During the late stages of the Human Genome Project and in the years thereafter,
several important private and public spin-off projects have been launched. These
projects are capitalizing on the new biology and new technologies brought about
by the HGP that have enabled their research to go forward. They include
Genomics:GTL Project
http://genomicsgtl.energy.gov/
GTL research conducts explorations of microbes and plants at the molecular,
cellular, and community levels. The goal is to gain insights about fundamental
biological processes and, ultimately, a predictive understanding of how living
systems operate. The resulting knowledgebase—all linked through DNA sequence
and freely available—will catalyze the translation of science into new
technologies for energy and environmental applications.
Human Microbiome Project
http://nihroadmap.nih.gov/hmp/
Within the body of a healthy adult, microbial cells are estimated to outnumber human cells by a factor of ten to one. These communities, however, remain largely unstudied, leaving almost entirely unknown their influence upon human development, physiology, immunity, and nutrition. To take advantage of recent technological advances and to develop new ones, the NIH Roadmap has initiated the Human Microbiome Project (HMP) with the mission of generating resources enabling comprehensive characterization of the human microbiota and analysis of its role in human health and disease.
Genographic Project
https://www3.nationalgeographic.com/genographic/
The Genographic Project is a five-year research partnership led by National
Geographic and IBM. Researchers are using cutting-edge genetic and computational
technologies to analyze historical patterns in DNA from participants around
the world to better understand our human genetic roots.
International HapMap Project
http://snp.cshl.org/index.html.en
The goal of the International HapMap Project is to develop a haplotype map
of the human genome, the HapMap, which will describe the common patterns of
human DNA sequence variation. The HapMap is expected to be a key resource for
researchers to use to find genes affecting health, disease, and responses to
drugs and environmental factors. The information produced by the Project will
be made freely available.
Microbial Genome Project
http://microbialgenomics.energy.gov/
The U.S. Department of Energy (DOE) led the Microbial Genome Project from 1994-2005.
The projectssupported innovative, high-impact, peer-reviewed biological science
to seek solutions to difficult DOE mission challenges. These challenges included
finding alternative sources of energy, understanding biological carbon cycling
as it relates to global climate change, and cleaning up environmental wastes.
Microbial genome sequencingcontinues at DOE through the DOE Joint Genome Institute
Community Sequencing Program.
Environmental Genome Project
http://www.niehs.nih.gov/research/supported/programs/egp/
Many diseases are the outcome of a complex inter-relationship between multiple
genetic and environmental factors. Research suggests that individual susceptibility
is influenced more by certain genes than by exposure to environmental agents.
To better understand how individuals differ in their susceptibility to environmental
agents and how these susceptibilities change over time, the National Institute
of Environmental Health Sciences (NIEHS) developed the Environmental Genome
Project (EGP) in 1997. The long-term goal of the EGP is to characterize how
specific human genetic variations, or polymorphisms, contribute to environmentally
induced disease susceptibility.
Cancer Genome Anatomy Project
http://cgap.nci.nih.gov/
The goal of the NCI's Cancer Genome Anatomy Project is to determine the gene
expression profiles of normal, precancer, and cancer cells, leading eventually
to improved detection, diagnosis, and treatment for the patient. By collaborating
with scientists worldwide, CGAP seeks to increase its scientific expertise and
expand its databases for the benefit of all cancer researchers.
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