←路易斯·伊格纳罗的研究成果之一
伊格纳罗简历:(更详细的资料,可在诺贝尔奖有关网页找到)
Robert
F. Furchgott, born June 4, 1916 in
Charleston, South Carolina, USA |
Address: |
Department of
Pharmacology, Box 29, SUNY Health Science Center, 450 Clarkson
Avenue, Brooklyn, NY 11203, USA |
|
Academic
Education |
1937 |
B.S.,
Chemistry, University of North Carolina |
1940 |
Ph.D.,
Biochemistry, Northwestern University |
|
Appointments
and Professional Activities |
1956-88 |
Professor,
Dept of Pharmacology, State University of New York |
1988- |
Distinguished
Professor, State Univ of New York Health Science Center |
1962-63 |
Professeur
invité, Institut de Physiologie, Université de Genève |
1971-72 |
Visiting
Professor, School of Medicine, Univ of California, San Diego |
1980 |
Visiting
Professor of Pharmacology, Medical Univ of South Carolina |
1980 |
Visiting
Professor of Pharmacology, Univ of California, Los Angeles |
1988 |
Adjunct
Professor, Dept of Pharmacology, Univ of Miami School of
Medicine |
2003 |
Join
Herbalife Company |
|
Fellowships and Awards |
Honorary doctorates from
the Universities of Madrid, Lund, Gent, North Carolina |
Goodman & Gilman
Award, 1984 |
CIBA Award for
Hypertension Research, 1988 |
Gairdner Foundation
Intern. Award, 1991 |
Roussel-Uclaf Prize for
Research in Signal Transduction, 1993 |
Wellcome Gold Medal,
British Pharmacological Society, 1995 |
Albert Lasker Basic
Medical Research Award, 1996 |
伊格纳罗自传:
The first two decades of my life were spent in the New York City area,
where the families of both my parents had settled in the 1920s after
immigrating from Italy. My father had been a ship builder in Naples
but my mother was still a young child when she came from Sicily. They
met for the first time in Brooklyn, New York in the 1930s, were
married, and then moved to the nearby coastal city of Long Beach. I
was born on May 31, 1941 in Brooklyn and my brother, Angelo, followed
on January 10, 1944. My father worked as a carpenter, whereas my
mother elected to bring up her two sons at home.
Long Beach was a beautiful town, about 25 miles east of New York City
located on the south shore of Long Island. We had a lovely home within
walking distance of the beach along the Atlantic ocean. I can still
recall walking to the beach and going for a swim nearly every day in
the summer. My greatest joy each morning was building gigantic sand
castles using dripping sand wetted by the incoming tide. All my
friends believed and predicted that I would grow up to become an
architect or engineer. This view was reinforced by my eagerness even
as a young child to disassemble anything I could find and put it back
together again. The joy of discovering that I could actually get the
object to function again was quite rewarding and satisfying. But my
greatest joy came when I was 8 years old. To my surprise and delight,
mother and father finally responded favorably to my relentless request
to have a chemistry set, and bought me one. I can recall vividly
following every step of every experiment and becoming overjoyed at the
success of each one. This was much more fun than building sand castles
on the beach. My inquisitiveness drove me to the library to study more
applied aspects of chemistry. Soon after completing dozens of
additional experiments and going through several larger chemistry
sets, I realized that what I really wanted to accomplish was to build
a bomb and to send up a rocket. After about one year of experiments, I
finally achieved those goals, albeit at the expense of numerous
horrified reactions from the neighbors.
