Department of Genetics
The Genetics Graduate Core Course Series
1998-1999
The organization of Genetics 551, 552 and 553 for Autumn, Winter and Spring is given below. These courses are not intended to present a comprehensive overview of the field. Rather, they emphasize genetic approaches to the analysis of biological processes and critical reading of the original research literature. Several of the sections will focus on model systems, but human genetics will also be included in the winter quarter.
The small class size permits good student-teacher interaction. Class sessions will include lectures, as well as discussions of original papers and experimental approaches. Evaluation of students will be based on short written assignments designed to develop skills in critical evaluation of the research literature and in the design of research proposals. We encourage students to take the three quarter sequence, but each course often can, depending on the student's background, be taken independently.
James Thomas - Genetic Dissection of Biological Processes
Colin Manoil - Genetics of Protein Structure, Function, and Evolution
Breck Byers - Mechanisms in Meiosis
Carol Sibley - Genetic Analysis of Drug Resistance in Human Pathogens
Robert Braun - Genetic Analysis in the Mouse
Walt Fangman - Chromosome Replication
Part 1: GENETIC DISSECTION OF BIOLOGICAL PROCESSES - James Thomas
Genetic analysis is a powerful approach to the dissection of complex biological processes. Selective removal or alteration of specific proteins allows inferences about processes too complex to study effectively with biochemical approaches. Emphasis will be on the logic of functional inference from genetic perturbations as illustrated with two systems:
YEAST MATING PHEROMONE RESPONSE: Analysis of single and double mutant phenotypes to infer a functional pathway. Methods include complementation tests, epistasis analysis, use of activating mutations, gene overexpression, and two-hybrid analysis of protein interactions.
C. elegans PROGRAMMED CELL DEATH: This section will emphasize analysis that is relatively specific to diploids and multicellular organisms. These will include uses and interpretation of dominant mutations, redundancy, genetic mosaic analysis, expression patterns, and genetic enhancer screens.
Part 2: GENETICS OF PROTEIN STRUCTURE, FUNCTION AND EVOLUTION - Colin Manoil
The course aims to provide a framework for thinking about biological functions of proteins based on structural principles. Genetic studies will be emphasized, particularly those illustrating how mutations can screw things up.
Topics:
Part 1: MECHANISMS IN MEIOSIS - Breck Byers
Understanding how genes are transmitted between generations demands knowledge of the basis for meiotic linkage and recombination. The cytological and biochemical complexities of the evolutionarily fundamental process of meiosis have proven amenable to mutational analysis. Questions include:
What is the cytological basis for linkage and for the faithful disjunction of homologues in meiosis?
How does one undertake the genetical dissection of molecular mechanisms that are required for synapsis, recombination, and chromatid segregation?
Exceptions that prove the rule: How has the reproductive mechanism evolved to function successfully in a real biological world of rearrangements, polyploidy, and heterosis?
Part 2: GENETIC ANALYSIS OF DRUG RESISTANCE IN HUMAN PATHOGENS - Carol Sibley
Pathogens exhibit a wide range of mechanisms for evading host defenses and therapeutic interventions. Genetic approaches have been the key to many of the recent advances in our understanding of these mechanisms. We will focus on HIV and Mycobacterium tuberculosis to understand the key role that genetic analysis has played in this field.
What are the properties of M. tuberculosis and HIV that make them pathogenic for humans? How are drugs designed to combat these pathogens?
What are the genetic mechanisms by which these pathogens become resistant to therapeutic drugs? What selective pressures affect the emergence of drug-resistant populations of parasites?
How can genetics be used to understand and circumvent the development of drug resistance?
Part 1: GENETIC ANALYSIS OF THE MOUSE - Robert Braun
Selected topics in mammalian genetics will be discussed in depth. Each topic will begin with an historical perspective and conclude with the most recent understanding of the subject . Emphasis will be placed on experimental genetic analysis of the phenomena. The goal is to acquire a rigorous working knowledge of the genetic methodologies and a sound appreciation of the relevant mouse biology associated with each topic.
Topics will include:
Imprinting
Part 2: CHROMOSOME REPLICATION - Walt Fangman
Special considerations in the genetic analysis of chromosome replication will be covered.
THE REPLICATION FORK AS A MOLECULAR MACHINE: The replication fork apparatus is a multiprotein machine rivaling the ribosome in complexity. Observations on aberrant replication in mutants provides a general view of how the machinery works. However, reconstruction of the details of the machine in vitro is be guided by attainment of the speed and fidelity of the in vivo process.
THE NATURE OF REPLICATIONS ORIGINS AND THE INITIATION PROCESS. Identification and analysis of replication origins, the cis-acting elements, require unique approaches. Detection by cloning uses a plasmid assay and loss of function means failure of maintenance. Assessment of origin activity in the chromosome requires special assays that detect the small, two-fold increase in specific sequences.
REGULATION OF INITIATION WITHIN THE CELL CYCLE. A variety of tools have been developed to reveal the many regulatory steps of the cell cycle. Recent studies have shown that chromosome replication is exquisitely integrated into the cycle. The existence of redundant control elements requires special experimental approaches.