Team:Bielefeld-Germany/Biosafety/Biosafety System M

From 2013.igem.org

Revision as of 00:07, 29 October 2013 by Tore (Talk | contribs)



Biosafety System TetOR alive


Overview

Biosafety-System TetOR alive.

The Biosafety-System TetOR alive <bbpart>BBa_K1172915</bbpart> is an improvement of the BioBrick <bbpart>BBa_K914014</bbpart> by replacing the first promoter into the rhamnose promoter PRha, integration of the alanine racemase <bbpart>BBa_K1172901</bbpart> and utilization of the repressor TetR to regulate the transcription of the Barnase behind the tetO promoter. Because this system is known for a tight repression and a fast activation, it is expected that bacteria containing this Biosafety-System are dead or alive...






Genetic Approach


Rhamnose promoter PRha


IGEM Bielefeld 2013 biosafety Rhamnose-promoter.png

The promoter PRha (<bbpart>BBa_K914003</bbpart>) naturally regulates the catabolism of the hexose L-rhamnose. The advantage to use this promoter is its solely positive regulation. The regulon consists of the gene rhaT for the L-rhamnose transporter and the two operons rhaSR and rhaBAD.
The operon rhaSR encodes the two transcriptional activators RhaS and RhaR, who are responsible for the positive activation of the L-rhamnose catabolism, while the operon rhaBAD encodes the genes for the direct catabolism of L-rhamnose.
When L-rhamnose is present, it acts as an inducer by binding to the regulatory protein RhaR. RhaR regulates its own expression and the expression of the regulatory gene rhaS by repressing or, in the presence of L-rhamnose, activating the operon rhaSR. Normally, the expression level is modest, but it can be enhanced by a higher level of intracellular cAMP, which increases in the absence of glucose. So, in the presence of L-rhamnose and a high concentration of intracellular cAMP, the activator protein RhaR is expressed on higher level, resulting in an activation of the promoter PrhaT for an efficient L-rhamnose uptake and an activation of the operon rhaBAD. The L-rhamnose is than broken down into dihydroxyacetone phosphate and lactate aldehyde by the enzymes encoded by rhaBAD (Wickstrum et al., 2005).
A brief schematic summary of the regulation is shown in Figure 1.



Figure 1: The catabolism of L-rhamnose in E. coli is turned off in general but inducible by L-rhamnose. The induction activates the transcription of the genes rhaS and rhaR, which regulate the L-rhamnose catabolism by positive activation of the rhamnose uptake (rhaT) and its metabolization (rhaBAD).


Dihydroxyacetone phosphate can be metabolized in the glycolysis pathway, while lactate aldehyde is oxidized to lactate under aerobic conditions and reduced to L-1,2,-propandiol under anaerobic conditions.
The degradation of L-rhamnose can be separated in three steps. In the first step the L-rhamnose is turned into L-rhamnulose by an isomerase (gene rhaA). L-rhamnulose is in turn phosphorylated to L-rhamnulose-1-phosphate by a kinase (gene rhaB) and the sugar phosphate is finally hydrolyzed by an aldolase (gene rhaD) to dihydroxyacetone phosphate and lactate aldehyde (Baldoma et al., 1988).
For our Safety-System TetOR alive, the rhamnose promoter PRha is used to control the expression of the repressor TetR and the essential alanine racemase, because this promoter has a very low basal transcription. This is needed to tightly repress the expression of the alanine racemase (alr) and thereby take advantage of the double-kill switch. The Tet-System is also characterized by a tight repression, but the induction have to be realized with an antibiotic or anhydrotetracycline(Kamionka et. al, 2004). Although the rhamnose promoter PRha is characterized by a very low basal transcription it can not be used for the control of the toxic RNase Ba (Barnase), which ist needed for the alanine racemase (alr), the other part of the double-kill switch. In conclusion this promoter is the best choice for the first part of the Biosafety-System, as it is tightly repressed in the absence of L-rhamnose, but activated in its presence.





