Transcript Kasparov
Refresher Course: Integrating Genomics Into Physiology Courses: A New Paradigm or Just More Information? Incorporating physiological genomics into an undergraduate physiology course. Sergey Kasparov University of Bristol, UK. [email protected] What is Physiological Genomics-1? Griffiths et al – Introduction to Genetic Analysis 8th ed. Chapter 12 – Genomics. “… Indeed the knowledge of entire genomes has revolutionized not only genetics but most fields of biological research. … this exciting new field broadly called genomics - the study of genomes in their entirety. “ “Functional Genomics uses various automated procedures to delineate networks of interacting genes active during some developmental process.” W.F. Boron & EL Boulpaep “Medical Physiology” 2003 Pg 4…> “Physiological Genomics is the Link Between the Organ and the Gene. Physiological genomics (or functional genomics) is a new branch of physiology devoted to understanding the roles of genes play in physiology. Traditionally physiologists have moved in reductionistic direction from organ to cell to molecule to gene. One of the most fascinating aspects of physiological genomics is that it has closed the circle and linked organ physiology directly with molecular biology…. In order to grasp the function of a gene product the physiologist must retrace his steps back up the reductionistic road and achieve an integrated understanding of that gene’s function at the level of cells, organs, and the whole body.” What is Physiological Genomics-2 ? Lodish et al. Molecular Cell Biology Starting from Pg 380 9.4 Genomics: Genome-wide Analysis of Gene Structure and Expression Key concepts: -The function of an unknown protein may be predicted based on the aminoacid similarity to the known ones… - BLAST searches protein databases for similarities with the known proteins… - Functional motifs may be identified… - A protein family may be identified within a range of available genomes… - Computer programmes search for open reading frames (> 100 codons)… - Microarrays… cluster analysis and so on… Journal of Physiology – a special issue in 2003 contained a set of papers all about Physiological Genomics A.W.Cowley Jr, The chief editor of the “Physiological Genomics” wrote an editorial called “Physiological Genomics: tools and concepts”. ”Physiological genomics is an emerging field that brings together disciplines of genomics and cell, organ and whole animal systems integrative physiology in an effort to attach function to the DNA sequences of complex living systems”. What is Physiological Genomics-3 ? This meeting: Symposium: Discovery of Genes for Polycystic Kidney Disease Symposium: Genomics of Circadian Clocks Symposium: Genomics of Transport and Sensory Functions Symposium: Imprinting, Development and the Programming of Adult Health Featured Topic: Complex Pathway of Function and Disease Deduced from the Whole Genome Perspective Featured Topic: Genetic Basis of Cardiopulmonary Disorders Symposium: Functional Genomics of Macromolecular Damage Responses and Environmental Stress Adaptation Featured Topic: Epithelial Genomics, Proteomics and Genetic Models Symposium: Genetic Determinants of Obesity and Metabolic Disease Symposium: Comparative Genomics of Blood Pressure Control: Genetic Maps in Humans, Rats and Mice Symposium: Comparative Genomics of the Lung Teaching Physiological Genomics to the Physiology Students in Bristol Our cohort of students: -NOT specialised in molecular biology or biochemistry… Some examples of the topics covered in Y1 and 2 -Physiological Genomics is one of the two Elements they do in Y3 -Class size in Y 2005 = 18 -Many of our students DO NOT continue as scientists, but take jobs related to biomedicine, for example with the scientific publishers or ??? Teaching Physiological Genomics to the Physiology Students in Bristol… A dream course… 1. Revision of the structure of genes, gene expression and basics of genetics 2. Bioinformatics and approaches to genome annotation and gene discovery 3. Comparative genomics and model organisms 4. Molecular high throughput systems for studies of gene function 5. Methods of Gene Expression analysis (high throughput vs high fidelity), microarrays. 6. Gene expression and genetic plasticity 7. Polymorphisms in experimental science and medicine 8. Epigenetics 9. Transgenic animals (including knockouts) 10.Other approaches to gene suppression (antisense, decoys, siRNA etc) and gene “loss-of-function” experiments (dominant negatives and similar approaches). 11.Somatic gene transfer (viral vectors) – application for physiological studies 12.Gene therapy 13.Safety and legal aspects of GM experimentation Module learning objectives On completion of the module, students will:Be able to describe a range of current molecular approaches used to investigate physiological functions at different levels of organisation, from single cell to whole body. Be familiar with the advantages of cross-species analysis for studies of gene function. Be aware of the rationales for the use of different molecular approaches, and the advantages and disadvantages of individual techniques. Be familiar of the application of the Functional Genomics to studies of the origins of human diseases. Be able to give examples of the recent publications where methods of physiological genomics have been successfully used. Understand and be able to explain molecular strategies used in drug development and rational drug design. Be able to compare gene therapy with conventional biomedical approaches to the treatment of diseases, and give examples of recent advances in gene therapy. The overall structure of our course (Element) STAR T FINIS H SESSIO N 10/01/2 005 14:00 15:20 LECT Element 3B: Introduction to Physiological Genomics SEK stuff 10/01/2 005 15:40 17:00 LECT Element 3B: Model organisms 1 PBM stuff 12/01/2 005 09:00 10:20 LECT/ PA Element 3B: Model organisms 2 PBM