WORLD OF MICROBIOLOGY AND IMMUNOLOGY Bacterial growth and division49•
sequence of the DNA. BACs proved useful in the sequencing
of the human genome.
The BAC is based on a plasmid in Escherichia colithat
is termed the F (for fertility) plasmid. The F plasmid (or F fac-
tor) contains information that makes possible the process called
conjugation. In conjugation, two Escherichia colibacteriacan
physically connect and an exchange of DNA can occur.
A BAC contains the conjugation promoting genetic infor-
mation as well as stretch of DNA that is destined for incorpora-
tion into the bacterium. The foreign DNA (e.g., portion of
human genome) is flanked by sequences that mark the bound-
aries of the insert. The sequences are referred to as sequence tag
connectors. When the BAC becomes incorporated into the
genome of Escherichia colithe sequence tag connectors act as
markers to identify the inserted foreign DNA.
Using a BAC, large stretches of DNA can be incorpo-
rated into the bacterial genome and subsequently replicated
along with the bacterial DNA. In molecular biologyterminol-
ogy, pieces of DNA that contain hundreds of thousands of
nucleotides (the building blocks of DNA) can be inserted into
a bacterium at one time. As the process is done using different
sections of the foreign DNA, the amount of DNA that can be
analyzed can be very large.
BACs were developed in 1992. Since then, their useful-
ness has grown immensely. The primary reason for this popu-
larity is the stability of the inserted DNA in the bacterial
genome. Because the inserted DNA remains in the bacterial
genome during repeated cycles of replication, the information
is not lost. As well, the BAC can be sequenced using the nor-
mal tools of molecular biology.
The most dramatic recent example of the power of
BACs is their use by The Institute for Genomic Research
(TIGR) in the technique of shotgun cloningthat was employed
in the sequence determination of the human genome. Many
fragments of the human genome could be incorporated into
BACs. The resulting “library” could be expressed in
Escherichia coliand the sequences determined. Subsequently,
these sequences could be reconstructed to produce the orderly
sequence of the actual genome. This approach proved to be
less expensive and quicker than the method known as directed
sequencing, where a genome was sequenced in a linear fash-
ion starting at one end of the genome.
The total number of fragments of the DNA from the
human genome that have been expressed in Escherichia coli
by the use of BACs is now close to one million. In addition to
the human genome, BACs have also been used to sequence the
genome of agriculturally important plants such as corn and
rice, and of animals such as the mouse.
With the realization of the sequence of the human
genome, the use of BACs is becoming important in the screen-
ing of the genome for genetic abnormalities. Indeed, BAC
cloning kits are now available commercially for what is
termed genomic profiling.See alsoBiotechnology; Plasmid and plastidBACTERIAL EPIDEMICS•seeEPIDEMICS, BACTERIAL
BACTERIAL FOSSILIZATION •seeFOSSILIZATION
OF BACTERIABACTERIAL GENETICS•seeMICROBIAL GENETICS
BBacterial growth and divisionACTERIAL GROWTH AND DIVISION
The growth and division of bacteriais the basis of the increase
of bacterial colonies in the laboratory, such as colony forma-
tion on agarin a liquid growth medium, in natural settings,
and in infections.
A population of bacteria in a liquid medium is referred
to as a culture. In the laboratory, where growth conditions of
temperature, light intensity, and nutrients can be made ideal
for the bacteria, measurements of the number of living bacte-
ria typically reveals four stages, or phases, of growth, with
respect to time. Initially, the number of bacteria in the popula-
tion is low. Often the bacteria are also adapting to the envi-
ronment. This represents the lag phase of growth. Depending
on the health of the bacteria, the lag phase may be short or
long. The latter occurs if the bacteria are damaged or have just
been recovered from deep-freeze storage.
After the lag phase, the numbers of living bacteria rap-
idly increases. Typically, the increase is exponential. That is,
the population keeps doubling in number at the same rate. This
is called the log or logarithmic phase of culture growth, and is
the time when the bacteria are growing and dividing at their
maximum speed. For Escherichia coli, for example, the rate
of growth and division of a single bacterium (also called the
generation time) during the log phase is 15 to 20 minutes. In
the log phase, most of the bacteria in a population are growing
and dividing.
The explosive growth of bacteria cannot continue for-
ever in the closed conditions of a flask of growth medium.
Nutrients begin to become depleted, the amount of oxygen
becomes reduced, and the pHchanges, and toxic waste prod-
ucts of metabolic activity begin to accumulate. The bacteria
respond to these changes in a variety of ways to do with their
structure and activity of genes. With respect to bacteria num-
bers, the increase in the population stops and the number of
living bacteria plateaus. This plateau period is called the sta-
tionary phase. Here, the number of bacteria growing and
dividing is equaled by the number of bacteria that are dying.
Finally, as conditions in the culture continue to deterio-
rate, the proportion of the population that is dying becomes
dominant. The number of living bacteria declines sharply over
time in what is called the death or decline phase.
Bacteria growing as colonies on a solid growth medium
also exhibit these growth phases in different regions of a
colony. For example, the bacteria buried in the oldest part of
the colony are often in the stationary or death phase, while the
bacteria at the periphery of the colony are in the actively divid-
ing log phase of growth.
Culturing of bacteria is possible such that fresh growth
medium can be added at rate equal to the rate at which cul-
ture is removed. The rate at which the bacteria grow iswomi_B 5/6/03 1:09 PM Page 49