the cancer initiating stem cells within metastatic sites of cancer. To do this, a variety of bacterial and natural product toxins are being chemically modified to produce “prodrugs” whose cytotoxicity is selectively activated by proteases produced in high levels only by cancer cells or tumor associated blood vessel cells. In this way, these prodrugs can be given systemically to metastati...c patients without un-acceptable toxicity to the host while being selectively activated to potent killing molecules within metastatic sites of cancer.

    Such a “Trojan Horse” approach is also being developed using allogeneic bone marrow derived Mesenchymal Stem cells which are genetically engineered to secrete “prodrugs” so that when they are infused into the patient, they selectively “home” to sites of cancers where the appropriate enzymatic activity is present to liberate the killing toxin sterilizing the cancer “neighborhood”.
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    Research Areas: anti-cancer drugs, stem cell biology

    Lab Website

    Principal Investigator

    John Isaacs, Ph.D.

    Department

    Oncology

  • Jun O. Liu Laboratory

    The Jun O. Liu Laboratory tests small molecules to see if they react in our bodies to find potential drugs to treat disease. We employ high-throughput screening to identify modulators of various cellular processes and pathways that have been implicated in human diseases from cancer to autoimmune diseases. Once biologically active inhibitors are identified, they will serve both as probes of the biological processes of interest and as leads for the development of new drugs for treating human diseases. Among the biological processes of interest are cancer cell growth and apoptosis, angiogenesis, calcium-dependent signaling pathways, eukaryotic transcription and translation.

    Research Areas: cancer, autoimmune, eukaryotic cells, drugs, cellular signaling, pharmacology, calcium-dependent signaling pathways, molecular biology, angiogenesis

  • Jungsan Sohn

    Dr. Sohn's lab is interested in understanding how biological stress-sensors are assembled, detect danger signals and initiate stress response.

    Innate immunity is the first line of defense against invading pathogens in higher eukaryotes. We are using in vitro quantitative biochemical assays and mutagenesis and x-ray crystallography to investigate the underlying operating principles of inflammasomes, a component of the innate immune system, to better understand biological stress sensors.

    Research Areas: immunology, cell biology, cancer, eukaryotes, stress sensors

  • Kalina Hristova Lab

    The Kalina Hristova Lab investigates the structure and assembly of biological membranes. Our team conducts research on the structural and thermodynamic principles that enable membrane protein folding and signal transduction across biological membranes. Part of our work has involved developing new tools to study the structure of thermally disordered fluid membranes and the energetics of biomolecular interactions in biological membranes. Through our studies, we have established a better understanding of the physical principles behind complex biological processes and the mechanisms of disease development in humans.

    Research Areas: membranes, proteins, biology

    Principal Investigator

    Kalina Hristova, Ph.D.

    Department

    Biomedical Engineering

  • Karakousis Lab

    The Karakousis Lab is primarily focused on understanding the molecular basis of Mycobacterium tuberculosis persistence and antibiotic tolerance. A systems biology-based approach, including the use of several novel in vitro and animal models, in combination with transcriptional, proteomic, genetic, imaging, and computational techniques, is being used to identify host cytokine networks responsible for immunological control of M. tuberculosis growth, as well as M. tuberculosis regulatory and metabolic pathways required for bacillary growth restriction and reactivation. In particular, we are actively investigating the regulatory cascade involved in the mycobacterial stringent response. Another major focus of the lab is the development of host-directed therapies for TB, with the goal of shortening treatment and improving long-term lung function. Additional research interests include the development of novel molecular assays for the rapid diagnosis of latent TB infection and active TB diseas...e, and for the detection of drug resistance. view more

    Research Areas: diagnostics, persistence, infectious disease, Mycobacterium tuberculosis, host-directed therapy, latency, drugs, antibiotics, tuberculosis

    Lab Website

    Principal Investigator

    Petros Karakousis, M.D.

    Department

    Medicine

  • Karen Reddy Laboratory

    The focus of the research in the Reddy Laboratory is to begin to understand how the nuclear periphery and other subcompartments contribute to general nuclear architecture and to specific gene regulation. Our research goals can be broken down into three complementary areas of research: understanding how genes are regulated at the nuclear periphery, deciphering how genes are localized (or "addressed") to specific nuclear compartments and how these processes are utilized in development and corrupted in disease.

    Research Areas: biological chemistry, cell biology, nuclear structure, epigenetics, gene regulation

    Principal Investigator

    Karen Reddy, Ph.D.

    Department

    Biological Chemistry

  • Katherine Wilson Lab

    Research in the Wilson Lab focuses on three components of nuclear lamina structure: lamins, LEM-domain proteins (emerin), and BAF.

    These three proteins all bind each other directly, and are collectively required to organize and regulate chromatin, efficiently segregate chromosomes and rebuild nuclear structure after mitosis. Mutations in one or more of these proteins cause a variety of diseases including Emery-Dreifuss muscular dystrophy (EDMD), cardiomyopathy, lipodystrophy and diabetes, and accelerated aging.

    We are examining emerin's role in mechanotransduction, how emerin and lamin A are regulated, and whether misregulation contributes to disease.

    Research Areas: cell biology, Emery-Dreifuss muscular dystrophy (EDMD), accelerated aging, chromatin, diabetes, genomics, emerin, nuclear lamina, lipodystrophy, cardiomyopathy

    Principal Investigator

    Katherine Wilson, Ph.D.

    Department

    Cell Biology

  • Laboratory of Richard L. Huganir

    The Laboratory of Richard L. Huganir is interested in the mechanisms that regulate synaptic transmission and synaptic plasticity. Our general approach is to study molecular and cellular mechanisms that regulate neurotransmitter receptors and synapse function. We are currently focusing our efforts on the mechanisms that underlie the regulation of the glutamate receptors, the major excitatory neurotransmitter receptors in the brain.

    Research Areas: synapses, neurotransmitters, cell biology, brain, molecular biology

    Lab Website

    Principal Investigator

    Richard Huganir, Ph.D.

    Department

    Neuroscience

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