2009 NOBEL TIP ÖDÜLLERİ
2009 NOBEL TIP ÖDÜLLERİ 5.Ekim.2009 Pazartesi günü açıklandı
Prof. Dr. Emin Kansu - Hacettepe Üniversitesi Tıp Fakültesi Öğretim Üyesi
NOBEL TIP ÖDÜLLERİ bu yıl 3 Amerikalı bilim insanı arasında paylaşıldı.
Jack W.Szostak (Harvard Medical School) , Elizabeth H.Blackburn
(University of California-San Francisco) ve Carol W.Greider (Johns Hopkins
University) "Kromozomların Telomerler ve Telomeraz Enzimi İle Nasıl
Korundukları" konusundaki çalışmalarından dolayı ödüle layık görüldüler.
Telomerler kromozomlarımızın uç kısımlarında bulunan bölgelerdir. Jack Szostak ile Elizabeth Blackburn kromozomların uç bölgelerindeki Telomerleri degradasyondan (yıkılmasını) önleyen özgül DNA dizileri tanımlamışlardır.
Carol Greider doktorasını Elizabeth Blackburn ile yapmış ve 1985 yılında Cell mecmuasında yayınladıkları makalede ilk kez "Telomer DNA" sını yapan "Telomeraz" enzimini tanımlamışlardır.
Telomerlerin varlığı , yapıları ve genleri konusundaki gelişmeler 1946 Nobel Ödülünü alan Hermann Müller ve 1983 yılında Nobel Ödülünü alan Barbara McClintock'un araştırmaları ile başlamıştır.
Kromozomlarımızın uç bölgelerinde yer alan "Telomerler" fonksiyonel olarak kromozomları zedelenmelere karşı korumakta ve hücre yaşlanmasını geciktirmektedirler. "Telomeraz Enzim" aktivitesi ne kadar yüksek olursa "Telomer"lerin uzunlukları korunmakta ve hücre yaşlanması gecikmektedir.Buna karşın "Telomeraz Enzim" aktivitesi bir nedenle azalırsa "Telomer" yapımı giderek bozulmakta (azalmakta), Telomerler kısalmakta ve hücre / vücud yaşlanması (aging) başlamaktadır.
Kanser hücreleri başta olmak üzere bazı hastalıklarda "Telomeraz Enzim" aktivitesi artmakta, böylece kromozomlarda Telomer uzunlukları korunmakta ve Kanser Hücreleri "ölümsüz" olarak yaşlanmadan sonsuz yaşayabilmektedirler.
Jack W.Szostak, Elizabeth H.Blackburn ve Carol W.Greider canlılarda hücre bölünmesi sırasında kromozomların nasıl kopyalandıklarını ve kromozomların degradasyondan ( yıkılma,parçalanma) nasıl korunduklarını göstermeleri " nedeniyle 2009 Nobel Ödülü'ne layık görülmüşlerdir. Buluşları hücre biyolojisinin anlaşılmasına, kanser ve diğer hastalıkların gelişimine ve tedavilerinin planlanmasına ışık tutacak çok büyük öneme sahiptir.
5.Ekim.2009 Pazartesi günü Karolinska Enstitüsü'nde Nobel Tıp ve Fizyoloji Ödül Komitesi Sekreteri Prof. Göran K.Hansson tarafından açıklanan ödüllerin "Basın Bildirisi" aşağıda yer almaktadır.
The Nobel Prize in Physiology or Medicine 2009
5 October 2009
The Nobel Assembly at Karolinska Institutet has today decided to
award. The Nobel Prize in Physiology or Medicine 2009 jointly to
Elizabeth H. Blackburn, Carol W. Greider and Jack W. Szostak for the discovery of "how chromosomes are protected by telomeres and the enzyme telomerase".
Summary
This year's Nobel Prize in Physiology or Medicine is awarded to three
scientists who have solved a major problem in biology: how the
chromosomes can be copied in a complete way during cell divisions and how
they are protected against degradation. The Nobel Laureates have shown that
the solution is to be found in the ends of the chromosomes – the telomeres –
and in an enzyme that forms them – telomerase.
