Our laboratory conducts basic and translational research aimed at better understanding the pathogenesis of multiple sclerosis (MS) and the role of the immune system in CNS disease, particularly the processes that drive progressive disability such as neurodegeneration and remyelination failure. We currently have three parallel research programs: 1. Metabolism as a modulator of MS: We are studying how basic metabolic pathways regulate the immune system and how these pathways might be exploited to protect neurons and myelin-forming oligodendrocytes from injury. 2. Identifying pathways by which nitric oxide (NO) and other free radicals cause neuronal and axonal damage. Our lab is identifying specific signaling pathways initiated by NO and other free radicals that can be targeted by drugs to produce neuroprotection. 3. Modulating the innate immune system in MS: In collaboration with others at Johns Hopkins, we are studying ways to enhance the reparative functions of microglia while preventing maladaptive responses. This work has identified bryostatin-1 as a potential drug that may be re-purposed for this task.

Research in the Michael Matunis Lab focuses on the SUMO family of small ubiquitin-related proteins. We study the covalent conjugation of SUMOs to other cellular proteins, which regulates numerous processes needed for cell growth and differentiation, and which, when defective, can lead to conditions such as cancer, neurodegenerative disease and diabetes.

Research in the Michael Melia Lab focuses primarily on nocardia infections, Lyme disease and hepatitis C. Our studies have included key topics such as risk factors for incident infections during hepatitis C treatment, racial differences in eligibility for hepatitis C treatment and misdiagnosis of Lyme arthritis using the Borrelia burgdorferi immunoblot testing method. We also have a longstanding interest in medical education and work on curriculum to improve the quality of education for medical students and interns.

The Wolfgang Laboratory is interested in understanding the metabolic properties of neurons and glia at a mechanistic level in situ. Some of the most interesting, enigmatic and understudied cells in metabolic biochemistry are those of the nervous system. Defects in these pathways can lead to devastating neurological disease. Conversely, altering the metabolic properties of the nervous system can have surprisingly beneficial effects on the progression of some diseases. However, the mechanisms of these interactions are largely unknown. We use biochemical and molecular genetic techniques to study the molecular mechanisms that the nervous system uses to sense and respond to metabolic cues. We seek to understand the neurometabolic regulation of behavior and physiology in obesity, diabetes and neurological disease. Current areas of study include deconstructing neurometabolic pathways to understand the biochemistry of the nervous system and how these metabolic pathways impact animal behavior and physiology, metabolic heterogeneity and the evolution of metabolic adaptation.

Research interests in the Michelle Belantoni Lab include osteoporosis screening using heel ultrasonography and quality outcomes in post-acute care settings.

The Michelle Eakin Lab conducts research on behavioral science and adherence and asthma outcomes in inner-city children. Our studies into behavioral science have included exploring the impact of medication adherence on lung health outcomes in patients with cystic fibrosis, disparities in anti-hypertensive medication adherence in adolescents and other key topics. We also investigate methods for improving asthma care and treatment as well as health disparities among various ethnicities, particularly in pediatric patients.

The Mihaela Pertea Lab develops computational tools for RNA sequence analysis, gene finding, splice-site prediction and sequence-motif finding. Previous research projects led to the development of open-source software systems related to finding genes.

Research in the Mihail Zilbermint Lab focuses on diabetes, adrenal disease and thyroid disease. Recent areas of focus include pseudohypoaldosteronism type 1 related to novel variants of SCNN1B gene, genetic variance in the ARMC5 gene in primary macronodular adrenocortical hyperplasia and hyperaldosteronism due to de novo KCNJ5 mutation.

The Miho Iijima Laboratory works to make a further connection between cells' signaling events and directional movement. Our researchers have identified 17 new PH domain-containing proteins in addition to 10 previously known genes in the Dictyostelium cDNA and genome database. Five of these genes contain both the Dbl and the PH domains, suggesting these proteins are involved in actin polymerization. A PTEN homologue has also been identified in Dictyostelium that is highly conserved with the human gene. We are disrupting all of these genes and studying their roles in chemotaxis.

Directed by Alan R. Cohen MD, Carson-Spiro Professor of Neurosurgery, Oncology and Pediatrics, the laboratory is focused on developing novel instruments and approaches to enhance the safety and efficacy of neurosurgical procedures. Current investigations include work in microsurgery, endoscopy, image guidance and robotic surgery. A cadaveric Skills Lab offers training in neurosurgical techniques.