Microbiology and Immunology

(Axel Boer) #1
WORLD OF MICROBIOLOGY AND IMMUNOLOGY Jerne, Niels K.

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Physicians in London, insisting that he first pass a test on the
theories of Hippocrates and Galen. Jenner refused to bow to
their demands, saying his accomplishments in conquering
smallpox should have qualified him for election. He was never
elected to the college. Jenner continued his medical practice,
as well as collecting fossils and propagating hybrid plants in
his garden, until his death from a stroke at the age of 73.
Nearly two centuries after Jenner’s experimental vacci-
nation of young James, the World Health Organization
declared endemic smallpox to be eradicated.

See alsoAntibody and antigen; Antibody formation and kinet-
ics; Immunity, active, passive and delayed; Immunity, cell
mediated; Immunity, humoral regulation

JJerne, Niels K.ERNE, NIELSK.(1911-1994)

Danish immunologist

Often considered the founder of modern cellular immunology,
Niels K. Jerne shared the 1984 Nobel Prize for medicine or
physiology with César Milsteinand Georges J. F. Köhler for
his body of work that explained the function of the immune
system, the body’s defense mechanism against disease and
infection. He is best known for three theories showing how
antibodies—the substances which protect the body from for-
eign substances such as virusesand poisons—are produced,
formed, and regulated by the immune system. His theories
were initially met with skepticism, but they later became the
cornerstones of immunological knowledge. By 1984, when
Jerne received the prize, colleagues agreed that he should have
been recognized for his important contributions to the field
much earlier than he was. Jerne’s theories became the starting
point from which other scientists, notably 1960 Nobel Prize
winner Frank MacFarlane Burnett, furthered understanding of
how the body protects itself against disease.
Niels Kaj (sometimes translated Kai) Jerne was born in
London, England, to Danish parents Else Marie Lindberg and
Hans Jessen Jerne. The family moved to the Netherlands at the
beginning of World War I. Jerne earned his baccalaureate in
Rotterdam in 1928, and studied physics for two years at the
University of Leiden. Twelve years later, he entered the
University of Copenhagen to study medicine, receiving his
doctorate in 1951 at the age of forty. From 1943 until 1956 he
worked at the Danish State Serum Institute, conducting
research in immunology.
In 1955, Jerne traveled to the United States with noted
molecular biologist Max Delbrück to become a research fel-
low at the California Institute of Technology at Pasadena. The
two worked closely together, and it was not until his final two
weeks at the institute that Jerne completed work on his first
major theory—on selective antibody formation. At this time,
scientists accepted that specific antibodies do not exist until an
antigen—any substance originating outside the body (e.g., a
virus, snake venom, transplanted organs, etc.)—is introduced,
and acts as a template from which cells in the immune system
create the appropriate antibodyto eliminate it. Antigens and
antibodies have surface patches, called combining sites, with

distinct patterns. When an antibody and antigenwith comple-
mentary combining sites meet, they become attached, fitting
together like a lock and key. Jerne’s theory postulated instead
that the immune system inherently contains all the specific
antibodies it needs to fight specific antigens. The appropriate
antibody, one of millions that are already present in the body,
attaches to the antigen, thus neutralizing or destroying the
antigen and its threat to the body.
Not until some months after developing his theory did
Jerne shared it with Delbrück, who sent it to the Proceedings
of the National Academy of Sciencesfor publication. Jerne
later noted that his theory probably would have been forgot-
ten, except that it caught the attention of Burnett, leading him
to the development in 1959 of his clonal selectiontheory,
which built on Jerne’s hypothesis to show how specific anti-
body-producing cells multiply to produce necessary quantities
of an antigen’s antibody. The following year, Jerne left his
research in immunology to become chief medical officer with
the World Health Organizationin Geneva, Switzerland, where
he oversaw the departments of biological standards and
immunology. From 1960 to 1962, he served on the faculty at
the University of Geneva’s biophysics department.
From 1962 to 1966, Jerne was professor of microbiol-
ogy at the University of Pittsburgh in Pennsylvania. During
this period, he developed a method, now known as the Jerne
plaqueassay, to count antibody-producing cells by first mix-
ing them with other cells containing antigen material, causing
the cells to produce an antibody that combines with red blood
cells. Once combined, the blood cells are then destroyed, leav-
ing a substance called plaque surrounding the original anti-
body-producing cells, which can then be counted. Jerne
became director of the Paul EhrlichInstitute, in Frankfurt,
Germany, in 1966, and, in 1969, established the Basel Institute
for Immunology in Switzerland, where he remained until tak-
ing emeritus status in 1980.
In 1971, Jerne unveiled his second major theory, which
deals with how the immune system identifies and differentiates
between self molecules (belonging to its host) and nonself mol-
ecules (invaders). Noting that the immune system is specific to
each individual, immunologists had concluded that the body’s
self-tolerance cannot be inherited, and is therefore learned.
Jerne postulated that such immune system “learning” occurs in
the thymus, an organ in the upper chest cavity where the cells
that recognize and attack antigens multiply, while those that
could attack the body’s own cells are suppressed. Over time,
mutationsamong cells that recognize antigens increase the
number of different antibodies the body has at hand, thereby
increasing the immune system’s arsenal against disease.
Jerne introduced what is considered his most significant
work in 1974—the network theory, wherein he proposed that
the immune system is a dynamic self-regulating network that
activates itself when necessary and shuts down when not
needed. At that time, scientists knew that the immune system
contains two types of immune system cells, or lymphocytes: B
cells, which produce antibodies, and T cells, which function as
“helpers” to the B cells by killing foreign cells, or by regulat-
ing the B cells either by suppressing or stimulating their anti-
body producing activity. Further, antibody molecules

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