Research
Neuroscience & Aging
As our population ages, mainly due to advances in medical research, we are faced with greater numbers of individuals above the age of 65 and a plethora of age-related diseases. People above 65 years old have increased risk of developing disorders such as atherosclerosis, heart disease, diabetes, cancer, a list of neurodegenerative diseases including Alzheimer’s and Parkinson’s, as well as other conditions caused by the deposition of aggregated amyloid protein fibrils, collectively called amyloidoses. The Department of Biochemistry offers graduate students exciting opportunities to study age-related diseases in a variety of cellular and animal systems.
Faculty conducting research into these areas include:
Carmela Abraham, PhD, Normal aging and Alzheimer’s
Lawreen Connors, PhD, Systemic amyloidosis
Catherine Costello, PhD, Amyloidosis
David A. Harris, MD, PhD, Prion diseases
Peter Polgar, PhD, Vascular disease and aging
Michael Sherman, PhD, Amyloidosis in Huntington’s
Signal Transduction & Cancer
Cancer is a class of diseases (also known as malignant neoplasms) in which normal cellular homeostasis is lost and a group of abnormal cells divide without control or stop responding to normal restraint in growth. In addition to uncontrolled growth, these cells can also display invasion (intrusion on and destruction of adjacent tissues) and sometimes metastasis. In the U.S., cancer accounts for 1 of every 4 deaths. The American Cancer Society estimated that this year, about 565,650 Americans are expected to die of cancer, more than 1,500 people a day. Nearly all cancers are caused by abnormalities in the genetic material of the transformed cell. These abnormalities can either be inherited genetically (about 10% of cases) or occur sporadically due to the effects of carcinogens, such as tobacco smoke, radiation, chemicals, or infectious agents.
Genetic abnormalities found in cancer typically affect two general classes of genes: oncogenes and tumor suppressor genes. Cancer-promoting oncogenes are typically activated in cancer cells, giving those cells new properties, such as hyperactive growth and division, protection against programmed cell death, loss of respect for normal tissue boundaries, and the ability to become established in diverse tissue environments. Inactivation of tumor suppressor genes in cancer cells can result in the loss of normal functions in those cells, such as accurate DNA replication, control over the cell cycle, orientation and adhesion within tissues, and interaction with protective cells of the immune system. Additional pathways that contribute to tissue homeostasis are regulated by genes that control DNA damage, apoptosis, senescence, and the activity of carcinogens.
Faculty conducting research into these areas include:
Kathrin H. Kirsch, PhD, Cell signaling
Zhijun Luo, PhD, Tumor growth and metabolism
Michael Sherman, PhD, Cell senescence, cell stress
Zhi-Xiong Jim Xiao, PhD, Tumor suppressor genes
ECM/Cellular Injury
Critical to the evolution of multicellular organisms was acquiring the ability to synthesize connections between cells. The extracellular matrix (ECM) integrates cells into tissues, tissues into organs, and organs into the organism. The ECM is an extension of the cell and participates actively in functions including development, migration, proliferation, metabolism and stabilization of tissue structure. Just as connective tissue was critical to the evolution of multicellular organisms, so too has evolution of multicellular organisms left them dependent upon connective tissue so that the ECM is associated with a wide range of diseases.
Cardiovascular disease is the number one cause of death in the United States. Vascular injury leads to chronic inflammation of the vasculature, causing atherosclerosis or lesion formation that leads to cardiovascular events. Likewise, injury and inflammation in the lung compromise its properties. Researchers in the Department of Biochemistry have identified basic elements of the mechanisms of vascular injury and lung fibrosis that contribute to cellular dysfunction, with emphasis on the role of the extracellular milieu.
Faculty conducting research into these areas include:
Matthew Layne, PhD, Transcriptional regulation, atherosclerosis, lung fibrosis
Matthew Nugent, PhD, Glycosaminoglycans, atherosclerosis, chronic obstructive pulmonary disease
Peter Polgar, PhD, Receptor structure/function
Barbara Schreiber, PhD, Elastin, serum amyloid A, atherosclerosis
Barbara Smith, PhD, Collagen, transcriptional regulation, atherosclerosis, lung fibrosis
Phillip Stone, PhD, Elastin, pulmonary emphysema
Vickery Trinkaus-Randall, PhD, glycosaminoglycans
Joe Zaia, PhD, glycosaminoglycans
Metabolism, Obesity/Diabetes
The modern world is in the midst of an obesity epidemic that is growing to the extent that, in 2003–2004, 32% of U.S. adults were obese and more than 50% were overweight, numbers that have been growing ever since. This dramatic increase in body weight has led to a significant upsurge in the number of individuals with obesity-related disorders, including Type-2 Diabetes, cardiovascular disease, hypertension, and dyslipidemia. A worrying trend is that adolescents are also becoming obese and, consequently, are succumbing to metabolic diseases that a decade ago only occurred in adults. Awareness of this trend has stirred a significant effort to understand more about the link between adiposity and metabolic disease.
