ANALYSIS
OF RHESUS MONKEY GENOME UNCOVERS GENETIC DIFFERENCES WITH HUMANS, CHIMPS
DNA Comparison Provides New Clues to Primate Biology
An international
consortium of researchers has published the genome sequence of the rhesus
macaque monkey and aligned it with the chimpanzee and human genomes.
Published April 13 in a special section of the journal "Science",
the analysis reveals that the three primate species share about 93 percent
of their DNA, yet have some significant differences among their genes.
In its
paper, the Rhesus Macaque Genome Sequence and Analysis Consortium, supported
in part by the National Human Genome Research Institute (NHGRI), one
of the National Institutes of Health (NIH), compared the genome sequences
of rhesus macaque ("Macaca mulatta") with that of human ("Homo
sapiens") and chimp ("Pan troglodytes"), the primate
most closely related to humans. Four companion papers that relied on
the rhesus sequence also appear in the same issue.
The rhesus
genome is the second non-human primate, after the chimp, to have its
genome sequenced and is the first of Old World monkeys to have its DNA
deciphered.
"The
sequencing of the rhesus macaque genome, combined with the availability
of the chimp and human genomes, provides researchers with another powerful
tool to advance our understanding of human biology in health and disease,"
said NHGRI Director Francis S. Collins, M.D., Ph.D. "As we build
upon the foundation laid by the Human Genome Project, it has become
clear that comparing our genome with the genomes of other organisms
is crucial to identifying what makes the human genome unique."
The rhesus,
because of its response to the simian immunodeficiency virus (SIV),
is widely recognized as the best animal model for human immunodeficiency
virus (HIV) infection. The rhesus genome sequence will also serve to
enhance essential research in neuroscience, behavioral biology, reproductive
physiology, endocrinology and cardiovascular studies. In addition, the
rhesus serves as a valuable model for studying other human infectious
diseases and for vaccine research.
The sequencing
of the rhesus genome was conducted at the Baylor College of Medicine
Human Genome Sequencing Center in Houston, the Genome Sequencing Center
at Washington University School of Medicine in St. Louis and the J.
Craig Venter Institute in Rockville, Md., which are part of the NHGRI-supported
Large-Scale Sequencing Research Network. The DNA used in the sequencing
was obtained from liver cells from a female rhesus macaque that had
died of other health problems at the Southwest Foundation for Biomedical
Research in San Antonio, which is supported by the National Center for
Research Resources, part of NIH.
Independent
assemblies of the rhesus genome data were carried out at each of the
three sequencing centers using different and complementary approaches
and then combined into a single "melded assembly." In their
analysis, scientists from 35 institutions compared this melded assembly
to the reference sequence of the human genome, a newer unpublished draft
sequence of the chimp genome, the sequence of more than a dozen other
more distant species already in the public databases, the human HapMap,
and the Human Gene Mutation Database that lists known human mutations
that lead to genetic disease.
"This
study of the rhesus genome is invaluable because it gives researchers
a perspective to observe what has been added or deleted in each primate
genome during evolution of rhesus, chimp, and the human from their common
ancestors ," said Richard Gibbs, Ph.D., director of Baylor College
of Medicine's Human Genome Sequencing Center in Houston and the project
leader.
One of
the most useful features of the rhesus genome is that it is less closely
related to the human genome than to the chimp genome. This means that
important features that have been conserved in primates over time can
be more easily seen by comparing rhesus to human, than chimp to human.
By adding
the rhesus genome to the primate comparison, researchers identified
nearly 200 genes likely to be key players in determining differences
among primate species. These include genes involved in hair formation,
immune response, membrane proteins and sperm-egg fusion. Many of these
genes are located in areas of the primate genome that have been subject
to duplication, indicating that having an extra copy of a gene may enable
it to evolve more rapidly and that small duplications are a key feature
of primate evolution.
The analysis
also revealed a few instances in which whole families of genes were
radically different in the rhesus, containing more copies of certain
genes than in the chimp or human. These gene families include important
immune related genes, as well as genes with functions not yet fully
known.
In addition
to comparing the rhesus with the chimp and human genomes, the group
also studied genetic variation in macaque populations, and developed
a set of 'single nucleotide polymorphisms' or SNPs (single base DNA
differences) that can be used for future analysis of inheritance of
biomedically important traits in rhesus. This advance in macaque genetics
will enhance the use of macaques for the study of genetic diseases of
man.
The rhesus
study is part of an ongoing program to analyze primate genomes. Other
primate genomes underway include the marmoset, gibbon and gorilla. Researchers
at the Baylor Center and the Washington University Genome Center completed
the raw sequence for the orangutan and marmoset genomes early this year,
and Washington University has deposited the assemblies on <http://genome.wustl.edu>.
Researchers plan to analyze the orangutan and marmoset genomes and compare
them with the other primates over the summer.
The chimp,
orangutan and human genome sequences, along with those of a wide range
of other organisms such as mouse, rat, dog, cow, honey bee, roundworm
and yeast, can be accessed through the following public genome browsers:
GenBank <http://www.ncbi.nih.gov/Genbank> at NIH's National Center
for Biotechnology Information (NCBI); the UCSC Genome Browser <http://www.genome.ucsc.edu>
at the University of California at Santa Cruz; the Ensembl Genome Browser
<http://www.ensembl.org> at the Wellcome Trust Sanger Institute
and the EMBL-European Bioinformatics Institute; the DNA Data Bank of
Japan <http://www.ddbj.nig.ac.jp>; and EMBL-Bank. <http://www.ebi.ac.uk/embl/index.html>
at the European Molecular Biology Laboratory's Nucleotide Sequence Database.
NHGRI is
one of the 27 institutes and centers at the National Institutes of Health,
which is an agency of the Department of Health and Human Services. The
NHGRI Division of Intramural Research develops and implements technology
to understand, diagnose and treat genomic and genetic diseases. Additional
information about NHGRI can be found at <http://www.genome.gov>.
The National
Institutes of Health (NIH) -- The Nation's Medical Research Agency --
includes 27 Institutes and Centers and is a component of the U. S. Department
of Health and Human Services. It is the primary federal agency for conducting
and supporting basic, clinical, and translational medical research,
and it investigates the causes, treatments, and cures for both common
and rare diseases. For more information about NIH and its programs,
visit <http://www.nih.gov>.