The long, thread-like DNA molecules that carry our genes are packed into
chromosomes, the telomeres being the caps on their ends. Elizabeth
Blackburn and Jack Szostak discovered that a unique DNA sequence in the
telomeres protects the chromosomes from degradation. Carol Greider and
Elizabeth Blackburn identified telomerase, the enzyme that makes telomere
DNA. These discoveries explained how the ends of the chromosomes are
protected by the telomeres and that they are built by telomerase.
If the telomeres are shortened, cells age. Conversely, if telomerase activity is
high, telomere length is maintained, and cellular senescence is delayed. This
is the case in cancer cells, which can be considered to have eternal life.
Certain inherited diseases, in contrast, are characterized by a defective
telomerase, resulting in damaged cells. The award of the Nobel Prize
recognizes the discovery of a fundamental mechanism in the cell, a discovery
that has stimulated the development of new therapeutic strategies.
The mysterious telomere
The chromosomes contain our genome in their DNA molecules. As early as
the 1930s, Hermann Muller (Nobel Prize 1946) and Barbara McClintock
(Nobel Prize 1983) had observed that the structures at the ends of the
chromosomes, the so-called telomeres, seemed to prevent the chromosomes
from attaching to each other. They suspected that the telomeres could have a
protective role, but how they operate remained an enigma.
When scientists began to understand how genes are copied, in the 1950s,
another problem presented itself. When a cell is about to divide, the DNA
molecules, which contain the four bases that form the genetic code, are
copied, base by base, by DNA polymerase enzymes. However, for one of the
two DNA strands, a problem exists in that the very end of the strand cannot
be copied. Therefore, the chromosomes should be shortened every time a cell
divides – but in fact that is not usually the case (Fig 1).
Both these problems were solved when this year's Nobel Laureates
discovered how the telomere functions and found the enzyme that copies it.
Telomere DNA protects the chromosomes
In the early phase of her research career, Elizabeth Blackburn mapped DNA
sequences. When studying the chromosomes of Tetrahymena, a unicellular
ciliate organism, she identified a DNA sequence that was repeated several
times at the ends of the chromosomes. The function of this sequence,
CCCCAA, was unclear. At the same time, Jack Szostak had made the
observation that a linear DNA molecule, a type of minichromosome, is
rapidly degraded when introduced into yeast cells.
Blackburn presented her results at a conference in 1980. They caught Jack
Szostak's interest and he and Blackburn decided to perform an experiment
that would cross the boundaries between very distant species (Fig 2). From
the DNA of Tetrahymena, Blackburn isolated the CCCCAA sequence.
Szostak coupled it to the minichromosomes and put them back into yeast
cells. The results, which were published in 1982, were striking – the telomere
DNA sequence protected the minichromosomes from degradation. As
telomere DNA from one organism, Tetrahymena, protected chromosomes in
an entirely different one, yeast, this demonstrated the existence of a
previously unrecognized fundamental mechanism. Later on, it became
evident that telomere DNA with its characteristic sequence is present in most
plants and animals, from amoeba to man.
An enzyme that builds telomeres
Carol Greider, then a graduate student, and her supervisor Blackburn started
to investigate if the formation of telomere DNA could be due to an unknown
enzyme. On Christmas Day, 1984, Greider discovered signs of enzymatic
activity in a cell extract. Greider and Blackburn named the enzyme
telomerase, purified it, and showed that it consists of RNA as well as protein
(Fig 3). The RNA component turned out to contain the CCCCAA sequence.
It serves as the template when the telomere is built, while the protein
component is required for the construction work, i.e. the enzymatic activity.
Telomerase extends telomere DNA, providing a platform that enables DNA
polymerases to copy the entire length of the chromosome without missing the
very end portion.
