Phage therapy WORLD OF MICROBIOLOGY AND IMMUNOLOGY434•
pathway is followed, transcriptionof the remainder of the
viral genes occurs, and assembly of the virus particles will
occur. The N protein functions in this process, ensuring that
transcription does not terminate.
The path to lysogenyoccurs differently, involving a
protein called cI. The protein is a repressor and its function is
to bind to operator sequences and prevent transcription.
Expression of cI will induce the phage genome to integrate
into the host genome. When integrated, only the cI will be pro-
duced, so as to maintain the lysogenic state.
The virus adopts the lytic or lysogenic path early fol-
lowing infection of the host bacterium. The fate of the viral
genetic material is governed by a competition between the cro
and cI proteins. Both can bind to the same operator region.
The region has three binding zones—cro and cI occupy these
zones in reverse order. The protein, which is able to occupy
the preferred regions of the operator first, stimulates its further
synthesis and blocks synthesis of the other protein.
Analysis of the genetics of phage activity is routinely
accomplished using a plaqueassay. When a phage infects a
lawn or layer of bacterial cells growing on a flat surface, a
clear zone of lysis can occur. The clear area is called a plaque.
Aside from their utility in the study of gene expression,
phage genetics has been put to practical use as well. Cloning
of the human insulin gene in bacteria was accomplished using
a bacteriophage as a vector. The phage delivered to the bac-
terium a recombinant plasmid containing the insulin gene.
M13, a single-stranded filamentous DNA bacteriophage, has
long been used as a cloning vehicle for molecular biology. It is
also valuable for use in DNA sequencing, because the viral
particle contains single-stranded DNA, which is an ideal tem-
plate for sequencing. T7 phage, which infects Escherichia
coli,and some strains of Shigellaand Pasteurella,is a popu-
lar vehicle for cloning of complimentary DNA. Also, the T7
promoter and RNA polymerase are in widespread use as a sys-
tem for regulatable or high-level gene expression.See alsoBacteriophage and bacteriophage typing; Microbial
genetics; Viral geneticsPPhage therapyHAGE THERAPY
Bacteriophageare well suited to deliver therapeutic payloads
(i.e., deliver specific genes into a host organism).
Characteristic of viruses, they require a host in which to make
copies of their genetic material, and to assemble progeny virus
particles. Bacteriophage are more specific in that they infect
solely bacteria.
The use of phage to treat bacterial infections was popu-
lar early in the twentieth century, prior to the mainstream use
of antibiotics. Doctors used phages as treatment for illnesses
ranging from cholera to typhoid fevers. Sometimes, phage-
containing liquid was poured into the wound. Oral, aerosol,
and injection administrations were also used. With the advent
of antibiotic therapy, the use of phage was abandoned. But
now, the increasing resistance of bacteria to antibiotics has
sparked a reassessment of phage therapy.Lytic bacteriophage, which destroy the bacterial cell as
part of their infectious process, are used in therapy. Much of
the focus in the past 15 years has been on nosocomial, or hos-
pital-acquired infections, where multi-drug-resistant organ-
isms have become a particularly lethal problem.
Bacteriophage offer several advantages as therapeutic
agents. Their target specificity causes less disruption to the
normal host bacterial flora, some species of which are vital in
maintaining the ecological balance in various areas of the
body, than does the administration of a relatively less specific
antibiotic. Few side effects are evident with phage therapy,
particularly allergic reactions, such as can occur to some
antibiotics. Large numbers of phage can be prepared easily
and inexpensively. Finally, for localized uses, phage have the
special advantage that they can continue multiplying and pen-
etrating deeper as long as the infection is present, rather than
decreasing rapidly in concentration below the surface like
antibiotics.
In addition to their specific lethal activity against target
bacteria, the relatively new field of genetherapy has also uti-
lized phage. Recombinant phage, in which carry a bit of non-
viral genetic material has been incorporated into their genome,
can deliver the recombinant DNAor RNAto the recipient
genome. The prime use of this strategy to date has been the
replacement of a defective or deleterious host gene with the
copy carried by the phage. Presently, however, technical safety
issues and ethical considerations have limited the potential of
phage genetic therapy.See alsoBacteriophage and bacteriophage typing; Microbial
genetics; Viral genetics; Viral vectors in gene therapyPPhagocyte and phagocytosisHAGOCYTE AND PHAGOCYTOSIS
In the late 1800s and early 1900s, scientific researchers
worked to uncover the mysteries of the body’s immune sys-
tem—the ways in which the body protects itself against harm-
ful invading substances. One line of investigation showed that
immunityis due to protective substances in the blood—anti-
bodies—that act on disease organisms or toxins.
An additional discovery was made by the Russian-
French microbiologist Élie Metchnikoff(1845–1916) in the
1880s. While studying transparent starfish larvae, Metchnikoff
observed certain cells move to, surround, and engulf foreign
particles introduced into the larvae. Metchnikoff then
observed the same phenomenon in water fleas. Studying more
complicated animals, Metchnikoff found similar cells moving
freely in the blood and tissues. He was able to show that these
mobile cells—the white blood corpuscles—in higher animals
as well as humans also ingested bacteria.
The white blood cells responded to the site of an infec-
tion and engulfed and destroyed the invading bacteria.
Metchnikoff called these bacteria-ingesting cells phagocytes,
Greek for “eating cells,” and published his findings in 1883.
The process of digestion by phagocytes is termed
phagocytosis.womi_P 5/7/03 11:09 AM Page 434