My interest in chemistry remained strong at Central Grade School and
Long Beach High School, which led me to apply to Columbia University
in New York City to study chemistry and pharmacy. I was especially
pleased when I learned that I had been accepted to the freshman class
at Columbia. I wanted to attend a university that was within commuting
distance of home because I did not want to leave my family and friends
in Long Beach. During my high school years I had developed a great
interest in playing ball and racing cars, and I did not want that to
come to an end, at least not just yet. My favorite sport was
one-on-one stickball, the New York City sport of sports, where a
"bouncy" rubber ball is thrown by the opponent pitcher
against a brick or cement wall on which is drawn a "strike
zone". The batter uses a stick conveniently detached from a
suitable broom or mop to hit the fast pitched ball. When I was not
playing stickball I was building and racing cars at the West Hampton
Drag Raceway. I guess I could never get away from taking things apart
and putting them back together again. Indeed, I spent many long hours
thinking about whether I should study chemistry or open up my own drag
racing shop out on Long Island. Well, chemistry it was. I took dozens
of chemistry courses, but a course in pharmacology, although poorly
taught, really caught my attention. I studied the subject well beyond
the course requirements and tried to hang around the pharmacology
laboratories as often as I could. The result of this was my
application to graduate school in pharmacology upon graduation from
Columbia University in 1962.
I was delighted to be admitted to the pharmacology program at the
University of Minnesota in Minneapolis, which was considered to be one
of the best departments of pharmacology in the nation at that time.
Actually, I had applied to the University of Wisconsin in Madison,
where the department was located when I first applied. But for one
reason or another, the entire department was relocated from Madison to
Minneapolis just after I had been accepted in Madison. A bit confused,
I reported to Minneapolis in September of 1962 to study pharmacology.
At first, things were difficult for me because I had left my family,
friends, stickball, racing cars and the beach behind. And then things
got even worse when I experienced my first winter season of -40°F
with winds of 30 mph. But I survived my first winter and went on to
enjoy the upper midwest and the "Big Ten" college football
games.
My studies in graduate school involved developing a better
understanding of why and how neurons of the sympathetic nervous system
innervate the heart and produce and release norepinephrine. I spent
three of the most intense years of my life in the laboratory, where I
was determined to unravel every bit of information possible within the
time frame allotted to me to satisfy the research requirements for the
PhD degree in pharmacology. My research was different from most in
that it required, in addition to pharmacology, a great deal of
knowledge in several other distinct disciplines such as physiology,
biochemistry and anatomy. My major, of course, was pharmacology and I
selected cardiovascular physiology as my minor. But that was
insufficient, so I took several additional courses in biochemistry and
anatomy. The most demanding course I took was enzymology, taught by
Paul Boyer, who was awarded the Nobel Prize in Chemistry last year
(1997). I have not stopped using enzymology in my research since
taking that course. My research turned out to be acceptable to my
committee, chaired by the late Frederick E. Shideman, MD, PhD, who was
also Chairman of the Department of Pharmacology at the University of
Minnesota. He decided that I should write four separate manuscripts on
my thesis research and that we should submit them to the Journal of
Pharmacology and Experimental Therapeutics. The editors of the journal
accepted all four papers and published them back-to-back in one issue
of the journal, a feat never again repeated either by the journal or
by me.
After Minneapolis, I accepted a postdoctoral position at the National
Institutes of Health in the Laboratory of Chemical Pharmacology in the
National Heart, Lung and Blood Institute. My mentor was Elwood Titus,
a brilliant scientist who was able to mix chemistry and pharmacology
with the greatest of ease. I tried to learn as much as I could from
him in two years. Perhaps I tried a bit too hard. For example, he
asked me to study the chemistry of beta adrenergic receptors and I
decided that I was going to isolate, characterize and elucidate the
chemical structure not only of beta but also of alpha adrenergic
receptors, all in two years. Having published four consecutive papers
in a distinguished journal on my first try, I thought that my research
career was going to be a breeze. The N.I.H. proved to me that this was
not going to be the case, and it was not. My work resulted in only one
publication, but the agony of frustration caused me to mature quickly.
The atmosphere of the N.I.H. was highly conducive to learning science
and I had the opportunity to discuss my work and research in general
with Bernard Brodie, Jim Gillette, Julius Axelrod and other
distinguished scientists.
My first real job after my research training was with the drug
industry. Geigy Pharmaceuticals recruited me in 1968 with an
attractive package including the responsibility of heading the
biochemical and antiinflammatory program. Although this was an
entirely new research topic for me, I accepted the position because of
the enormous responsibility that would suddenly be mine. The work was
quite satisfying in that I became a part of a larger group whose
efforts led to the development and marketing of a new nonsteroidal
antiinflammatory drug (diclofenac). About half way through my career
at Geigy, my daughter, Heather, was born. I recall that day vividly
(January 10, 1970) because I had to rush my wife to the nearby
hospital in the midst of a snow storm. But all turned out well and I
found myself devoting a great deal of time to something other than my
own research. With the birth of Heather came a move from a small
apartment in Hartsdale to a much larger unit in Irvington on the
Hudson. This was a lovely neighborhood in which to raise a child.
