IUPS/APS Newsroom March 29-April 6
San Diego Convention Center
Hall E Registration Area/Flex Unit
Telephone: 619.525.6228
Contact: Donna Krupa
(703) 967-2751 (cell)
(301) 634-7209 (office, outside IUPS dates)
Fifteen Generations Of
Untrained Athletes And ‘Couch Potatoes’ Reveal Change From Muscle Function
To Major Physiological Adaptations
Don’t
like to exercise? Blame gramps. Maybe. New therapies on the way.
San Diego (April 3, 2005) – So, you don’t like to
exercise? Maybe you could blame it on your great-great-grandparents.
Similarly, if you’re a practiced and proud couch potato who suddenly woke up
to the fact that you’re a “natural” athlete, the credit could also belong to
your genes.
Exercise research traditionally has focused on the
effects of training, rather than underlying genetic mechanisms. But
physiologists wondered what would happen if they took a single strain of
rats – meaning they all had the same basic genetic background – and bred two
separate lines purely on the basis of “continued selecting of untrained rats
with either high- and low-running endurance.” In other words, the genetic
role in endurance performance and oxygen delivery systems.
Results of this large longitudinal study have been
coming out generation by generation, and now a group of researchers at the
University of California, San Diego have found some surprising results at
generation #15 (G15), compared with G7. The G7 untrained rats from the
“athletic” line had a greater running endurance and increased oxygen
consumption (12%) than the “couch potatoes.” These differences were mainly
due to peripheral improvements (skeletal muscle) rather than central
physiological changes in the cardiovascular or respiratory systems.
Wider endurance, oxygen usage differences reflect
system-wide changes
As would be expected, the UCSD physiologists found that
the continued selection led to significantly greater differences in
endurance and oxygen consumption (44%) between the two groups of G15 rats
than were seen at G7.
“This enhanced divergence at G15 was due in part to an
increased skeletal muscle oxygen conductance that allowed for better
transport of the oxygen to the muscle mitochondria of the athletic rats.”
according to Richard A. Howlett, lead author of one of three papers on
the experiment. Howlett and the other two lead authors, Scott D. Kirkton and
Patrick G. Giuliano are all from UCSD’s Department of Medicine, Division of
Physiology.
They are presenting their research at the 35th Congress
of the International Union of Physiological Sciences in San Diego, March 31
- April 5, 2005. (See below * for specifics.)
Howlett continued: “However, we found that in addition
the G15 ‘athletic’ rats had increased performance due to central changes in
oxygen delivery.” Specifically, the running rats had improved cardiovascular
systems (proportionally larger hearts (16% ) and increased blood flow (33%),
reported in Kirkton et al., below) and respiratory systems
(proportionally larger lungs (17%) and better oxygen diffusing capacity,
reported in Giuliano et al., below) over the G7 stage, the
researchers pointed out.
Oxygen delivery system maximized over time; support
for ‘controversial thesis’
Overall, Kirkton said the G15 results are exciting
because “they clearly demonstrate that steps in the oxygen delivery system
are coordinated to maximize efficiency, independent of exercise or other
environmental influences.” And by the G15 stage, the central delivery
components (lung and cardiovascular system) have improved to better meet the
demands of the muscles. Additionally, our results provide support for the
controversial hypothesis that suggests that physiological systems, such as
the oxygen delivery pathway, are, over time, optimized in animals,” Kirkton
noted.
Next steps and implications for human attitudes and
therapies
Having demonstrated the genetic role in endurance
performance and the oxygen delivery systems, the group of researchers are
turning their attention to identify the various genes involved that provide
the underlying signal for “why” some subjects become more athletic, while
others are couch potatoes.
This effort will include looking for genes and/or
signaling mechanisms that prompt the initial signal for the differential
abilities to run on a treadmill without training, as well as the mechanisms
responsible for the “natural” improvements in muscular, cardiovascular and
pulmonary oxygen delivery.
Further in the future the physiologists hope that
identifying these genes and underlying processes could provide insight into
human attitudes toward exercise and lead to therapies to improve oxygen
delivery in patients with muscular, cardiovascular and respiratory diseases.
*Paper presentations: These research results
reflect three concurrent presentations at IUPS. Each is listed below with
the lead author. Other authors involved in all three papers are listed
below. The authors will be in attendance 12:30 p.m.-3 p.m. Tuesday April 5,
Physiology session 936, Physiological genomics of the respiratory system.
Their boards, A487-A489, will be on view 7:30 a.m. - 4 p.m.
“VO2max and muscle O2 transport in rats continue to
diverge with further selective breeding for endurance running.” Richard
A. Howlett, University of California at San Diego. 936.2/A488.
“Cardiovascular differences between rats
selectively bred for endurance running capacity.” Scott David Kirkton,
UCSD, 936.3/A489.
“15 generations of selective breeding for endurance
running capacity in rats is associated with enhanced lung structure and
function not seen at generation 7.” Patrick G. Giuliano (this paper only),
UCSD. 936.1/A487.
Others involved in all three papers: Peter D.
Wagner, Harrieth E. Wagner, UCSD Department of Medicine, Division of
Physiology (as are Howlett, Kirkton and Giuliano); Norberto C. Gonzalez,
University of Kansas Medical Center, Dept. of Molecular and Integrative
Physiology; Steven L. Britton and Lauren G. Koch, University of Michigan
Dept. of Physical Medicine and & Rehabilitation.
Funding. Research was supported by the National
Institutes of Health.
***
The 35th Congress of the International Union of
Physiological Sciences is in San Diego, March 31 - April 5, 2005. The
Congress (http://www.iups2005.org/)
is organized by the six member societies of the U.S. National Committee of
the IUPS,
the American Physiological Society,
the Society for Neuroscience,
the Microcirculatory Society,
the Society of General Physiologists,
the Biomedical Engineering Society, and
the Society for Integrative and Comparative Biology, under the auspices
of the U.S. National Academy of Sciences.
The IUPS conference, held every four years, runs
concurrently this year with Experimental Biology 2005 at the San Diego
Convention Center.
The American Physiological Society (APS), which is
hosting IUPS, was founded in 1887 to foster basic and applied science, much
of it relating to human health. The Bethesda, MD-based Society has more than
10,000 members and publishes nearly 4,000 articles every year in its 14
peer-reviewed journals. In May, APS received the Presidential Award
for Excellence in Science, Mathematics and Engineering Mentoring (PAESMEM).
***
Editor’s Note: For further information or to
schedule an interview with a member of the research team, please contact
Donna Krupa at the IUPS/APS newsroom @ 619.525.6228 (March 31-April
6), or (703) 967-2751 (cell) or (301) 634-7209 (office), or Stacy Brooks at
240.432.9697 (cell) or 301.634.7253 (office).
A searchable online program for IUPS and EB is at
http://www.faseb.org/meetings/eb2005/call/default.htm
