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Scott
Mohr
Professor
Biophysical
Chemistry and Bioinformatics
Office:
SCI 360
Phone: 617-353-2172
Fax: 617-353-6466
E-mail: mohr@bu.edu
Office
hours: By
appointment
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| Degrees |
- B.A. (summa cum laude), Williams College, 1962
- M.A., Harvard University, 1966
- Ph.D., Harvard University, 1968
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| Honors |
- Sigma Xi
- NIH Postdoctoral Fellow, 1968-1969
- Danforth Fellow, 1962-1968
- NSF Fellow, 1962-1964
- Phi Beta Kappa, 1961
- National Merit Scholar, 1958-1962
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| Teaching |
- CC 105 - Core Curriculum, Natural Science I (Evolution of Life
and Intelligence)
- CC 106 - Core Curriculum, Natural Science II (Evolution of the
Physical Universe)
- BF 527 - Bioinformatics Applications
- MB 721 - Graduate Biochemistry
- MB 722 - Advanced Biochemistry
- CH 724 - Special Topics in Biochemistry
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| Research/Activities |
- I have a longstanding interest in the conformations of nucleic
acids and the ways in which they interact with other molecules
(both proteins and low-molecular-weight ligands). This has led
to publications on the fast kinetics of ligand binding, the conformation
of nucleic acids as influenced by other macromolecules (including
compaction to the "psi" state) and a structural model
for the covalent complex between benzo[a]pyrene diol epoxide and
DNA. My students and I have demonstrated the DNA-conformation-modulating
properties of small, acid-soluble spore proteins (SASPs) from Gram-positive
bacteria.
- The interest in DNA-binding proteins has led me to work on nuclear
receptors and we have published homology-extension models of the
human estrogen receptor as well as the related vitamin D receptor.
I also have supervised the synthesis of a number of potential photodynamic
therapy agents targeted to the estrogen, androgen and vitamin D
receptors. This work is ongoing.
- In the last three years I have reoriented most of my research
interests towards bioinformatics in collaboration with Professor
Temple F. Smith of the Boston University Department of Biomedical
Engineering. In addition to the homology modelling described above,
I have pursued questions regarding the overall layout of chromosomal
DNA as revealed by strand asymmetry in base composition and gene
locations and I have created a functional database of mitochondrial
proteins for yeast (C. cerevisiae). This work involves dissecting
genes into their constituent protein domains, constructing phylogenetic
trees for these domains, and identifying "missing" genes
which are required for mitochondrial function, but not yet annotated
in the database(s). We have employed prior-based profiles to identify
more than 2000 homologs for ca. 415 mitoproteins, and the phylogenetic
trees constructed with these homologs serve to define the evolutionary
origins of the yeast mitochondrial "proteome."
- I am also collaborating with Dr. Joel Graber and Professor Charles
Cantor in informatic analysis of the 3'-end-processing (cleavage
and polyadenylation) sites in eukaryotic mRNAs.
- I currently direct a Chemistry Graduate Student (Taner Kaya)
and I codirect several Pharmacology and Engineering graduate students
(with T. Smith). Futher description of my active research in bioinformatics,
including a list of recent publications, is described at the home
of the BioMolecular Engineering
Research Center.
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