The
bacterium Vibrio cholerae O1 causes
epidemics of the disease cholera, and incidences have been well-documented in
areas such as Bangladesh. This pattern is particularly clear at two main
seasonal peaks each year, which coincides with plankton blooms in the spring
and in the autumn. Chitin, a highly abundant substrate in the marine
environment, is thought to affect the population dynamics of V. cholerae, and it is mainly found in
the exoskeletons of crustaceans. These invertebrates feed on the highly
abundant zooplankton during the blooms, which act as a reservoir for the
bacterium. Chitin is heavily colonised by the chinolytic V. cholerae, which breaks it down into soluble constituents that
can be further colonised by these bacteria.
There are three stages to the life cycle of V. cholerae; the non-culturable state,
the reservoir, and the culturable, toxigenic stage which results in cholera
transmission. However, the mechanisms and the capacity of the bacteria to
regain their culturability are not well understood. Shrimp chitin from the estuarine
of Bangladesh was used as the sole nutrient in two different types of
microcosms (artificial ecosystems created for this experiment), the Mathbaria
water (MW) and Mathbaria water supplemented with chitin chips (MW-CC), to
determine how chitin influences both the natural cycle of V. cholerae and seasonal occurrence of cholera in this area of Bangladesh.
DFA Counts
In the
initial counts for Direct Fluorescent Antibodies (DFA), there were similar
numbers of V. cholerae in the MW and
MW-CC microcosms. However, a gradual reduction in counts was found in both
microcosms in the subsequent weekly intervals, with higher cell count for a
longer duration in MW-CC (Cells in MW water were only counted for 49 days). The
cells in the MW-CC microcosm remained culturable for longer than 174 days (when
growing on LB agar), but the counts declined to <10 before the next interval
at day 189.
Multiplex-PCR
Two particular
toxigenic genes in V. cholerae, wbe and ctxA, could still be amplified using Multiplex-PCR (M-PCR) up to
day 174 for MW-CC, but only for 49 days in the MW microcosm. However, the M-PCR
only shows the presence of multiple genes, and do not mention whether the genes
are expressed or not. It may be more appropriate to use
reverse-transcriptase-PCR (RT-PCR) to give a more accurate length of time that
the toxigenic genes are expressed for and hence how long V. cholerae remains in this life stage.
MW with Added Shrimp Chitin Chips
Chitin
degradation was recorded for six months, and it was observed that chitin became
degraded after the chips were initially colonised. During the experiment, it
was noted that large numbers of cells formed clusters of biofilm, and after
further degradation, the majority of the V.
cholerae bacteria were embedded within the biofilm up to day 189, although
there was still some further colonisation of the degraded residue. V. cholerae remained culturable up to
174 days, but no longer showed active growth by day 189.
Addition of HCl
The chitin
biofilm formed by the bacterium was thought to act as a shelter from harmful
environmental conditions, as it is suggested that V. cholerae can survive the stomach acid in humans when they
consume drinking water from the Mathbaria waters containing chitinous material. When concentrated HCl was added, it
was found that the homogenate of the chitin biofilm still had 104
cfu/ml of toxigenic cells present. These results could be supported further by
repeating the experiment in the control MW microcosm as a comparison.
The study
gives support for the ability of V.
cholerae O1 to persist in the plankton reservoir between epidemics using
chitin in estuarine water, which shows that this biopolymer keeps the cells in
the exponential active growth phase for a longer duration. The V. cholerae that are normally found in
the environment are typically toxigenic, but the chitin acts as a food source to
activate the toxigenic stage. However, this paper seems to assume that chitin
degradation is the single cause for the activation of toxigenic V. cholerae, even though there could be
a multitude of interacting factors involved, and the authors make many
inferences biased on their experiments.
Ellie Vaughan & Dave Watt
Nahar, S., Sultana, M., Naser, M.N., Nair, G.B.,
Watanabe, H., Ohnishi, M., Yamamoto, S., Endtz, H., Cravioto, A., Sack, R.B.,
Hasan, N.A., Sadique, A., Huq, A., Colwell, R.R., and Alam, M. (2012) Role of
shrimp chitin in the ecology of toxigenic Vibrio
cholerae and cholera transmission. Frontiers in Microbiology,
2(260). doi: 10.3389/fmicb.2011.00260
Hi Ellie & Dave,
ReplyDeleteFrom what you have explained about various life stages of V. cholerae, one of its life stage is non-culturable. Does that mean V. cholerae are in the viable but non culturable (VBNC) state which is kind of a bacterial response to stress or starvation?
If I get it correctly, from what you have said, it appears that chitin degradation could be one of the mechanisms through which bacteria regain their cultarability. Did the authors say this?
Hi Sanket, thanks for your comment.
DeleteYes, the non-culturable part of its life cycle is when it is not in the plankton reservoir or in its toxigenic form, which tend to occur twice in the year (in the spring and in the autumn). The VBNC state could be a tactic used by the bacteria to survive, until it accumulates in the reservoir or it is able to regain culturability (as the experiments in this study suggest that they use chitin as a shelter from adverse conditions such as the low pH in the digestive system during its culturable, toxigenic stage) but it could otherwise be more vulnerable and less protected if it were in its culturable form. For instance, using the same example I just mentioned, if it was in its toxigenic state without chitin present, the bacteria may not survive the stomach acid of humans when water was consumed from the estuary.
However, this is just the impression I have got when basing assumptions on this paper alone; it does not mean that there might not be other factors that could influence the resilience of V. cholerae. But yes, the authors do say that chitin, and the process of its degradation by V. cholerae, is thought to be one of the triggers of the toxigenic stage which causes cholera. However the authors do not really mention these other options in their study or go into much more detail, so it is something that probably needs further research into.