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Team:LMU-Munich/Bacillus Introduction
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| - | <p align="justify"> In general, bacteria can be divided into two groups that differ in essential characteristics: gram-positive and gram-negative. Escherichia coli is a model organism for the gram-negative bacteria. A model organism for the gram-positive microorganism is ''B. subtilis'', which we work with. The natural habitat of ''B. subtilis'' is soil. Because of the large environmental changes that force ''B. subtilis'' to adapt, this bacterium is very complex. There are many differentiations and survival strategies that ''B. subtilis'' can engages (Fig. 1): Due to its natural competence it can uptake DNA and integrate it into its genome. To be flexibal to the environment and move towards nutrients or avoid toxics it is motile because of its peritrich flagella. There is even cannibalism as one differentation form. If the conditions get to bad for living cells, ''B. subtilis'' can form spores. These are very stable vehicles where the cells are resistant towards e.g. desiccation, heat and pressure. If these spores sense better conditions they are able to germinate again. | + | <p align="justify"> In general, bacteria can be divided into two groups that differ in essential characteristics: gram-positive and gram-negative. Escherichia coli is a model organism for the gram-negative bacteria. A model organism for the gram-positive microorganism is ''B. subtilis'', which we work with. The natural habitat of ''B. subtilis'' is soil. Because of the large environmental changes that force ''B. subtilis'' to adapt, this bacterium is very complex. There are many differentiations and survival strategies that ''B. subtilis'' can engages (Fig. 1): Due to its natural competence it can uptake DNA and integrate it into its genome. To be flexibal to the environment and move towards nutrients or avoid toxics it is motile because of its peritrich flagella. There is even cannibalism as one differentation form. If the conditions get to bad for living cells, ''B. subtilis'' can form spores. These are very stable vehicles where the cells are resistant towards e.g. desiccation, heat and pressure. If these spores sense better conditions they are able to germinate again.</p> |
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<font color="#000000"; size="2">Fig. 1: The various forms ''Bacillus subtilis'' cells may take.</font> | <font color="#000000"; size="2">Fig. 1: The various forms ''Bacillus subtilis'' cells may take.</font> | ||
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| - | ''' | + | There are two major differences between ''B. subtilis'' and ''E. coli'' that are of interest to us: |
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| + | '''1) Natural competence''' ''B. subtilis'' can replicate exogenous DNA via an origin of replication on a plasmid as ''E. coli'' does, but there is a much more elegant way of bringing in exogenous DNA stretches. When flanked by homologous regions to the bacterial genome, it will integrate at high efficiency via homologous recombination at this locus and furthermore be replicated with the genome. This has the advantage that if comparing different variables, not only the enviroment is always the same, but also the copy number is from cell to cell and from strain to strain the same, which is not always the case for replicative plasmids. This integrative way of bringing in exogenous DNA was exploited by us when producing the BioBrick compatible ''Bacillus'' vectors. The comparision between these two ways of bringing in exogenous DNA is depicted in Fig. 2. | ||
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For these reasons, in some cases ''B. subtilis'' can be the chassis of choice. Unfortunately, very few iGEM teams have worked with this model organism, and there is at this time no established BioBrick system to use ''B. subtilis'' as a chassis. | For these reasons, in some cases ''B. subtilis'' can be the chassis of choice. Unfortunately, very few iGEM teams have worked with this model organism, and there is at this time no established BioBrick system to use ''B. subtilis'' as a chassis. | ||
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| - | <font color="#000000"; size="2"><p align="justify">Fig. | + | <font color="#000000"; size="2"><p align="justify">Fig. 2: Exogenous DNA is shown in red while the bacterial genome is black a) The propagation of exogenous DNA if brought in as replicative plasmid. The number of plasmids per cell can vary. b) The propagation of exogenous DNA if it is able to integrate into the genome via homologous recombination</p></font> |
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| + | '''2) Integration of DNA''' ''B. subtilis'' is able to differentiate into cells with different morphology and function (Fig. 1), the most severe form being the endospore which is produced under stress conditions. But there are also phenomena like cannibalism which makes ''B. subtilis'' a lot more diverse to work with. We will exploit the production of endospores in our project '''Bead'''zillus. The life cycle of ''B. subtilis'' is depicted in Fig. 2. | ||
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| + | |[[File:Figures Bacillus Intro fig1.png|500px|center]] | ||
