Operon WORLD OF MICROBIOLOGY AND IMMUNOLOGY416•
be seen if a mutation is present. All of the newer techniques
are more sensitive than cytogenetic analysis and can pick up
abnormal cell lines occurring at very low frequencies.
Clinically, it may be useful to detect the disease in an early
stage when there are fewer cancer cells present so that treat-
ment may begin before severe symptoms are experienced. In
addition, these techniques aid in detection of minimal residual
disease (the presence of low levels of disease after treatment)
and may give warning that the disease is returning.
A major breakthrough has come in treatment of dis-
eases caused by oncogenes. The current standard of care for
cancer patients has been chemotherapyand radiation therapy.
This is successful in limiting or eradicating the disease, but,
because the whole body is affected by these treatments, there
are usually multiple side effects such as hair loss, nausea,
fatigue, etc. New drugs are designed to counteract the partic-
ular mutation associated with the patient’s disease and thus
are target specific. This is only possible if the mutation caus-
ing the disease is known and a treatment can be developed
that inactivates the negative affect of that mutation. Because
only one cellular component is affected, negative physical
side effects may be reduced.
The most successful of these drugs to date is STI-571,
or Gleevec, and was developed for use in patients with chronic
myelogenous leukemia (CML). In CML, the proto-oncogene
translocation results in overproduction of the enzyme tyrosine
kinase. Gleevec is an inhibitor of tyrosine kinase and works at
the cellular level to block excess enzyme activity. Although
there are several different types of tyrosine kinase in humans,
STI-571 is specific to the form produced by the CML mutation
and does not affect other members of this enzyme family. The
drug is therefore so specific, other cells and tissues in the body
are not impacted, and there are few negative side effects
resulting in a therapy that is much more tolerable to the
patient. Early clinical trials showed such a high degree of suc-
cess that the trails were terminated early and the drug was
FDA approved and released for general use. There is now new
evidence to suggest that this drug also may be effective for
other diseases, including some types of solid tumors. This is
clearly the way drug treatments will be designed in the future.
By targeting only the defect and correcting that, a disease can
be managed without impairing other aspects of a patient’s
health or quality of life.
Other types of ongoing research include further elucida-
tion of normal proto-oncogene function and how the onco-
genic mutations change cellular regulation. In particular,
issues involving oncogeneimpact on apoptosis, programmed
cell death, have become an important avenue of investigation.
It has been shown that normal cells have a fixed life span but
that cancer cells lose this characteristic and exhibit uncon-
trolled cell growth with aspects of immortality. A better under-
standing of the role oncogenes play in this process may give
insight into additional ways to treat cancer.See also Fluorescence in situ hybridization (FISH);
Immunogenetics; Immunologic therapies; Mutations and
mutagenesisOOperonPERON
An operon is a single unit of physically adjacent genes that
function together under the control of a single operator gene.
With respect to transcriptionand translation, the genes within
an operon code for enzymesor proteins that are functionally
related and are usually members of a single enzyme system.
The operon is under the control of a single gene that is
responsible for switching the entire operon “on” or “off.” A
repressor molecule that is capable of binding to the operator
gene and switching it, and consequently the whole operon,
off, controls the operator gene. A gene that is not part of the
operon produces the repressor molecule. The repressor mole-
cule is itself produced by a regulator gene. The repressor
molecule is inactivated by a metabolite or signal substance
(effector). In other words, the effector causes the operon to
become active.
The lacoperon in the bacterium E. coliwas one of the
first discovered and still remains one of the most studied and
well known. The deoxyribonucleic acid(DNA) segment con-
taining the lacoperon is some 6,000 base pairs long. This
length includes the operator gene and three structural genes
(lacZ, lacY, and lacA). The three structural genes and the
operator are transcribed into a single piece of messenger
ribonucleic acid (mRNA), which can then be translated.
Transcription will not take place if a repressor protein is bound
to the operator. The repressor protein is encoded by lacI,
which is a gene located to the left of the lacpromoter. The lac
promoter is located immediately to the left of the lacoperator
gene and is outside the lacoperon. The enzymes produced by
this operon are responsible for the hydrolysis (a reaction that
adds a water molecule to a reactant and splits the reactant into
two molecules) of lactose into glucose and galactose. Once
glucose and galactose have been produced, a side reaction
occurs forming a compound called allolactose. Allolactose is
the chemical responsible for switching on the lacoperon by
binding to the repressor and inactivating it.
Operons are generally encountered in lower organisms
such as bacteria. They are commonly encountered for certain
systems, suggesting that there is a strong evolutionary pres-
sure for the genes to remain together as a unit. Operons have
not yet been found in higher organisms, such as multicellular
life forms.
A mutation in the operator gene that renders it non-func-
tional would also render the whole operon inactive. As a direct
result of inactivation, the coded pathway would no longer
operate within the cell. Even though the genes are still sepa-
rate individual units, they cannot function by themselves,
without the control of the operator gene.See alsoGenetic code; Microbial geneticsOOpsonizationPSONIZATION
Opsonization is a term that refers to an immune process where
particles such as bacteriaare targeted for destruction by an
immune cell known as a phagocyte. The process of opsoniza-womi_O 5/7/03 7:58 AM Page 416