Cisplatin
2. Control Experiments in the Study of
the Effect of Electric Fields on E. coli
| With the result that application of
an electric field apparently halted bacterial cell division and led to filamentous growth,
Barnett Rosenberg’s group sought to understand better the cause of this phenomenon. (Recall
that filamentous growth occurs when cell division—but not cell growth—is
inhibited.) |
For this reason, the researchers conducted a variety of control
experiments in which they varied one experimental parameter at a time. They knew that the
filamentous growth they had observed in E. coli bacterial cells could be caused by
several known physical and chemical agents such as the following:
- dyes such as methylene blue and penicillin,
- transfer to an unaccustomed medium,
- osmotic pressure changes,
- near ultraviolet irradiation,
- and magnesium deficiency or excess.
Based on the experimental conditions, Rosenberg and his colleagues were able to rule out the first three possibilities. They then conducted a
variety of tests and ruled out not only the last two possibilities but also several
others:
- ultraviolet light,
- temperature,
- pH.
They also found that adaptive mechanisms and
mutation effects in the bacteria did not play a role in filamentous growth.1
The researchers then considered the
possibility that the application of an electric field to the bacterial medium might have
led to an electrolysis reaction and that the chemical products of this reaction might have
affected bacterial cell division. For this reason, they conducted more control
experiments. In one experiment, they decided to separate the electrodes from the E.
coli bacteria. Their new apparatus had two chambers: an electrolysis chamber
containing the electrodes but no bacteria, and a bacterial chamber containing E. coli
cells but no electrodes. In the experiment, the nutrient was pumped into the electrolysis
chamber and a voltage was applied to the electrodes. The nutrient was then pumped from
the electrolysis chamber into the bacterial chamber. The idea was that if a new chemical
species was produced in the electrolysis chamber, and if it was relatively stable
(meaning long-lived), then it would be pumped into the bacterial chamber along with the
nutrient. Such a new chemical species might be the cause of the observed filamentous
growth (also called elongation) of the bacterial cells. The researchers found that under
this new set of experimental conditions, they again observed that the bacterial cells
formed long filaments. From the results of this experiment, they concluded that the application
of the electric current (voltage) was not itself responsible for the observed effects on
bacterial growth, but rather that the electric current led to the formation of a new
chemical species that affected bacterial elongation. Furthermore, they again
observed that oxygen had to be present in the electrolysis chamber for bacterial
elongation to occur.1
This result led them to consider the
possibility that electrolysis was generating an oxidizing agent, which might be contributing to
the observed effects on bacterial growth. They then conducted another control
experiment to look for the presence of an oxidizing agent. One test commonly used to
detect the presence of an oxidizing agent is the potassium iodide-starch test. For
example, if the putative oxidizing agent is a metal ion with a +2 charge (represented here
as M2+), the metal ion gains two electrons to form the neutral,
elemental metal (M0) and is therefore reduced. The two electrons
come from two iodide ions (I-), each of which gives up one electron, producing a molecule
of elemental iodine (I2). When elemental iodine exists in the
presence of excess iodide ion, an acid-base reaction occurs in which elemental iodine acts
as a Lewis acid and iodide ion acts as a Lewis base to produce a triiodide ion, I3-. Triiodide ion is a linear species and forms a blue complex with
starch. Therefore, the potassium iodide-starch test is able to detect the presence of an
oxidizing agent, here M2+. For more information on oxidations and
reductions (i.e., redox chemistry), go to the redox
chemistry and electrochemistry modules.
M2+ + 2 I- ®
M0 + I2 redox reaction
I- + I2 ® I3- acid-base reaction
_____________________________
M2+ + 3 I- ® M0 + I3- net reaction
The researchers used the potassium
iodide-starch test to see whether any oxidizing agents were present in the medium
they were using to grow bacterial cells. They found that the ordinary medium gave no
reaction with potassium iodide and starch but that the electrolyzed medium gave a positive
test, in which a blue color developed after 5 minutes. From this result, they concluded that an oxidizing agent was indeed
present in the medium. Furthermore, they found that the appearance of the
blue color indicating the presence of oxidizing agent coincided with the
elongation of the bacterial cells. And finally, they observed that the intensity
of the blue color corresponded to the frequency of the applied voltage. When the
frequency was 500 c/s, the blue color was most intense, indicating that the concentration
of the oxidizing agent was highest at this frequency; when the frequency was 6,000 c/s,
the blue color was not detectable. (Recall that in the electric
fields module, we learned that when the applied voltage was 500 c/s, filamentous
growth was at a maximum, whereas at 6,000 c/s, no filaments were observed.) These last two
results strongly suggested that a new chemical species, an oxidizing agent, was causing
the changes in bacterial cell growth.1
The next step for the researchers was to determine
the identity of this mystery oxidizing agent. To do this, they ran
another set of control experiments. They deduced that several possible oxidizing agents
could be created from the medium during electrolysis:
- hypochlorite ion (ClO-),
- chlorite ion (ClO2-),
- chlorate ion (ClO3-),
- perchlorate ion (ClO4-),
- hydrogen peroxide (H2O2),
- hydroxylamine (NH2OH),
- and persulfate ion (S2O82-).
Sensitive qualitative tests showed that none
of these ions existed in the medium. In a separate set of control experiments,
each component of the medium was made up in the appropriate concentration and electrolyzed
for 6 amp-h. Following electrolysis, each solution was subjected to the potassium
iodide-starch test. A mixture of negative and positive results were obtained. Negative
tests resulted in the following cases, meaning that no oxidizing agents were found in
these electrolyzed solutions: phosphate ion (PO43-); sulfate ion (SO42-); phosphate ion + glucose; phosphate ion + sulfate ion + glucose;
sodium sulfate (Na2SO4); and sodium carbonate
(Na2CO3). However, oxidizing agents were found
in the following cases, as evidenced by positive tests: ammonium sulfate ((NH4)2SO4); ammonium carbonate
((NH4)2CO3); ammonium
chloride (NH4Cl); and other chlorides. Sodium chloride (NaCl) gave a
faint positive response.1 To learn the conclusions that Rosenberg
and his coworkers reached as a result of this set of control experiments, go to the module
on the role of platinum electrodes.
(1) Rosenberg, B., Camp, L. V., Krigas, T. Nature
,1965, 205, pp. 698-699.
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