Tetracyclin repressor/operator

IGEM Bielefeld 2013 biosafety TetR.png
IGEM Bielefeld 2013 biosafety TetO.png

The tetracycline repressor (TetR)/ operator (TetO) is naturally used by E. coli to inactivate the bacteriolytic effect of the antibiotic tetracycline.In the absence of tetracycline (continous line) TetR is expressed and forms a homodimer and binds with high affinity to the two tetracycline operator sides tetO1 and tetO2. In the presence of the antibiotic tetracycline, it diffuse through the cell membrane and can inhibit the transpeptidase, which is responsible for the cross-linkage of peptidoglycan. This will result in bacterial cell lysis. When the Tet-System is present the tetracycline uptaken from the environment aggregates with Mg2+ forming a chelate complex (red triangle). This complex binds to TetR causing a conformation switch in the repressor of the tetO operator. This causes that the repressor TetR is released from the tetO operator, resulting in the expression of TetA. TetA is assembled into the cytoplasmic membrane and works as an antiporter by transporting the complex to the outside. This prevent the bacteriolytic effect of the antibiotica. (S Orth et. al., 2000).


Figure 2: Principle of TetR and tetO system in tetracycline resistent bacteria.


For our Biosafety-System TetOR alive we used this System for the regualtion of the toxic RNase Ba. We used the TetR repressor (<bbpart>BBa_C0040</bbpart>) for the regulation of the tetO operator (<bbpart>BBa_R0040</bbpart>) containing the toxic RNase Ba. As this System is known for a tight repression and a high activation, it should be optimal for a Biosafety-System.


Alanine racemase Alr


IGEM Bielefeld 2013 biosafety alr test.png

The alanine racemase Alr (EC 5.1.1.1) from the Gram-negative enteric bacteria Escherichia coli is an isomerase, which catalyses the reversible conversion of L-alanine into the enantiomer D-alanine (see Figure 2). For this reaction, the cofactor pyridoxal-5'-phosphate (PLP) is necessary. The constitutively expressed alanine racemase (alr) is naturally responsible for the accumulation of D-alanine. This compound is an essential component of the bacterial cell wall, because it is used for the cross-linkage of peptidoglycan (Walsh, 1989).
The usage of D-alanine instead of a typically L-amino acid prevents cleavage by peptidases. However, a lack of D-alanine causes to a bacteriolytic characteristics. In the absence of D‑alanine dividing cells will lyse rapidly. This fact is used for our Biosafety-Strain, a D-alanine auxotrophic mutant (K-12 ∆alrdadX). The Biosafety-Strain grows only with a plasmid containing the alanine racemase (<bbpart>BBa_K1172901</bbpart>) to complement the D-alanine auxotrophy. Consequently the alanine racemase is essential for bacterial cell division. This approach guarantees a high plasmid stability, which is extremely important when the plasmid contains a toxic gene like the Barnase. In addition this construction provides the possibility for the implementation of a double kill-switch system. Because if the expression of the alanine racemase is repressed and there is no D-alanine supplementation in the medium, cells will not grow.


Figure 3: The alanine racemase (<bbpart>BBa_K1172901</bbpart>) from E. coli catalyses the reversible conversion from L-alanine to D-alanine. For this isomerization the cofactor pyridoxal-5'-phosphate is necessary.


Terminator


IGEM Bielefeld 2013 biosafety Terminator.png

Terminators are essential to terminate the transcription of an operon. In procaryotes two types of terminators exist. The rho-dependent and the rho-independent terminator. Rho-independent terminators are characterized by their stem-loop forming sequence. In general, the terminator-region can be divided into four regions. The first region is GC-rich and constitutes one half of the stem. This region is followed by the loop-region and another GC-rich region that makes up the opposite part of the stem. The terminator closes with a poly uracil region, which destabilizes the binding of the RNA-polymerase. The stem-loop of the terminator causes a distinction of the DNA and the translated RNA. Consequently the binding of the RNA-polymerase is cancelled and the transcription ends after the stem-loop (Carafa et al., 1990).
For our Bioafety-System TetOR alive the terminator is necessary to avoid that the expression of the genes under control of the rhamnose promoter PRha, like the Repressor TetR and the alanine racemase (alr) results in the transcription of the genes behind the tetracylcine operon tetO which contains the toxic Barnase <bbpart>BBa_K1172904</bbpart> and would lead to cell death.


Figure 4: Stem-loop structure of the terminator <bbpart>BBa_B0015</bbpart>, which is used for the Biosafety-System TetOR alive. The terminator is used to make sure that solely both the repressor TetR and the alanine racemase Alr are expressed but the transcription of the toxic RNase Ba (Barnase) is avoided.



RNase Ba (Barnase)


IGEM Bielefeld 2013 biosafety RNase Ba test.png

The Barnase (EC 3.1.27) is a 12 kDa extracellular microbial ribonuclease, which is naturally found in the Gram-positive soil bacteria Bacillus amyloliquefaciens and consists of a single chain of 110 amino acids. The Barnase (RNase Ba) catalyses the cleavage of single stranded RNA, preferentially behind Gs. In the first step of the RNA-degradation a cyclic intermediate is formed by transesterification and afterwards this intermediate is hydrolyzed yielding in a 3'-nucleotide (Mossakowska et al., 1989).


