Team:LMU-Munich/Germination Stop

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GerminationSTOP

The goal of this subproject was to yield Sporobeads which are safe (unable to germinate) and consistently functional (maintain their spore shape and structure). To achieve this, we sought to remove the germination capability of our spores, while keeping their necessary structural functions intact.

Two approaches were used to achieve this:

• Knock out genes that are involved in germination.

• Suicide switch: Toxin production by vegetative cells if germination knockout fails and spores manage to germinate.

How does Germination Work?

Fig. 1: Taken from [http://www.ncbi.nlm.nih.gov/pubmed/19554258 Kim, J. & Schumann W (2009)]. A: Cell at stage 0; vegetative phase. B: Cell at stage II; asymmetric septum has been formed. C: Cell at stage III; cytoplasmic membrane has engulfed forespore. D: Cell at stage IV; coat formation has started; spore will be released from lysed mother cell.

The Bacillus life cycle can include both classic division, and also reproduction by sporulation and spore germination. In response to starvation of nutrients (including carbon, nitrogen, or phosphorus) or in response to peptides secreted by other cells which signal too high of population densities to cells, Bacillus cells form spores in a process called sporulation. The “mother” cell forms the endospore within its own cell membrane. The endospore contains its DNA in the spore core, which is protected by several layers of coats. The outermost layer is the spore crust. The spore is very dry, and contains a substance called dipicolinic acid (DPA), which is replaced with water when the spore germinates. Until the spore hydrates and swells out of its protective coats, it is resistant to a wide variety of environmental stressors, including UV radiation, toxic chemicals, freezing, high heat, dessication, and pH extremes. This resistance to stressors allows the spore to survive until conditions are good for growth.

On its inner spore membrane, the spore has germinant receptors. The spore coats are believed to be semipermeable or porous, in order to permit the passage of germinants to the receptors. When germinants such as amino acids and sugars reach germinant receptors, the spore begins a biochemical process of germination. It takes up water, shifts its pH, and swells. It breaks out of its coat and begins the outgrowth process. We wish to prevent the germination process.

Fig. 2: The germination process in Bacillus spores. Taken from [http://www.ncbi.nlm.nih.gov/pubmed/14662349 Setlow 2003].

How do Germination Gene Knockouts Work?

Based on the work of others, we chose to knock out genes cwlJ, sleB, cwlB, gerD, and cwlD. Past works showed:

• cwlJ and sleB: both genes code for lytic enzymes which are active in the process of germination. When knocked out together, germination frequency was reduced by 5 orders of magnitude. 
• gerD and cwlB: the gerD product plays unknown role in nutrient germination; cwlB's product plays role in cell wall turnover & cell lysis. When knocked out together, germination frequency was reduced by 5 orders of magnitude. 
• cwlD: this gene codes for recognition components for cleavage by the germination-specific cortex lytic enzymes. When knocked out, germination occurred at a rate of 0.003 to 0.05%.

By knocking out all five of these genes, our goal was to yield a B. subtilis strain which produces spores completely incapable of germination. The stop to germination comes during the process of spore coat breakdown. Without the lytic enzymes to break down the coat, the spores should be unable to outgrow into the vegetative stage. After several attempts to knock out cwlB, and producing extremely slow-growing mutants, cwlB was removed from our list of genes to knock out.

What Methods Did We Use to Knockout Germination Genes?

Two methods were employed to knock out germination: resistance cassette knockouts and clean deletions. Resistance cassette (RC) knockouts were performed using long-flanking-homology PCR (see Protocols). Single RC knockouts were created first; then they were combined to create multiple knockouts.

Fig. 2: Procedure of long-flanking homology PCR. As an example, replacement of cwlD by a kanamycin (kan) resistance cassette is shown. 1000 base-pair fragments flanking cwlD were amplified. Up-reverse and down-forward primers have overhangs complementary to kan cassette. Kan separately amplified. Up and down clwD fragments and amplified kan cassettes were put into the PCR reaction. The result is a fragment containing the kann cassette flanked by cwlD. Bacillus subtilis is transformed with the fragment; replacement is checked by PCR.

Fig. 3: The four germination genes being knocked out, and their resistance cassette replacements, as shown on the Bacillus chromosome.

The germination rate of our mutants were checked with a germination assay. The assay was developed based on the protocols of others. For our method, see Protocols. In the event that some small percentage of spores retained the ability to germinate, the Suicide switch subproject (below) prevents outgrowth into viable vegetative cells.

Suicide switch

Fig. 4: Genetic elements of the Suicide switch and its expected performance.

As a backup plan to make our Sporobeads even safer, we developed the Suicideswitch. In case the spores do germinate, due to degradation or destruction of their outer coats, e.g. by high pressure, the Suicideswitch will be turned on.

It is composed by an alternative sigma factor [http://www.ncbi.nlm.nih.gov/pmc/articles/PMC3426412/ ecf41], which derives from B. lincheniformes and we chose to work with the short version constitutively on. It is synthetically linked to a sigma G regulated promotor responding quite late to sigma G ([http://www.ncbi.nlm.nih.gov/pubmed/15699190 PspoIVB] responding strongly or [http://www.ncbi.nlm.nih.gov/pubmed/15699190 PsspK] responding weakly) which is the last sigma factor activated in the forespore. Through this ecf41 is produced quite late in the forespore. Ecf41 then activates the [http://www.ncbi.nlm.nih.gov/pmc/articles/PMC3426412/ PydfG] promotor, which is the naturally responding promoter to ecf41, which then activates the transcription of [http://jcs.biologists.org/content/118/19/4327.abstract MazF], a bacterial toxin from E.coli degrading mRNA.

The idea behind this is to pack the Sporobeads full with ecf41 when they sporulate, which will in turn kill them upon germination due to the MazF.

Through the system with the alternative sigma factor the forespore gains hopefully enough time to fully mature before MazF starts to be produced.

We chose MazF, as we think it will not be able to harm our Sporobead even if it is made too early, as the spore does not rely on translation to be preserved.

We are planning to model this system.

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