Physiological control of metabolism involves an elaborately coordinated process involving cross-talk between several organs and tissues that regulate the production of hormones and the metabolism of lipids and glucose. In an effort to gain a greater understanding of the control of energy balance, investigators in the Department of Biochemistry are attempting to identify the molecular mechanisms within each tissue that contribute to the overall control of metabolism. This research has included defining the signaling pathways and transcriptional events that specify production and action of metabolically important hormones and cytokines.
Faculty conducting research into these areas include:
Stephen R. Farmer, PhD, Transcriptional control of adipocyte formation and function
Konstantin Kandror, PhD, Cell biological aspects of insulin signaling
Paul F. Pilch, PhD, Vesicular traffic related to insulin action, caveolae, lipodystrophies
Barbara Schreiber, PhD, Inflammation and smooth muscle cell lipid metabolism
Proteomics & Glycomics
Proteins, carbohydrates, and lipids serve both structural and signaling roles; their identities and distributions vary with growth, development, and disease. At cell and membrane surfaces and in the extracellular space, the interactions of cells are regulated by these classes of molecules. Within cells, they govern traffic between compartments.
Proteomics, glycomics, and lipidomics investigate the phenotypes with respect to these compound classes in a given cell, tissue, or organism, and the dynamics of their expression related to biological transformation, thus leading to understanding of intracellular and intercellular processes at the level of expression rather than extrapolation from genetic information. These studies are relevant to metabolic disorders and diseases such as diabetes, oxidative stress, cancers, neurological disorders, infectious diseases, and atherosclerosis, as well as normal development and aging.
Faculty conducting research into these areas include:
Catherine Costello, PhD, Proteins, glycans and lipids
Cheng Lin, PhD, Proteins, glycans
Joseph Zaia, PhD, Glycosaminoglycans, protein-GAG interactions
Development
Directed cell migration plays a critical role in embryonic development. To migrate in a directed way, a cell must be able to detect and move towards a source of an attractive signal (chemoattractant) or away from a repulsive one. This requires the creation of spatially asymmetrical signaling that leads to extension of leading edge protrusions such as lamellipodia, the generation of traction and force, and a balance of detachment and attachment to neighboring cells and the extracellular matrix. Thus, there is a constant need for the cell to coordinate a variety of extracellular and intracellular activities both spatially and temporally. The challenge is to understand how the cell compartmentalizes, yet cooperatively couples, these activities to drive directed cell movement and how upstream signaling controls this behavior. Toward this end, investigators in the Department of Biochemistry study growth factor signaling that is modulated by specific extracellular matrix proteins and induces specific changes in cellular architecture. In vivo and 3-dimensional ex vivo models are studied in which growth factor signaling and downstream effectors are modulated through introduction of mutant forms, and resultant morphology and cell migration are analyzed.
Faculty conducting research into these areas include:
Matthew Nugent, PhD, Proteoglycans, growth factors, ECM
Karen Symes, PhD, Cell migration, notochord development, PDGF signaling
Vickery Trinkaus-Randall, PhD, EGF receptor, glycosaminoglycans
Admissions
Requirements for Admission
Students who have completed an undergraduate degree—usually with a major in biochemistry, biology, or chemistry—and have taken courses in general biology, general chemistry, organic chemistry, physical chemistry, and calculus may apply for either an MA or a PhD in Biochemistry. Some coursework in biochemistry is also recommended. Students who have completed an MA degree in biochemistry or a closely related field can apply for a post-MA PhD program. MD/PhD students are also eligible for admission.
A part-time MA program is available to qualified applicants who are employees in laboratories of faculty within the Department of Biochemistry at Boston University School of Medicine (contact the Director of Graduate Studies for further information). A student currently enrolled in an MA program in the Department of Biochemistry may apply for the PhD program if he/she has completed 12 or more graduate credits including GMS MS 753, Bl 755, Bl 756 (and excluding BI 854) and has obtained a GPA of 3.25 or better. In addition, the student must have taken and successfully passed the Written Qualifying Examination in the Department of Biochemistry.
The deadline for submission of applications and supportive credentials for admission for the fall semester is January 1. Late applications will be considered with prior approval of the department chair or program director. Contact the Director of Graduate Studies for additional information.
Student Life
Students are an important and integral part of any educational department and this is no different at BUSM’s Department of Biochemistry. In order to be more involved in departmental affairs, students of the department have created the Biochemistry Student Organization (BSO) to foster the academic and professional development of the biochemistry student body. In addition to this primary mission, the BSO also organizes and sponsors various social and academic events for students and the department.