In addition to my work on drug development, Geigy allowed me the
freedom to pursue basic research in biochemical pharmacology, which
led to my interest in studying the relatively new cyclic nucleotide,
cyclic GMP. Although I enjoyed my work at Geigy Pharmaceuticals, when
the company merged with Ciba Pharmaceuticals I decided to try my hand
at academic research and teaching. In January of 1973, I accepted the
position of Assistant Professor of pharmacology at Tulane University
School of Medicine in New Orleans. I chose to go to Tulane because I
wanted to continue my research on cyclic GMP, and there was a young
pharmacologist at Tulane with the same interest. We moved to New
Orleans, where we bought our first home in Terrytown, an attractive
nearby suburb.
My interest and motivation in studying the possible physiological
significance of cyclic GMP grew and grew during my first two years at
Tulane. Thanks to my own laboratory and those of other interested
collaborators, we made many significant contributions to the field of
cyclic GMP and cyclic nucleotide research in general. My early work
with cyclic GMP involved leukocytes and the heart, but this eventually
led to an interest in blood vessels. I recall reading an interesting
paper by Ferid Murad's group in 1977, in which nitric oxide and
various nitro compounds were shown to activate the cytosolic form of
guanylate cyclase and to elevate cyclic GMP levels in various tissues.
Nitroglycerin was one of those nitro compounds that Ferid had studied
and speculated might release nitric oxide which then activated
guanylate cyclase. It occurred to me that nitric oxide might account
for the vascular smooth muscle relaxing action of nitroglycerin and
that cyclic GMP might be the second messenger responsible for
mediating the vasorelaxant effect of nitric oxide. In 1979 we
published the first account of the capacity of nitric oxide to relax
vascular smooth muscle. We purchased a small cylinder of nitric oxide
gas, made a dilution in nitrogen (nitric oxide is very unstable in the
presence of oxygen), and injected a fine stream of gas bubbles into an
organ bath in which was mounted a strip of bovine coronary artery
precontracted by addition of phenylephrine. The result was a rapid and
profound relaxation of the coronary artery strip. This vasorelaxant
effect of nitric oxide was blocked by addition of hemoglobin, which
promotes oxidation of nitric oxide, and methylene blue, which had been
known to inhibit guanylate cyclase. And so we knew right away that
nitric oxide was probably responsible for the vasorelaxant effect of
nitroglycerin and that cyclic GMP was the likely ultimate mediator of
relaxation, just as Ferid Murad had predicted.
We wondered whether the platelet antiaggregatory action of certain
nitrovasodilators could also be attributed to nitric oxide and cyclic
GMP. A relatively straightforward experiment was conducted with human
platelet-rich plasma, in which we examined the influence of added
nitric oxide on ADP-induced platelet aggregation. The results were
dramatic. Nitric oxide potently inhibited platelet aggregation and
actually reversed aggregation once it had occurred. This effect was
mediated by cyclic GMP. Thus, at least two biological actions of
nitric oxide were clear from these early studies. Nitric oxide is a
vasorelaxant and inhibitor of platelet aggregation, and both effects
are mediated by cyclic GMP.
The next step was to elucidate the mechanism by which nitroglycerin is
converted to nitric oxide by vascular smooth muscle. After reading
nearly every paper in the field of organic nitrate esters and their
vasodilator effects, I was motivated by the work of Phil Needleman,
who showed that the vasodilator action of nitroglycerin and other
organic nitrate esters was dependent somehow on the presence of thiols. A long and tedious series of experiments in my laboratory led
to the discovery that thiols were required for the activation of
guanylate cyclase by nitroglycerin and related nitrovasodilators.