Figure 5: Enzymatic reaction of the RNA-cleavage by the RNase Ba. First the transesterification by the Glu-73 residue is performed and then this cyclic intermediate is hydrolyzed by the His-102 of the Barnase.


In Bacillus amyloliquefaciens, the activity of the Barnase (RNase Ba) is inhibited intracellular by an inhibitor called barstar. Barstar consists of only 89 amino acids and binds with a high affinity to the toxic Barnase. This prevents the cleavage of the intracellular RNA in the host organism (Paddon et al., 1989). Therefore the Barnase normally acts only outside the cell and is translocated under natural conditions. For the Biosafety-System TetOR alive we modified the enzyme by cloning only the sequence responsible for the cleavage of the RNA, leaving out the N-terminal signal peptide part.
As shown in Figure 6 below, the transcription of the DNA, which encodes the Barnase produces a 474 nt RNA. The translation of the RNA starts about 25 nucleotides downstream from the transcription start and can be divided into two parts. The first part (colored in orange) is translated into a signal peptide at the amino-terminus of the Barnase coding RNA. This part is responsible for the extracellular translocation of the RNase Ba, while the peptide sequence for the active Barnase starts 142 nucleotides downstream from the transcription start (colored in red).
For the Biosafety-System TetOR alive, we only used the part (<bbpart>BBa_K1172904</bbpart>) of the Barnase encoding the catalytic domain without the extracellular translocation signal of the toxic gene product. Translation of the barnase gene leads to rapid cell death if the expression of the Barnase is not repressed by the repressor TetR of our Biosafety-System.


Figure 6: Sequence of the signal peptide amino terminal of the RNase Ba (Barnase). The Biobrick <bbpart>BBa_K1172904</bbpart> does not contain the signal sequence for the extracellular translocation, but only the coding sequence for the mature enzyme.


Biosafety system TetOR alive


Combining the genes described above with the Biosafety-Strain K-12 ∆alrdadX results in a powerful device, allowing us to control the bacterial cell division. The control of the bacterial growth is possible either active or passive. Active by inducing the tetO operon with tetracycline and passive by the induction of L-rhamnose. The passive control makes it possible to control the bacterial cell division in a defined closed environment, like the MFC, by continuously adding L-rhamnose to the medium. As shown in Figure 7 below, this leads to an expression of the essential alanine racemase (alr) and the TetR repressor, so that the expression of the RNase Ba is repressed.


Figure 7:Biosafety-System TetOR alive in the presence of L-rhamnose. The essential alanine racemase (Alr) and the repressor TetR are expressed, resulting in a repression of the expression of the RNAse Ba. Consequently the bacteria show normal growth behavior.


In the event that bacteria exit the defined environment of the MFC or L-rhamnose is not added to the medium any more, both the expression of the alanine Racemase (Alr) and the TetR repressor decrease, so that the expression of the toxic RNase Ba (Barnase) begins. The cleavage of the intracellular RNA by the Barnase and the lack of synthesized D-alanine, caused by the repressed alanine racemase inhibit the cell division. Through this it can be secured that the bacteria can only grow in the defined area or the device of choice respectively.


Figure 8:Active Biosafety-System TetOR alive outside of a defined environment lacking L-rhamnose. Both the expression of the alanine racemase (Alr) and TetR repressor are reduced and ideally completely shut down. In contrast, the expression of the RNase Ba (Barnase) is turned on, leading to cell death by RNA cleavage.


Results


Characterization of the tetracycline tetO operator

First the tetO operator was characterized to get a first impression of its basal transcription rate. Therefore the bacterial growth was investigated under the pressure of the unrepressed tetO operator on different carbon source using M9 minimal medium with either glucose or glycerol. The transcription rate was identified by fluorescence measurement of GFP <bbpart>BBa_E0040</bbpart> behind the tetO operator <bbpart>BBa_R0040</bbpart> using the BioBrick <bbpart>BBa_K1172914</bbpart>.
As shown in Figure 9 below, the bacteria grew slightly better on glucose then on glycerol. This is due to glucose being the better energy source of these two, because glycerol enters glycolysis at a later step and therefore delivers less energy. Moreover an additional ATP consumption is needed to drive glycerol uptake. For the investigation of the basal transcription the fluorescence measurements, shown in Figure 10, is more interesting.
In contrast to the other promoters characterized, like PBAD or Plac, the fluorescence does not differ between the carbon sources used. This was expected in this case, because this operator is not enhanced by intracellular cAMP like the arabinoe or lactose promoter.