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| + | <font color="#000000"; size="2"><p align="justify">Fig. 2: The vegetative cycle is very similiar to the one of ''E. coli.'' But if there is a stress condition like starvation, the cells enter sporulation, where they first undergo a polar cell division, followed by the formation of the endospore. If the enviromental conditions are suitable again, the spore will then germinate and reenter the vegetative cycle.</p></font> | ||
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| + | <p align="justify">In contrast to ''E. coli'', the model organism ''B. subtilis'' is a gram-postivite rod. It is a facultatively aerobic soil bacterium which can move with its peritrichous flagella. Under ideal conditions, it has a doubling time of 45 minutes. ''B. subtilis'' is, in contrast to ''E. coli'', naturally competent, which means that e.g. under nutrient limitation, 10% of cells in a populaton get competent and take up DNA. Also unique for ''B. subtilis'' is that the vegetative cells can differentiate under nutrient limitations into spores, which we use in our project '''Bead'''zillus. Concerning working with ''B. subtilis'', it is important to know that there are integrative vectors which can integrate into the genome of the organism, in contrast to ''E. coli'', for which there are only replicative vectors. Also both organisms have [http://en.wikipedia.org/wiki/Generally_recognized_as_safe GRAS] state. | ||
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Revision as of 20:32, 26 September 2012
The LMU-Munich team is exuberantly happy about the great success at the World Championship Jamboree in Boston. Our project Beadzillus finished 4th and won the prize for the "Best Wiki" (with Slovenia) and "Best New Application Project".
[ more news ]
Bacillus subtilis - a new chassis for iGEM
We chose to work with Bacillus subtilis to set new horizons and offer tools for this model organism to the Escherichia coli-dominated world of iGEM. To introduce B. subtilis, we want to highlight some important aspects of this organism, which are listed in the taable below.
| Organism | B. subtilis | E. coli |
|---|---|---|
| Type | gram-positive rod | gram-negative rod |
| Motility | + | + |
| Transformation | natural competence | artificial competence |
| Vectors | integrative & replicative | replicative |
| Sporulation | + | - |
| Differentiation | + | - |
| Safety | GRAS | GRAS |
In general, bacteria can be divided into two groups that differ in essential characteristics: gram-positive and gram-negative. Escherichia coli is a model organism for the gram-negative bacteria. A model organism for the gram-positive microorganism is B. subtilis, which we work with. The natural habitat of B. subtilis is soil. Because of the large environmental changes that force B. subtilis to adapt, this bacterium is very complex. There are many differentiations and survival strategies that B. subtilis can engages (Fig. 1): Due to its natural competence it can uptake DNA and integrate it into its genome. To be flexibal to the environment and move towards nutrients or avoid toxics it is motile because of its peritrich flagella. There is even cannibalism as one differentation form. If the conditions get to bad for living cells, B. subtilis can form spores. These are very stable vehicles where the cells are resistant towards e.g. desiccation, heat and pressure. If these spores sense better conditions they are able to germinate again.
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There are two major differences between B. subtilis and E. coli that are of interest to us:
<p align="justify">
1) Natural competence B. subtilis can replicate exogenous DNA via an origin of replication on a plasmid as E. coli does, but there is a much more elegant way of bringing in exogenous DNA stretches. When flanked by homologous regions to the bacterial genome, it will integrate at high efficiency via homologous recombination at this locus and furthermore be replicated with the genome. This has the advantage that if comparing different variables, not only the enviroment is always the same, but also the copy number is from cell to cell and from strain to strain the same, which is not always the case for replicative plasmids. This integrative way of bringing in exogenous DNA was exploited by us when producing the BioBrick compatible Bacillus vectors. The comparision between these two ways of bringing in exogenous DNA is depicted in Fig. 2.
For these reasons, in some cases B. subtilis can be the chassis of choice. Unfortunately, very few iGEM teams have worked with this model organism, and there is at this time no established BioBrick system to use B. subtilis as a chassis.
In contrast to E. coli, the model organism B. subtilis is a gram-postivite rod. It is a facultatively aerobic soil bacterium which can move with its peritrichous flagella. Under ideal conditions, it has a doubling time of 45 minutes. B. subtilis is, in contrast to E. coli, naturally competent, which means that e.g. under nutrient limitation, 10% of cells in a populaton get competent and take up DNA. Also unique for B. subtilis is that the vegetative cells can differentiate under nutrient limitations into spores, which we use in our project Beadzillus. Concerning working with B. subtilis, it is important to know that there are integrative vectors which can integrate into the genome of the organism, in contrast to E. coli, for which there are only replicative vectors. Also both organisms have GRAS state.
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