stuff 12/01/2 005 10:40 12:00 LECT Element 3B: Microarrays DaM 17/01/2 005 14:00 15:20 LECT Element 3B: Somatic gene transfer 1 SEK 17/01/2 005 15:40 17:00 LECT Element 3B: Somatic gene transfer 2 JFP 19/01/2 005 09:00 10:20 LECT Element 3B:Germline transgenesis DaM guest 19/01/2 005 10:40 12:00 LECT Element 3B: Gene suppression SW guest 24/01/2 005 14:00 15:20 LECT Element 3B: GM Legislation SJ 24/01/2 005 15:40 17:00 LECT Element 3B: Genetic Plasticity DaM 26/01/2 005 09:00 10:20 LECT Element 3B: Gene Therapy AB 26/01/2 005 10:40 12:00 LECT/ PA Element 3B: Genomic tools and rational drug design HJW stuff 31/01/2 005 15:40 17:00 LECT/ PA Element 3B:Gene therapy vs chemicals & drugs? HJW stuff 02/02/2 005 09:00 10:20 Element 3B: From Genome to Therapy Paper Analysis1 SEK stuff 02/02/2 005 10:40 12:00 PA PA Element 3B: From Genome to Therapy Paper Analysis2 SEK DATE TITLE STAFF guest stuff stuff guest guest guest stuff EXAMPLES from lectures S. Kasparov Teaching using Paper Analysis Beginning of the Element: Introduced the paper and explained the process of orphan receptors discovery. Students were given their assignments (to prepare talks to explain various experiments which were included in that study). During the Element: Students were reading the paper and preparing their presentations using (some of the) information they were taught. Last two sessions of the Element: Students made their presentations and answered questions. The teacher had to step in from time to time. Citric acid cycle intermediates as ligands for orphan G-proteincoupled receptors Weihai He1*, Frederick J.-P. Miao1, Daniel C.-H. Lin1, Ralf T. Schwandner1,2, Zhulun Wang1, Jinhai Gao1*, Jin-Long Chen1, Hui Tian1 & Lei Ling1 NATURE, VOL 429, 13 MAY 2004, 188 A handout to assist paper analysis: I. First steps. Proof of the physiological activity of the putative receptors, identification of the ligands and crossspecies analysis. 1. Identification of putative GPCRs by analysis of ESTs and genome-wide screening (based on Wittenberg et al (2001) paper. Initial assumptions based on sequence homology. Questions which were unanswered: a) do these sequences really encode for functional GPCRs? b) where are these GPCRs present in mammalian organisms? c) what are their endogenous ligands d) what are their physiological roles) 2. Development of an assay which could be used to identify the ligand(s): Stables 1997 paper 3. Identification of the ligand for GPR91: a) basic chemistry of that ligand b) Mass spec analysis = at charge one, mol mass is ~ 120 c) NMR for 1H = in highly ionised form only one type of H atoms and 13C = presence of C=O and CH2. What could it be? Succinate! Comparison with synthetic chemical proved the guess. 4. Inter-species analysis of GPR91 in aequorin essay. ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ 5. Generation of a stable cell line with human GPR91 (the same was done for GPR99)– a way to screen for any other ligand or a drug lead compound. 6. Cracking the GPR99: structurally very close to GPR91. Hypothesised that the ligands might be similar. Screened in aequorin assay (but the number of suspects was relatively small) and identified it to be ketoglutarate, another intermediate of the same cycle. NOW NEED to find out how they work in order to get an idea of what they might be doing… II. Analysis of G-protein signalling mechanism and the molecular structure of the receptor. 7. 7a: hGPR91 couples to PTX-sensitive Gio to inhibit forskolin-induced cAMP accumulation and to Gq to trigger IP (MUST BE IP3!) accumulation (Figs 2e,f,g).. 7b: GPR99 couples via Gq only (Figs 2g&supplementary info) 8. Internalisation – Fig 2h 9. Generation of a computer model of the binding site and site-directed mutagenesis – Fig 3 a,b,c,d. WHY THIS MIGHT BE NECESSARY??? EXAMPLES from lectures EXAMPLES of STUDENTS PRESENTATIONS The outcomes in Y2005 Average scores Phys Genom 2005 (n=12) 5 4.5 4 3.5 3 2.5 2 1.5 1 0.5 0 Usefulness of the element Was your background sufficient for this element? Did you like paper analysis as a method of teaching? Did you like the selection of topics and speakers? Successful and unsuccessful teaching? Correlation between the Overall Interest and Understanding and Student’s Background Level (Teacher 2) Correlation between the Overall Interest and Understanding and Student’s Background Level (Teacher 1) 12 16 10 14 12 8 10 6 8 6 4 4 2 2 0 0 0 1 2 3 4 5 6 0 1 2 3 4 Correlation between the Overall Interest and Understanding and Student’s Background Level (Teacher 3) 16 14 Overall Interest= Clarity+ Interest+ “Can remember” 12 10 8 6 4 2 0 0 1 2 3 4 5 6 5 6 What is still missing: Bioinformatics (could be a bit problematic because of the need of good background in mol biology and also maths) Polymorphisms and their potential roles in human diseases Epigenetics…??? A fundamental problem – wider and deeper teaching of biochemistry and general molecular biology during the initial part of training. However, this is slightly at odds with the overall ambition of this Department to be seen as a knowledge base for systems and in vivo physiology. Conclusions 1.Our view, consistent with (A.W.Cowley Jr), is that ”Physiological genomics… brings together disciplines of genomics and cell, organ and whole animal systems integrative physiology in an effort to attach function to the DNA sequences of complex living systems” 2.Combination of traditional lectures and paper analysis seems to work best 3. Students seem to be more interested in application of genomic tools to physiological and medical problems than in “hard-core” molecular genetics 4. Background knowledge is a problem and needs to be looked at. 5.Several important areas have not been covered in sufficient detail, but this also depends on the time allocated in the curriculum. 6.Finally, we have successfully run an “element” of “Physiological Genomics” to a non-specialist class of 3Y Physiology Students