Figure 9: Characterization of the bacterial growth of the Biosafety-Strain K-12 ∆alrdadX containing the plasmid <bbpart>BBa_K1172914</bbpart> with GFP (<bbpart>BBa_E0040</bbpart>) under the control of the tetO operator. The M9 medium was supplemented with 5 mM D-alanine. It could be demonstrated, that the bacteria grow faster on M9 minimal medium containing glucose than on M9 minimal medium with glycerol.
Figure 10: Characterization of the fluorescence of the Biosafety-Strain K-12 ∆alrdadX containing the plasmid <bbpart>BBa_K1172914</bbpart> with GFP (<bbpart>BBa_E0040</bbpart>) under control of the tetO operator. The Biosafety-Strain was cultivated on M9 minimal medium supplemented with 5 mM D-alanine..


As for the other characterizations, the specific production rate was calculated to demonstrate in this case, that the carbon source does not influence the basal transcription, as shown in Figure 11. The specific production rates were calculated via equation (1) :


IGEM Bielefeld 2013 Sepzifische Produktionsrate.png


With the calculation of the specific production rate of GFP it can be demonstrated that the GFP synthesis rates does not differ between the cultivation on glucose and glycerol. The specific production rate show fluctuation on both cultivation, resulting in an up and down, so that there is can no obviously obvious be seen. This demonstrates, that tetO operator is not enhanced by cAMP and confirms the results of the lactose and arabinose promoter, as they can be enhanced by cAMP and their basal transcription differs on glucose and glycerol.
Moreover the specific production rate was calculated between every single measurement point, so the curve in Figure 11 is not smoothed and the fluctuations have to be ignored, as they do not stand for real fluctuations in the expression of GFP. They are caused by measurement variations in the growth curve and the fluorescence curve. And as neither of this curves are ideal, the fluctuations are the result. Nevertheless this graph shows the difference between the two carbon sources.


Figure 11: Specific production rate of GFP expressed via the tetO operator in dependence of different carbon sources.


Characterization of the Biosafety-System TetOR alive


The Biosafety-System TetOR alive was characterized on M9 minimal medium using glycerol as carbon source. As for the characterization of the pure tetO operator above, the bacterial growth and the fluorescence of GFP <bbpart>BBa_E0040</bbpart> was measured. Therefore, the wild type and the Biosafety-Strain E. coli K-12 ∆alrdadX both containing the Biosafety-Plasmid <bbpart>BBa_K1172915</bbpart> were cultivated once with the induction of 1% L-rhamnose and once only on glycerol.
It becomes obvious (Figure 12) that the bacteria, induced with 1 % L-rhamnose (red and black curve) grow obviously slower, than on pure glycerol (orange and blue curve). This might be attributed to the high metabolic burden encountered by the induced bacteria. The expression of the repressor TetR and the alanine racemase (Alr) simultaneously causes a high stress on the cells, so that they grow slower than the uninduced cells which express only GFP.
Comparing the bacterial growth with the fluorescence in Figure 15, it can be seen that the fluorescence that the fluorescence of the Biosafety-Strain is much higher than the fluorescence of the wild type. This was also observed for the Biosafety-Strain Lac of Growth and therefore the wild tpye is taken for further analysis of the Biosafety-Plasmid. While the Biosafety-Strain shows an decreasing fluorescence, the wild type shows an expected increase during cultivation. As observed for the other Biosafety-Systems, the flourescence seems to follow the same trend than the bacterial growth. The uninduced cells show approximately an exponential rise of fluorescence, while in comparision the fluorescence of the induced bacteria increases only slowly.


Figure 12: Characterization of the bacterial growth of the Biosafety-System TetOR alive on M9 minimal medium with glycerol. The Figure compares the wild type K-12 and the Biosafety-Strain K-12 ∆alrdadX containing the Biosafety-Plasmid <bbpart>BBa_K1172915</bbpart> and the induction by 1% L-rhamnose to pure glycerol


Figure 13: Characterization of the fluorescence of the Biosafety-System TetOR alive. The Figure compares the wild type K-12 and the Biosafety-Strain K-12 ∆alrdadX containing the Biosafety-Plasmid <bbpart>BBa_K1172915</bbpart> and the induction by 1% L-rhamnose to pure glycerol.


