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Team:Paris Liliane Bettencourt/Project/Memo-cell/Microcin
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| + | |||
| + | </html><br><br><br><br> | ||
| + | ==What is microcin C?== | ||
| + | <html> | ||
| + | <p style="display:block;"> | ||
| + | <br>Microcins are a class of small (>10-kDa) antibacterial agents produced by Escherichia | ||
| + | coli and its close relatives (1, 2, 15). Microcins are produced from ribosomally synthesized | ||
| + | peptide precursors. The microcin C (McC) is posttranslationally modified by dedicated | ||
| + | maturation enzymes encoded by genes in the microcin C operon mccABCDE (15). McC | ||
| + | is a heptapeptide with covalently attached C-terminal modified AMP (11). The peptide | ||
| + | moiety of McC is encoded by the 21-bp mccA gene, the shortest bacterial gene known | ||
| + | (6). McC (Fig. 1) has a molecular mass of 1,178 Da and contains a formylated N-terminal | ||
| + | methionine, a C-terminal aspartate instead of the asparagine encoded by the mccA gene, | ||
| + | and an AMP residue attached to the | ||
| + | carboxamido group of the modified aspartate | ||
| + | through an N-acyl phosphoramidate bond. The phosphoramidate group is additionally | ||
| + | esterified by a 3-aminopropyl moiety. | ||
| + | <br><br></html> | ||
| + | |||
| + | ==How it works?== | ||
| + | <html> | ||
| + | <p style="display:block;"> | ||
| + | <br>McC is taken up by E. coli through the action of the Yej- ABEF transporter (11) and is | ||
| + | processed once it is inside the cell. Processing involves deformylation of the N-terminal | ||
| + | Met residue by protein deformylase, followed by degradation by any one of the three | ||
| + | broad-specificity aminopeptidases (peptidases A, B, and N) (9). | ||
| + | <br>Processed McC (Fig. 1) strongly inhibits translation by preventing the synthesis of amino- | ||
| + | acylated tRNAAsp by aspartyl-tRNA synthetase (AspRS) (10). | ||
| + | The tRNA aminoacylation reaction catalyzed by aminoacyl tRNA synthetases includes two | ||
| + | steps. First, the enzyme activates a cognate amino acid by coupling it to ATP and forming | ||
| + | aminoacyl-AMP (aminoacyl-adenylate). The aminoacyl moiety is then transferred to tRNA. | ||
| + | <br>Processed McC is structurally similar to aspartyl-AMP but is not hydrolyzable. Thus, | ||
| + | the inhibition of AspRS results from tight binding of processed McC in place of aspartyl- | ||
| + | adenylate. | ||
| + | <br>Thus, McC is a Trojan horse inhibitor (13): the peptide moiety is required for McC delivery | ||
| + | |||
| + | into sensitive cells, where it is processed with subsequent release of the inhibitory | ||
| + | payload. | ||
| + | <br><br></html> | ||
| + | ==Engineering of the microcin C operon.== | ||
| + | <html><p style="display:block;"> | ||
| + | <br> | ||
| + | For our project, we needed to have a inducible death gene, as small as possible (<40bp), | ||
| + | so that it could fit within a recombination site but also could be triggered only when | ||
| + | recombination did not happen, that is to say, when the bacteria did not «count» well. | ||
| + | <br>Hence, microcin C seemed to be the only choice as it is only 24bp long. | ||
| + | <br>However, microcin C is naturally produced by one bacteria to survive in a depleted media | ||
| + | by killing surrounding bacterias, which is the opposite of what we needed. | ||
| + | <br>We had then to engineer to operon so that once induced, the microcin C would kill the | ||
| + | producing bacteria but not the rest of the population. | ||
| + | |||
| + | <br><br>To do this, we had to tackle three major keypoints: | ||
| + | </html> | ||
| + | *1. Knock-out the gene coding for the membrane transporter responsible for the uptake of | ||
| + | the microcin. | ||
| + | *2. Knock-out genes within the operon which are responsible for self-immunity against the | ||
| + | microcin | ||
| + | *3. Mutate the operon so as to delete the four biobrick restriction sites (3 PstI and 1 EcoRI). | ||
| + | <br><html><p style="display:block;"> | ||
Latest revision as of 06:32, 27 October 2010
Memo-Cell project: Microcin
What is microcin C?
Microcins are a class of small (>10-kDa) antibacterial agents produced by Escherichia
coli and its close relatives (1, 2, 15). Microcins are produced from ribosomally synthesized
peptide precursors. The microcin C (McC) is posttranslationally modified by dedicated
maturation enzymes encoded by genes in the microcin C operon mccABCDE (15). McC
is a heptapeptide with covalently attached C-terminal modified AMP (11). The peptide
moiety of McC is encoded by the 21-bp mccA gene, the shortest bacterial gene known
(6). McC (Fig. 1) has a molecular mass of 1,178 Da and contains a formylated N-terminal
methionine, a C-terminal aspartate instead of the asparagine encoded by the mccA gene,
and an AMP residue attached to the
carboxamido group of the modified aspartate
through an N-acyl phosphoramidate bond. The phosphoramidate group is additionally
esterified by a 3-aminopropyl moiety.
How it works?
McC is taken up by E. coli through the action of the Yej- ABEF transporter (11) and is
processed once it is inside the cell. Processing involves deformylation of the N-terminal
Met residue by protein deformylase, followed by degradation by any one of the three
broad-specificity aminopeptidases (peptidases A, B, and N) (9).
Processed McC (Fig. 1) strongly inhibits translation by preventing the synthesis of amino-
acylated tRNAAsp by aspartyl-tRNA synthetase (AspRS) (10).
The tRNA aminoacylation reaction catalyzed by aminoacyl tRNA synthetases includes two
steps. First, the enzyme activates a cognate amino acid by coupling it to ATP and forming
aminoacyl-AMP (aminoacyl-adenylate). The aminoacyl moiety is then transferred to tRNA.
Processed McC is structurally similar to aspartyl-AMP but is not hydrolyzable. Thus,
the inhibition of AspRS results from tight binding of processed McC in place of aspartyl-
adenylate.
Thus, McC is a Trojan horse inhibitor (13): the peptide moiety is required for McC delivery
into sensitive cells, where it is processed with subsequent release of the inhibitory
payload.
Engineering of the microcin C operon.
For our project, we needed to have a inducible death gene, as small as possible (<40bp),
so that it could fit within a recombination site but also could be triggered only when
recombination did not happen, that is to say, when the bacteria did not «count» well.
Hence, microcin C seemed to be the only choice as it is only 24bp long.
However, microcin C is naturally produced by one bacteria to survive in a depleted media
by killing surrounding bacterias, which is the opposite of what we needed.
We had then to engineer to operon so that once induced, the microcin C would kill the
producing bacteria but not the rest of the population.
To do this, we had to tackle three major keypoints:
- 1. Knock-out the gene coding for the membrane transporter responsible for the uptake of
the microcin.
- 2. Knock-out genes within the operon which are responsible for self-immunity against the
microcin
- 3. Mutate the operon so as to delete the four biobrick restriction sites (3 PstI and 1 EcoRI).