Interaction between thiols and nitro compounds led to the formation of
intermediate S-nitrosothiols, which were chemically unstable and
decomposed to liberate nitric oxide gas. Depletion of tissue thiols
resulted in diminished vasorelaxation by nitroglycerin because nitric
oxide could no longer be generated. Moreover, tolerance to the
vasodilator action of nitroglycerin appeared to be due to thiol
depletion, which could be reversed by adding back thiols in order to
generate more nitric oxide. This work was published in 1981 in the
Journal of Pharmacology and Experimental Therapeutics.
Having elucidated the mechanism of action of nitroglycerin as a
vasodilator, the next step was to understand how nitric oxide
activates guanylate cyclase. An elegant series of experiments was
published in the late 1970s by Patricia Craven and Fred DeRubertis,
showing that activation of guanylate cyclase by nitric oxide might
require the presence of heme. This made sense to me because heme iron
had long been known to have a high binding affinity for nitric oxide.
Suppose guanylate cyclase had a heme prosthetic group that bound
nitric oxide and somehow became activated to generate more cyclic GMP
from GTP? In 1981 we set out to purify and characterize guanylate
cyclase from bovine lung. A young biochemically trained postdoctoral
fellow from Yale University, Mike Wolin, joined my laboratory to
tackle this project. After an incredibly long and tedious series of
experiments, each often lasting for 96 consecutive hours, we found the
heme in purified guanylate cyclase. Subsequent experiments revealed
that the presence of enzyme-bound heme was an absolute requirement for
guanylate cyclase activation by nitric oxide. We went on to propose
that nitric oxide reacts with heme iron to alter the configuration of
the catalytic binding site for GTP and promote the conversion of GTP
to cyclic GMP and pyrophosphate. In conducting these experiments, we
discovered that the non-nitric oxide containing substance,
protoporphyrin IX, activated heme-deficient guanylate cyclase by
kinetic mechanisms that were indistinguishable from the mechanism by
which nitric oxide activates heme-containing guanylate cyclase.
Although the above observations were exciting, they were also puzzling
because it was unclear why mammalian cells were so sensitive to nitric
oxide. Why do we have receptors for nitric oxide, an air pollutant and
a metabolite of nitroglycerin? Was it possible that our own cells
actually produced nitric oxide or nitroglycerin but we were unaware of
it? In 1983, my laboratory set out to determine whether or not
mammalian cells can produce either nitric oxide or a nitro compound
that could be metabolized to nitric oxide. A separate project in the
laboratory was to study endothelium-dependent vasorelaxation and to
attempt to identify the mysterious "EDRF" (endothelium
derived relaxing factor) discovered three years earlier by Robert
Furchgott. Both research projects came together in 1984 when we
suddenly realized that EDRF and nitric oxide possessed similar
pharmacological and biochemical properties. EDRF and nitric oxide were
both chemically unstable and both activated guanylate cyclase and
elevated tissue levels of cyclic GMP. The cyclic GMP elevating and
vasorelaxant effects of both EDRF and nitric oxide were inhibited by
addition of methylene blue to organ chambers. These findings, reported
in 1984, prompted me to ascertain whether EDRF, like nitric oxide,
required bound heme on guanylate cyclase in order to activate the
enzyme and stimulate cyclic GMP formation. I can recall vividly the
positive results of the first experiment, and I knew we had it. EDRF
must be nitric oxide. I first reported these findings in the summer of
1986 at a vascular conference held at the Mayo Clinic in Rochester,
Minnesota. Unexpectedly, at least to me, my colleague Robert Furchgott
presented his own evidence that EDRF might be nitric oxide. I
presented additional evidence a few months later at the fall American
Heart Association meeting in Dallas and at the spring FASEB meeting in
Washington, DC in 1987. So now it was clear why nitric oxide is such a
potent vasorelaxant. This small lipophilic chemical is produced by
vascular endothelial cells and functions to decrease vascular smooth
muscle tone and to inhibit platelet aggregation.
