Courses

  • GRS CH 621: Biochemistry 1
    Introductory biochemistry. Protein structure and folding enzyme mechanisms, kinetics, and allostery; nucleic acid structure; macromolecular biosynthesis with emphasis on specificity and fidelity; lipids and membrane structure; bioenergetics; vitamins and coenzymes; introduction to intermediary metabolismvitamins and coenzymes; introduction to intermediary metabolism. Three hours lecture, four hours laboratory, one hour discussion. Same as GRS BI 621. Lecture and laboratory meet with CAS BI/CH 421.
  • GRS CH 622: Biochemistry 2
    Cell metabolism, with special emphasis on the uptake of food materials, the integration and regulation of catabolic, anabolic, and anaplerotic routes, and the generation and utilization of energy. Lectures include consideration of events in prokaryotic and eukaryotic organisms. Polysaccharides, energy storage and recognition; intermediary metabolism; lipid and isoprene metabolism; nitrogen metabolism; nucleotide metabolism; macromolecular biosynthesis with emphasis on specificity and fidelity in the mechanisms of RNA, DNA, and proteins synthesis. Three hours lecture, four hours laboratory, one hour discussion. Same as GRS BI 622. Lecture and laboratory meet with CAS BI/CH 422.
  • GRS CH 625: Enzymology: Mechanisms of Enzymatic Reactions
    Covers enzyme structure-function relationships. A tool-box of methods is presented, including kinetics (steady state and pre-steady state methods), isotope effects, stereo-chemical methods, site-directed mutagenesis, methods to replace natural with unnatural amino acids, mechanism based inhibitors.
  • GRS CH 626: Epigenetics
    Surveys protein post-translational modifications and DNA/RNA processing, including mechanistic enzymology of protein and DNA modifications, signal transduction induced by the modifications, and related practical applications.
  • GRS CH 627: RNA Structure and Function
    Chemical and structural biology of natural RNA molecules, including ribosomal RNA, catalytic RNA (ribozymes), siRNA (small interfering RNA), microRNA, long non-coding RNA, riboswitches, and CRISPR.
  • GRS CH 629: DNA Nanotechnology
    Structural biology of DNA. Synthetic DNA objects, DNA origami, DNA templated synthesis, and DNAzymes. The main focus is DNA in nanotechnology, not the involvement of DNA in cell and molecular biology.
  • GRS CH 631: Advanced Coordination Chemistry I: Structure and Bonding
    The interdependence of chemical bonding, spectroscopic characteristics, and reactivity properties of coordination compounds and complexes are described and formalized using the fundamental concept of symmetry, as applied to inorganic coordination complexes.
  • GRS CH 632: Advanced Coordination Chemistry II: Inorganic Reaction Mechanisms
    The mechanistic study of ligand substitution and electron transfer processes in coordination compounds are discussed in the context of basic molecular orbital theory. The connections between small molecule inorganic and biological macromolecular metal-catalyzed processes are presented.
  • GRS CH 633: Physical Methods for Inorganic and Bioinorganic Chemistry
    A discussion of the physical techniques for the study of structural, magnetic, and redox-active properties of transitional metal complexes. Techniques discussed include x-ray crystallography; x-ray absorption; vibrational, NMR, EPR, and Mossbauer spectroscopies; and electrochemistry.
  • GRS CH 634: Metallobiochemistry
    The roles of transition metals in biology are assessed by review of the structural, spectroscopic, and genetic aspects of metallobiochemistry. Metal import and trafficking; cofactor biogenesis; biocatalytic transformations in biochemistry; reactive oxygen species; the inorganic basis of life.
  • GRS CH 635: Synthetic Methodology in Inorganic Chemistry
    The descriptive chemistries of the metallic elements are surveyed to develop a broad knowledge of these elements and how to prepare their compounds and understand the resultant reactivities. Case studies are taken from older and recent literature sources.
  • GRS CH 641: Physical Organic Chemistry
    Physical fundamentals of organic chemistry. Thermodynamics, kinetics, molecular orbital theory, and theory of concerted reactions. Isotope effects, aromaticity, linear free energy relationships, acidity functions, photo- and free-radical chemistry.
  • GRS CH 642: Organic Reaction Mechanisms
    Fundamentals of organic reactions and their mechanisms. Covers advanced topics in organic chemistry, such as conformational analysis, stereoelectronic effects, and a wide range of classical and modern organic transformations.
  • GRS CH 643: Synthetic Methods of Organic Chemistry
    Organic synthesis strategies for total synthesis. Various approaches for organic molecules whose synthesis constitutes major contributions to organic and medicinal chemistry.
  • GRS CH 645: Transition Metal Chemistry
    Introduction to the concepts of transition metal-mediated reactions and mechanisms, including electronic structure and properties, reaction mechanisms, kinetics, organometallic compounds, catalytic reactions, and aspects of asymmetric catalysis.
  • GRS CH 651: Molecular Quantum Mechanics I
    Postulates of quantum mechanics with emphasis on chemical applications; application to model systems: particle in a box, harmonic oscillator, rigid rotor, hydrogen atom; tunneling; angular momentum theory, spin; ladder operators, computational methods.
  • GRS CH 652: Molecular Quantum Mechanics II
    The chemical bond; Huckel, molecular orbital, and valence bond theories; ab initio methods, density functional theory; Born-Oppenheimer approximation/breakdown; time-dependent processes; Fermi's golden rule; non-adiabaticity; time-dependent perturbation theory; computational methods.
  • GRS CH 653: Molecular Spectroscopy
    Theory of electromagnetic radiation-matter interactions; linear and nonlinear molecular spectroscopy, time and frequency domain spectroscopic techniques; molecular responses and dielectric relaxation processes; theory of NMR, ESR, microwave, IR, Raman, visible, and UV spectroscopies; computational methods.
  • GRS CH 655: Statistical Mechanics I
    Introduction to statistical mechanical fundamentals; ensemble theory, Fermi-Dirac, Bose-Einstein, Gibbs-Boltzmann statistics; computational methods, Monte Carlo, Molecular Dynamics, many-body quantum mechanical simulations, normal mode analysis; ergodic hypothesis, modern theories of liquids and biomolecules, thermodynamic perturbation theory, integral equations, Debye-Huckel theory.
  • GRS CH 699: Teaching College Chemistry I
    The goals, contents, and methods of instruction in chemistry. General teaching-learning issues. Required of all teaching fellows.

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