Current research in the Sean T. Prigge Lab explores the biochemical pathways found in the apicoplast, an essential organelle found in malaria parasites, using a combination of cell biology and genetic, biophysical and biochemical techniques. We are particularly focused on the pathways used for the biosynthesis and modification of fatty acids and associated enzyme cofactors, including pantothenate, lipoic acid, biotin and iron-sulfur clusters. We want to better understand how the cofactors are acquired and used, and whether they are essential for the growth of blood-stage malaria parasites.

Dr. Sidhaye is interested in improving the care of persons with cystic fibrosis, type 1 diabetes mellitus and hospitalized person with diabetes. research topics include bone health of persons with CF undergoing lung transplant, CF-related diabetes mellitus, Care of persons with type 1 diabetes mellitus transitioning from pediatrics to adult specialty clinics, Management of hospitalized persons with diabetes.

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 in the Clifton O. Bingham III Lab focuses on defining clinical and biochemical disease phenotypes related to therapeutic responses in rheumatoid arthritis and osteoarthritis; developing rational clinical trial designs to test new treatments; improving patient-reported outcome measures; evaluating novel imaging modalities for arthritis; and examining the role of oral health in inflammatory arthritis.

The George Rose Lab investigates protein folding, the spontaneous disorder transition that takes place under physiological conditions. The protein polymer is flexible in its unfolded state but takes on a unique native, three-dimensional form when folded. We propose that the folded state is selected from a set number of structural possibilities, each corresponding to either a distinct hydrogen-bonded arrangement of ??helices or a strand of ??sheet.

The Goley Lab is broadly interested in understanding cellular organization and dynamic reorganization, with particular focus on the roles of the cytoskeleton in these phenomena. We use cell biological, biochemical, genetic and structural approaches to dissect cytoskeletal processes with the aim of understanding how they work in molecular detail. Currently, we are focused on investigating the mechanisms underlying cytokinesis in bacteria. A deep understanding of cytoskeletal function in bacteria will aid in the identification of targets for novel antibiotic therapies and in efforts in synthetic biology.

The Berger Lab's research is focused on understanding how multi-subunit assemblies use ATP for overcoming topological challenges within the chromosome and controlling the flow of genetic information. A long-term goal is to develop mechanistic models that explain in atomic level detail how macromolecular machines transduce chemical energy into force and motion, and to determine how cells exploit and control these complexes and their activities for initiating DNA replication, shaping chromosome superstructure and executing myriad other essential nucleic-acid transactions. Our principal approaches include a blend of structural (X-ray crystallography, single-particle EM, SAXS) and solution biochemical methods to define the architecture, function, evolution and regulation of biological complexes. We also have extensive interests in mechanistic enzymology and the study of small-molecule inhibitors of therapeutic potential, the development of chemical approaches to trapping weak protein/protein and protein/nucleic acid interactions, and in using microfluidics and single-molecule approaches for biochemical investigations of protein dynamics.

Research in the Bradley Undem Lab centers around the hypothesis that the peripheral nervous system is directly involved in the processes of inflammation. This hypothesis is being studied primarily in the central airways and sympathetic ganglia. We are addressing this in a multidisciplinary fashion, using pharmacological, electrophysiological, biochemical and anatomical methodologies.

The Devreotes Laboratory is engaged in genetic analysis of chemotaxis in eukaryotic cells. Our long-term goal is a complete description of the network controlling chemotactic behavior. We are analyzing combinations of deficiencies to understand interactions among network components and carrying out additional genetic screens to identify new pathways involved in chemotaxis. A comprehensive understanding of this fascinating process should lead to control of pathological conditions such as inflammation and cancer metastasis.

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.