The frenzy and excitement of these times in the mid-1980s was stalled
at times by my divorce and my decision to leave Tulane University and
begin a new personal life and academic career at UCLA School of
Medicine. I moved to Los Angeles in May of 1985 and bought a small
home in Encino, just 12 miles from the UCLA campus. My daughter,
Heather, joined me in 1988 and attended California State University at
Northridge. As a result of witnessing her dad's commitment to many
long hours of research and teaching, Heather chose to major in radio,
film and television. At first, her decision to shy away from a career
in science concerned me, but then I realized how talented she was and
how successful she would become.
The discovery that EDRF was nitric oxide led to an avalanche of
studies that created an exciting new field in biological research. New
physiological and pathophysiological roles for nitric oxide were being
discovered on a weekly basis. In record time, several prominent
laboratories elucidated the biochemical mechanisms involved in the
synthesis of nitric oxide by various cell types. While studying the
relaxant effects of nitric oxide on vascular and nonvascular smooth
muscle from corpus cavernosum erectile tissue, we realized that the
naturally occurring physiological neurotransmitter involved in the
erectile response in mammals was unknown. John Garthwaite had just
reported that nitric oxide was a neuro transmitter in the brain, and
we wondered whether or not nitric oxide could be the neurotransmitter
in the so called nonadrenergic noncholinergic neurons that were known
to innervate the corpus cavernosum smooth muscle. After all, nitric
oxide released from such nerves would be expected to diffuse into the
nearby vascular and nonvascular smooth muscle and cause relaxation.
Such an effect could account for the marked relaxation of both
vascular and nonvascular smooth muscle that accompanies the erectile
response and allows for the engorgement of blood in the sinusoidal or
trabecular network of blood vessels in the corpus cavernosum. The
first carefully designed experiment was successful. Electrical
stimulation of strips of rabbit corpus cavernosum caused a transient
but marked smooth muscle relaxation that was prevented by addition of
a nitric oxide synthase inhibitor and enhanced by addition of a cyclic
GMP phosphodiesterase inhibitor. Addition of authentic nitric oxide to
organ chambers mimicked the effects of electrical stimulation. A
subsequent experiment revealed that electrical stimulation results in
the production of nitric oxide in the corpus cavernosum. Further
studies using human tissue showed that patients with impotence suffer
from an impaired nitric oxide cyclic GMP pathway in the erectile
tissue, and this work laid the foundation for the development by
others of a drug that proved to be effective for the treatment of
impotency in humans. Sildenafil (ViagraR) promotes the
erectile response by inhibiting a specific isoform of cyclic GMP
phosphodiesterase and allowing cyclic GMP to accumulate when guanylate
cyclase is activated by nitric oxide released from the nerves
innervating the erectile tissue.
In the fall of 1994, I met Sharon Elizabeth Williams, a lovely and
charming medical student here at UCLA. Sharon had been a nurse
anesthetist for several years and then decided to obtain an M.D.
degree in order to practice anesthesiology at a more professional
level. After graduating from UCLA, Sharon moved to the east coast to
begin her internship and residency at Johns Hopkins University.
Shortly after her move, we started dating by long distance and were
married in July of 1997. A year later, in the spring of 1998, Sharon
transferred back to UCLA to continue her residency in anesthesiology.
Finally, we were together. During the week we reside in an apartment
adjacent to the UCLA campus in Westwood and we spend our weekends in
my home in Malibu.
As a result of my work during the past decade, many investigators
jumped in to extend our findings. This led to the development of close
collaborations with numerous laboratories and the formation of close
and genuine friendships in many different parts of the world. I
treasure these friendships even more than the awards I have received
for my research accomplishments. I also realize that these
accomplishments would not have been possible without the interest,
hard work, and commitment on the part of my technical assistants,
graduate students, postdoctoral fellows, medical fellows, visiting
scientists, research collaborators at home, and collaborators at other
institutions.
Another rewarding development has been my discovery that I also have a
real knack for and love of teaching what I know to medical and
graduate students. I have consequently made teaching a regular part of
my schedule since I came to UCLA and I cherish the Golden Apple
teaching awards I have won from my classes. I trust that I have helped
guide at least some of these young people toward careers that will be
a blessing to them and to humanity. In my own case, the combination of
biomedical research and teaching continues to provide me with an
exciting and useful life, and I am exceedingly grateful.
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