From the data presented above it cannot be determined if the expression of the repressor TetR does affect the transcription of GFP or not. Considering the wild type containing the Biosafety-System, the slower growth is a first indication that the repressor TetR and the alanine racemase (Alr) are highly expressed, but the growth of the bacteria shows nearly the same kinetics as the fluorescence. So it could be possible that the repressor does not affect the expression level of GFP under the control of the tetO operator. This becomes more clear by the calculation of the specific production rate of GFP by equation (1) . As shown in Figure 14 below the specific production rate does not really differ between the uninduced Biosafety-System and the Biosafety-System induced by 1% L-rhamnose.
At the beginning the production of GFP in the presence of L-rhamnose (red curve) is lower than in its absence (orange curve), so that the expression of GFP seems to be repressed in the presence of L-rhamnose, but later one this changes and the specific production rate is constantly higher in the induced Biosafety-Strain. Althought the fluctuation can be ignored, because the specific production rate of GFP was calculated between every single measurement point. The curve in Figure 14 is not smoothed , as they do not stand for real fluctuations in the expression of GFP. They are caused by measurement variations in the growth curve and the fluorescence curve. But this unexpected tendency that the production of GFP is lower when the bacteria are uninduced is obviously, so the Biosafety-System TetOR alive seems not to work unfortunatly. As the Biosafety-System Lac of Growth and AraCtive works there must be a problem in the interaction of the TetR repressor with the tetO operator. This is discussed in the next section.


Figure 14: Specific production rate of GFP for the Biosafety-System TetOR alive, calculated via equation (1). The production rate of GFP of the uninduced bacteria fluctates so that the Biosafety-System might not working as expected.


Conclusions

As mentioned above it seems that the Biosafety-System TetOR alive does not work as expected. This can also be confirmed by Figure 15 showing the specific production rates of GFP after 7,5 hours of the induced Biosafety-System TetOR alive (red bar), the uninduced Biosafety-System (orange bar) and the pure tetO operator (<bbpart>BBa_K1172914</bbpart>). Compared to Figure 14 the difference between the induced and uninduced Biosafety-System is not representative and additionally the lower GFP expression of the tetO operator was also not expected.


Figure 15: Comparison of the specific production rate of GFP. Shown are the induced (1% L-rhamnose) Biosafety-System TetOR alive, the uninduced Biosafety-System TetOR alive and the second part of the Biosafety-System (tetO - GFP only).


References

  • Saenger W. et al. (2000):Der Tetracyclin-Repressor – das Musterbeispiel für einen biologischen Schalter, In:[http://onlinelibrary.wiley.com/doi/10.1002/1521-3757%2820000616%29112:12%3C2122::AID-ANGE2122%3E3.0.CO;2-8/abstract Angewandte Chemie Volume 112, Issue 12, pages 2122–2133]
  • Mossakowska, Danuta E. et al. (1989): Kinetic Characterization of the Recombinant Ribonuclease from Bacillus amyloliquefaciens (Barnase) and Investigation of Key Residues in Catalysis by Site-Directed Mutagenesis [http://pubs.acs.org/doi/pdf/10.1021/bi00435a033 Biochemistry 28: 3843 - 3850].
  • Paddon, C. J. Vasantha, N. and Hartley, R. W. (1989): Translation and Processing of Bacillus amyloliquefaciens Extracellular Rnase [http://www.ncbi.nlm.nih.gov/pmc/articles/PMC209718/pdf/jbacter00168-0575.pdf|Journal of Bacteriology 171: 1185 - 1187].
  • Kamionka, A., Sehnal, M., Scholz, O., Hillen, W. (2004) Independent Regulation of Two Genes in Escherichia coli by Tetracyclines and Tet Repressor Variants [http://www.ncbi.nlm.nih.gov/pmc/articles/PMC421600/pdf/0151-04.pdf|Journal of Bacteriology 186(13): 4399 – 4401.]
  • Voss, Carsten Lindau, Dennis and Flaschel, Erwin (2006): Production of Recombinant RNase Ba and Its Application in Downstream Processing of Plasmid DNA for Pharmaceutical Use [http://onlinelibrary.wiley.com/doi/10.1021/bp050417e/pdf|Biotechnology Progress 22: 737 - 744].
  • Orth P. et al. (2000): Structual basis of gene regulation by the tetracycline inducible Tet repressor-operator system. In: [http://life.nthu.edu.tw/~b871641/tetrepressor.pdf nature structural biology, volume 7 number 3].