Field of Science

We now join a series of experiments already in progress

In the previous post I described the RNA-seq data that indicates that our antitoxin knockout is unlikely to express functional toxin during log-phase growth, because the promoter it would otherwise repress appears to begin transcription well downstream of the toxin start codon.  The graphic I showed was not exactly the right one, but the evidence is good.)

This would explain why the antitoxin knockout grows normally in rich medium, and suggests we should look for a growth defect when the competence promoter is active.  If we find such a defect, we could explain the observed DNA uptake defect by hypothesizing that cells expressing the toxin fail to take up DNA because they're suffering from a general toxicity (likely a blockage of translation or of gyrase activity), not because the toxin specifically blocks DNA uptake without affecting other processes.

So now I'm doing growth time courses, comparing the wildtype strain KW20 with our ∆0659 antitoxin knockout.  So far the results are a bit messy, but suggestive.

Here's a schematic of the experiments:

Cells are grown (shaking, 37°C) at low density in rich medium for at least two hours.  When the culture reaches OD600 = about 0.25. (about 5 x 10^8 cfu/ml) the cells are washed and transferred (at the same density) to a flask of the 'starvation medium' used to induce maximal competence (again shaking, 37°C).  After 100 minutes the cells are diluted 10-fold into a flask of fresh rich medium, and growth is monitored for several more hours.  

And here's a schematic of the possible outcomes:


It's important to consider the outcome if not all cells are affected by the toxin (Outcome C), because we know from 'congression' experiments that many cells in 'competent' cultures cannot be transformed.  It's hard to give precise numbers because we don't know all the variables, and we don't know if the nontransformable cells in these cultures are expressing the competence genes or not.  Importantly, this is the same outcome we'd see if growth of all cells was slowed but not eliminated by the toxin. 

Results so far:  I was able to process a cfu-measurement time-point (KW20 and ˚0659 samples) every 10-15 minutes.  I took OD time points a bit less frequently (often not at the same times as the cfu samples).  Here's the cfu/ml data:


The blue lines are KW20 and the orange lines are ∆0659.  The lighter blue and orange lines are the cells in the starvation medium.  You can see that the two strains grow at very similar rates in rich medium, but that ∆0659's growth slows down more severely than KW20's in the starvation medium.  ∆0659 may also take longer to recover from starvation.

This looks like Outcome C.

(The plating data is noisier than I would like - I think the ∆0659 strain might be more sensitive to very minor differences in the agar plates.)

Here's the OD600 data for the same cultures:



But this doesn't look like Outcome C!

For the initial growth in rich medium, the OD600 lines parallel the cfu measurements.  I didn't follow the OD600 in competence medium (I will next time).  For the recovery growth, the lines differ. The OD600 values are the same for KW20 and ∆0659, and the both start increasing immediately at the same rate.  After about an hour the mutant's OD600 falls below that of KW20,

Optical density measurements reflect the amount of biomass in the cultures rather than the number of viable cells the biomass is distributed among.  In principle the difference between the two measures (cfu/ml and OD600) tells us about the size of  the cells.  So this result might mean that the mutant cells continue growing (getting bigger) in competence medium and immediately after transfer into rich medium, but are unable to divide.  This interpretation is complicated by the fact that the competence medium itself allows growth but limits cell division - cells typically form filaments in this medium.

Plan:  I'm going to repeat this experiment (probably twice), focusing on the 30 min before transfer to competence medium and the hour after.  I'll try to take a time point every 10 minutes, and to take OD600 measurements at the same times I take cells for the cfu/ml platings.  

If the results agree with those here, then I think we'll be ready to finish writing the manuscript.

p.s.  I also did a separate experiment to get Bioscreen growth curves, for cultures both before and after transfer to competence medium.  (This is also an OD600-based measurement.) The ∆0659 cells always grow a tiny bit slower than KW20 and the ∆toxin, and double-knockout mutants but their recovery kinetics are indistinguishable from their normal growth kinetics, giving no evidence of any time needed for recovery before normal growth resumes.