Genome Project 
U.S. HGP on Fast Track 
DOE Joint Genome Institute Exceeds Goal 
New 5-Year Goals 
Faster Sequencing with BACs 
Mapping with STCs and STSs 
Availability of BAC Clones and STC Data 
BAC Related Websites 
BAC Resource Success Story 
Scientists Hunt SNPs for Variation, Disease 
Who's Sequencing the Human Genome? 
Genomics Progress in Science 
EMSL Promotes Remote Access to Instrumentation 
Second Private-Sector Sequencing Project 
GeneMap'98 

In the News 
Team Delivers C. elegans Sequence 
Why Sequence Entire Genomes? Worm's Eye View 
Embnet.news on Web 
European Biotech Program 
DOE BER Research Update 
Hollaender Fellows Named 
SBIR 1998 Human Genome Awards Announced 
Mouse Resources 
Mouse Consortium for Functional Genomics 
Chlamydia Genome Analysis 
HUGO Merges Offices, Web Sites 

Microbial Genomics 
Superbug Deinococcus radiodurans 
Unfinished Microbial Genomes Searchable 
TIGR Releases Chlorobium tepidum Sequence 
DOE MGP Abstracts Online 
Microbial TV Series 
 
Ethical, Legal, and Social Issues and Educational Resources 
Cambridge ELSI Symposium 
Eric Lander, Genetics in the 21st Century 
Mark Rothstein, Genetic Privacy 
James Wilson, Gene Therapy Present & Future 
LeRoy Walters, Ethical Issues in Gene Therapy 
DNA Files on NPR, Internet 
Innovative Biotechnology Curriculum 
Short Course for Biology Teachers 
Microbial TV Series 

Proteomics 
Looking at Proteins to Understand Expression 
2-DGE:  Protein Visualization, Modification 
Tool for Protein Analysis 
TREMBL Release 6 
R&D 100 Award Goes to LANL's SOLVE 
NIH Awards Proteomics Grant to Axys 
E. coli Proteome Database 

Genetics in Medicine 
National Organization for Rare Disorders 
Translation of Genetics to Medicine: New Website 
Cancer Genetics Web Site 
HuGem Website Offers Education in New Genetics 
Calculation of Genetic Risks 2nd Edition 
New Genetics Manual Offered 
Mutation Research Genomics Online 
 
Informatics 
GDB Database Operations Restored 
In Silico Biology: Bioinformatics Journal 
Computational Methods Book Available 
Bioinformatics Guide
BioToolKit
Gene-Finding Programs at Sanger
New Sequin Version
Tandem Repeat Tool
Sequence Viewer
SmithKline Licenses Gene Logic Software 
Influenza Database at LANL 
TRANSFAC Database 
p53 Mutation Database 
TBASE at Jackson Laboratory 
Intein Database on Web 
System Identifies Polymorphisms 

Web, Other Resources, Publications 
1999 Oakland Workshop Website 
Launchpad to Human Chromosomes 
Nature Genetics Supplement 

Funding 
DOE Office of Science Grants and Contracts 
NHGRI National Service Award Fellowships 
NCI Technologies for Molecular Analysis 
NIH: Netork for Large-Scale Mouse Sequencing 
NHGRI: Genomic Technology Development 
US Genome Research Funding 

Meeting Calendars & Acronyms 
Genome and Biotechnology Meetings 
Training Courses and Workshops 
Acronyms 

HGN archives and subscriptions 
HGP Information home

From Sequence to Systems: Looking at Proteins to Understand Genome Expression

The availability of entire genomic sequences for some 18 microbes (and many more to come) now offers investigators the opportunity to perform comparative analysis from an evolutionary perspective, identify conserved genes and metabolic capabilities based on protein sequence homology, and predict protein structures. Understanding how gene products--proteins--work together to create and maintain complex biological systems, however, requires data about the entire spectrum of protein production in the complex ecosystem of a cell.

In the account below, DOE Microbial Genome Program grantee Carol Giometti of Argonne National Laboratory (ANL) describes such studies on two microbial genomes, the heat-loving Methanococcus jannaschii and Pyrococcus furiosus, both subjects of the DOE program. [Introduction by Dan Drell, DOE Microbial and Human Genome programs]

In 1995, V. Wasinger and coworkers (University of Sydney, Australia) coined the term "proteome" to describe all the proteins encoded within a genome. Proteomics is the study of protein expression by biological systems, including relative abundance, post-translational modifications, stability within the cell, and fluctuations as a response to environment and altered cellular needs.

In contrast to genomic sequence, which captures DNA information that is stable throughout the lifetime of an organism, proteomics summarizes protein-expression patterns of a biological system at different times. Biochemical pathways and regulatory mechanisms can be deduced by manipulating the cellular environment or DNA sequence and observing coregulation of specific proteins or sets of proteins. Proteomics tools include high-resolution protein separation, detection, and quantitation methods and techniques for linking proteins to their corresponding gene sequences. These tools can be used to further annotate and validate completed genomes, reveal biochemical pathways and regulatory networks, and define targets for protein-structure determination. In the context of the DOE Microbial Genome Program, analyzing the proteomes of organisms for which complete genomes are available offers the potential for rapid identification of the organisms' major gene products.

Although M. jannaschii's complete genome sequence is publicly available and annotated according to sequence homology with other known proteins, the actual proteins synthesized by M. jannaschii and regulation of their synthesis have not been studied until now. Correlation of protein abundance, shifts in abundance in response to environmental changes, and post-translational modifications with the genome sequence will provide new information regarding gene expression and regulation in this member of the Archaea. In addition, proteome studies will serve to confirm or refute protein identifications based on sequence homologies alone.

The genome sequence of P. furiosus is virtually complete, and numerous P. furiosus enzyme activities have been well characterized. The regulation of specific gene expression (e.g., inducibility of enzyme activities of interest) is not characterized in P. furiosus, however, nor has the influence of post-translational modification been explored. Characterization of the P. furiosus proteome will bridge the gap between gene sequence and protein function by providing data on the regulation of protein synthesis. In addition, studies are in progress to determine the subcellular localization (soluble vs membrane fractions) of each P. furiosus protein.

Strategies rooted in 2-DGE are being developed to link the proteome information with existing genome sequence databases for these two Archaea. Evolving approaches to characterizing small-genome proteomes and linking proteome and genome databases will be the foundation for developing protocols for similar investigations of large mammalian proteomes. [Carol S. Giometti, ANL]

The electronic form of the newsletter may be cited in the following style:
Human Genome Program, U.S. Department of Energy, Human Genome News (v10n1-2).