Telomeres delay ageing of the cell
Scientists now began to investigate what roles the telomere might play in the
cell. Szostak's group identified yeast cells with mutations that led to a gradual
shortening of the telomeres. Such cells grew poorly and eventually stopped
dividing. Blackburn and her co-workers made mutations in the RNA of the
telomerase and observed similar effects in Tetrahymena. In both cases, this
led to premature cellular ageing – senescence. In contrast, functional
telomeres instead prevent chromosomal damage and delay cellular
senescence. Later on, Greider's group showed that the senescence of human
cells is also delayed by telomerase. Research in this area has been intense and
it is now known that the DNA sequence in the telomere attracts proteins that
form a protective cap around the fragile ends of the DNA strands.
An important piece in the puzzle – human ageing, cancer, and stem cells
These discoveries had a major impact within the scientific community. Many
scientists speculated that telomere shortening could be the reason for ageing,
not only in the individual cells but also in the organism as a whole. But the
ageing process has turned out to be complex and it is now thought to depend
on several different factors, the telomere being one of them. Research in this
area remains intense.
Most normal cells do not divide frequently, therefore their chromosomes are
not at risk of shortening and they do not require high telomerase activity. In
contrast, cancer cells have the ability to divide infinitely and yet preserve
their telomeres. How do they escape cellular senescence? One explanation
became apparent with the finding that cancer cells often have increased
telomerase activity. It was therefore proposed that cancer might be treated by
eradicating telomerase. Several studies are underway in this area, including
clinical trials evaluating vaccines directed against cells with elevated
telomerase activity.
Some inherited diseases are now known to be caused by telomerase defects,
including certain forms of congenital aplastic anemia, in which insufficient
cell divisions in the stem cells of the bone marrow lead to severe anemia.
Certain inherited diseases of the skin and the lungs are also caused by
telomerase defects.
In conclusion, the discoveries by Blackburn, Greider and Szostak have added
a new dimension to our understanding of the cell, shed light on disease
mechanisms, and stimulated the development of potential new therapies.
Elizabeth H. Blackburn has US and Australian citizenship. She was born in
1948 in Hobart, Tasmania, Australia. After undergraduate studies at the
University of Melbourne, she received her PhD in 1975 from the University
of Cambridge, England, and was a postdoctoral researcher at Yale University,
New Haven, USA. She was on the faculty at the University of California,
Berkeley, and since 1990 has been professor of biology and physiology at the
University of California, San Francisco.
Carol W. Greider is a US citizen and was born in 1961 in San Diego,
California, USA. She studied at the University of California in Santa Barbara
and in Berkeley, where she obtained her PhD in 1987 with Blackburn as her
supervisor. After postdoctoral research at Cold Spring Harbor Laboratory,
she was appointed professor in the department of molecular biology and
genetics at Johns Hopkins University School of Medicine in Baltimore in
1997.
Jack W. Szostak is a US citizen. He was born in 1952 in London, UK and
grew up in Canada. He studied at McGill University in Montreal and at
Cornell University in Ithaca, New York, where he received his PhD in 1977.
He has been at Harvard Medical School since 1979 and is currently professor
of genetics at Massachusetts General Hospital in Boston. He is also affiliated
with the Howard Hughes Medical Institute.
References:
Szostak JW, Blackburn EH. Cloning yeast telomeres on linear plasmid
vectors. Cell 1982; 29:245-255.
Greider CW, Blackburn EH. Identification of a specific telomere terminal
transferase activity in Tetrahymena extracts. Cell 1985; 43:405-13.
Greider CW, Blackburn EH. A telomeric sequence in the RNA of Tetrahymena telomerase required for telomere repeat synthesis. Nature 1989;
337:331-7.
The Nobel Assembly, consisting of 50 professors at Karolinska Institutet,awards the Nobel Prize in Physiology or Medicine. Its Nobel Committee evaluates the nominations. Since 1901 the Nobel Prize has been awarded to scientists who have made the most important discoveries for the benefit of mankind.
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