Berg, Paul WORLD OF MICROBIOLOGY AND IMMUNOLOGY60•
an economically devastating disease that dwarfs tobacco
plants and mottles their leaves.
Beijerinck, who graduated from the Delft Polytechnic
School, began his research under the assumption that the
tobacco mosaic disease was caused by an unidentified bac-
terium or a parasite. Attempting to isolate the causative agent,
Beijerinck filtered the sap of an infected plant to remove all
known bacteria; however, the resulting liquid was still infec-
tive. In addition, the filtered substance was capable of infect-
ing another plant, which could infect another, demonstrating
that the substance had the ability to multiply and grow. The
Russian botanist Dmitri Ivanovsky had come up against the
same type of agent, but had failed to report its existence,
assuming instead that his research was flawed.
In 1898 Beijerinck published his work, which main-
tained that tobacco mosaic disease was caused not by bacteria,
but by a living liquid virus that infected only growing plant
organs where cellular division allowed it to multiply. This new
agent he called a filterable virus, from Latin meaning filterable
poison. Louis Pasteurhad speculated about the existence of
germs that were smaller than bacteria, but did not conduct
research into this phenomenon. Beijerinck asserted that the
virus was liquid, but this theory was later disproved by
Wendell Stanley, who demonstrated the particulate nature of
viruses. Beijerinck, nevertheless, set the stage for twentieth-
century virologists to uncover the secrets of viral pathogens
now known to cause a wide range of plant and animal (includ-
ing human) diseases.See alsoVirology; Virus replication; Viruses and responses to
viral infectionBBerg, Paul ERG, PAUL(1926- )
American biochemistPaul Berg developed a technique for splicing together
(DNA)—the substance that carries genetic information in liv-
ing cells from generation to generation—from different types
of organisms. Berg’s achievement, one of the most fundamen-
tal technical contributions to the field of genetics in the twen-
tieth century, gave scientists an invaluable tool for studying
the structure of viral chromosomesand the biochemical basis
of human genetic diseases. It also allowed researchers to turn
simple organisms into chemical factories that churn out valu-
able medical drugs. In 1980 Berg was awarded the Nobel
Prize in chemistry for pioneering this procedure, now referred
to as recombinant DNAtechnology.
The commercial application of Berg’s work underlies a
large and growing industry dedicated to manufacturing drugs
and other chemicals. Moreover, the ability to recombine
pieces of DNA and transfer them into cells is the basis of an
important new medical approach to treating diseases by a
technique called genetherapy.
Berg was born in Brooklyn, New York, one of three
sons of Harry Berg, a clothing manufacturer, and Sarah
Brodsky, a homemaker. He attended public schools, including
Abraham Lincoln High School, from which he graduated in- In a 1980 interview reported in the New York Times,
Berg credited a “Mrs. Wolf,” the woman who ran a science
club after school, with inspiring him to become a researcher.
He graduated from high school with a keen interest in micro-
biology and entered Pennsylvania State University, where he
received a degree in biochemistryin 1948.
Before entering graduate school, Berg served in the
United States Navy from 1943 to 1946. On September 13,
1947, he married Mildred Levy; the couple later had one son.
After completing his duty in the navy, Berg continued his study
of biochemistry at Western Reserve University (now Case
Western Reserve University) in Cleveland, Ohio, where he was
a National Institutes of Health fellow from 1950 to 1952 and
received his doctorate degree in 1952. He did postdoctoral
training as an American Cancer Society research fellow, work-
ing with Herman Kalckar at the Institute of Cytophysiology in
Copenhagen, Denmark, from 1952 to 1953. From 1953 to 1954
he worked with biochemist Arthur Kornberg at Washington
University in St. Louis, Missouri, and held the position of
scholar in cancer research from 1954 to 1957.
He became an assistant professor of microbiology at the
University of Washington School of Medicine in 1956, where
he taught and did research until 1959. Berg left St. Louis that
year to accept the position of professor of biochemistry at
Stanford University School of Medicine. Berg’s background
in biochemistry and microbiology shaped his research inter-
ests during graduate school and beyond, steering him first into
studies of the molecular mechanisms underlying intracellular
protein synthesis.
During the 1950s, Berg tackled the problem of how
amino acids, the building blocks of proteins, are linked
together according to the template carried by a form of RNA
(ribonucleic acid, the “decoded” form of DNA) called mes-
senger RNA (mRNA). A current theory, unknown to Berg at
the time, held that the amino acids did not directly interact
with RNA but were linked together in a chain by special mol-
ecules called joiners, or adapters. In 1956 Berg demonstrated
just such a molecule, which was specific to the amino acid
methionine. Each amino acid has its own such joiners, which
are now called transfer RNA (tRNA).
This discovery helped to stoke Berg’s interest in the
structure and function of genes, and fueled his ambition to
combine genetic material from different species in order to
study how these individual units of heredity worked. Berg rea-
soned that by recombining a gene from one species with the
genes of another, he would be able to isolate and study the
transferred gene in the absence of confounding interactions
with its natural, neighboring genes in the original organism.
In the late 1960s, while at Stanford, Berg began study-
ing genes of the monkey tumor virus SV40 as a model for
understanding how mammalian genes work. By the 1970s, he
had mapped out where on the DNA the various viral genes
occurred, identified the specific sequences of nucleotides in
the genes, and discovered how the SV40 genes affect the DNA
of host organisms they infect. It was this work with SV40
genes that led directly to the development of recombinant
DNA technology. While studying how genes controlled the
production of specific proteins, Berg also was trying to under-
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