Engineering Adherent Bacteria by Creating a Single Synthetic Curli Operon

Summary

The design of a synthetic operon encoding both the secretory apparatus and the structural monomers of curli fibers is described. Overproduction of these amyloids and adherent polymers allows a measurable gain of adherence of the E. coli chassis¹. Easy ways to visualize and quantify adherence are explained.

Abstract

The method described here consists in redesigning E. coli adherence properties by assembling the minimum number of curli genes under the control of a strong and metal-overinducible promoter, and in visualizing and quantifying the resulting gain of bacterial adherence. This method applies appropriate engineering principles of abstraction and standardization of synthetic biology, and results in the BBa_K540000 Biobrick (Best new Biobrick device, engineered, iGEM 2011).

The first step consists in the design of the synthetic operon devoted to curli overproduction in response to metal, and therefore in increasing the adherence abilities of the wild type strain. The original curli operon was modified in silico in order to optimize transcriptional and translational signals and escape the "natural" regulation of curli. This approach allowed to test with success our current understanding of curli production. Moreover, simplifying the curli regulation by switching the endogenous complex promoter (more than 10 transcriptional regulators identified) to a simple metal-regulated promoter makes adherence much easier to control.

The second step includes qualitative and quantitative assessment of adherence abilities by implementation of simple methods. These methods are applicable to a large range of adherent bacteria regardless of biological structures involved in biofilm formation. Adherence test in 24-well polystyrene plates provides a quick preliminary visualization of the bacterial biofilm after crystal violet staining. This qualitative test can be sharpened by the quantification of the percentage of adherence. Such a method is very simple but more accurate than only crystal violet staining as described previously ¹ with both a good repeatability and reproducibility. Visualization of GFP-tagged bacteria on glass slides by fluorescence or laser confocal microscopy allows to strengthen the results obtained with the 24-well plate test by direct observation of the phenomenon.

Introduction

Bacterial adherence to abiotic support plays a major role in bioremediation, biocatalysis or microbial fuel cells. Bioremediation processes use the capacities of microorganisms to degrade organic substances, or to modify the metal distribution (immobilization, volatilization) or speciation. These beneficial activities are observed in aquatic and terrestrial ecosystems, but also in the artificial systems developed to treat polluted water of industrial and domestic wastes. The intensity and the quality of the microbial activity depend on physico-chemical factors, but also on the lifestyle of microorganisms (free-floating or embedded into biofilm). The biofilm formation is associated with a metabolism promoting resistance to biocides by diverse mechanisms. This phenomenon will therefore be encouraged in most bioremediation processes. Moreover, engineering Escherichia coli cells to control the biofilm formation has been successfully applied to immobilize whole-cell sensors on biochips^2-3.

Adaptation of microorganisms to high concentration of metals occurs via diverse mechanisms such as adsorption to extracellular matrix components, activation of efflux pump or specific carriers able to concentrate the metal into the cell. Boosting these bacterial activities via genetic engineering allows efficient and cheap treatment of metal pollution at the laboratory scale, especially in the case of highly toxic metals in weak quantity as described by Raghu et al. 2008 ⁴. Bacterial remediation represents in this case a competitive and cost saving method compared to classical chemical processes using ion exchange resins. The authors described an E. coli chassis genetically engineered for cobalt uptake and retention first by knocking out the efflux pump encoding gene rcnA, and then by transformation with a multi copy plasmid allowing overproduction of a transporter with preferential uptake for cobalt. Such a strain appears as an efficient alternative to ion exchange resins to treat radioactive effluent, but a key unresolved issue is the recovery of contaminated bacteria at the end of the process ⁴. The objective of our work was therefore to engineer a custom-designed strain able to stick to abiotic supports such as glass or plastic.

Amongst the whole set of adhesins and adherent fimbriae identified in Gram- bacteria, we chose to design a system allowing curli production. Curli are thin (2-5 nm diameter) and highly aggregative amyloid fibers that protrude from the E. coli and Salmonella surface as a non-crystalline and insoluble matrix ^5-7. Curli are also involved in the colonization of abiotic surfaces and the development of biofilms ⁸. Curli were recently shown to bind mercury ions ⁹. Amyloids are indeed known to possess high affinity for metals ions such as Cu²⁺, Zn²⁺ and Fe^{3+ 10}. This property might further improve the decontamination of metal polluted effluents. The csg cluster is responsible for the production of curli fibers and is constituted of two divergently transcribed operons (Figure 1). The csgB, csgA and csgC genes constitute the sense operon, encoding the two curli subunits, CsgA and CsgB. CsgC seems to be involved in redox activity within the curli biogenesis system and to affect CsgG pore behavior ¹¹. However, the absence of csgC in the majority of curli-producing bacteria indicates that the corresponding protein provides only a secundary level of control over the curli biogenesis. To simplify the system, we have been chosen to work with the minimum number of genes.

The csgDEFG operonencodes proteins essential in the regulation and transportation of CsgA and CsgB to the cell surface. CsgD is a transcriptional activator of the csgBAC operon and plays a key role in the control of biofilm formation by controlling the production of curli fimbriae and other biofilm components such as cellulose ¹² and by inhibiting the flagellum production ¹³. CsgE, CsgF and CsgG constitute a curli-specific secretory apparatus in the outer-membrane through which the major curli subunit protein CsgA is secreted as a soluble protein. The polymerization of CsgA is dependent in vivo on the membrane-bound nucleator protein CsgB (reviewed in ¹⁴). Complex regulatory pathways involving several two-component systems have been shown to control curli gene expression ^15-16. These complex regulations allow bacteria to form thick biofilms via the curli production in response to environmental cues, but are difficult to control for industrial applications. To facilitate the recovery of the metal-stuffed bacteria during an industrial process, bacterial fixation to a solid support indeed needs to be controlled by well defined parameter(s). The adherent properties of curli are linked to their amyloid nature ¹⁷ and could be used to improve bioremediation processes, but a simpler and easily controlled device has to be created.

Amongst these 7 genes ¹⁸, a set of 5 absolutely required genes for curli synthesis (csgB and csgA encoding fiber monomers) and export (csgE csgF and csgG, encoding the curli secretion complex) were selected to construct the synthetic operon. To escape the "natural" regulation of curli, a synthetic operon comprising these 5 csg genes under the control of a strong and cobalt-overinducible promoter (Figure 2) was designed and synthesized. The step-by-step analysis of the curli-encoding region and the design procedure for a functional synthetic operon are described. Two methods to visualize and quantify bacterial adherence to polystyrene and glass are explained.

Protocol

1. Biobrick Design and Synthesis of the Curli Operon

1. Determine the genetic organization and localize the endogenous transcriptional and translational signals of the curli genes. These informations are gathered in specialized databases such as RegulonDB^a or EcoGene^b and completed by a careful reading of pertinent publications. Data management and in silico preanalysis were performed with Clone Manager software^c.
2. Select the pertinent coding sequences. A set of five absolutely required genes for curli synthesis (csgB and csgA encoding fiber monomers) and export (csgE csgF and csgG, encoding the curlin secretion complex) were selected to construct the synthetic operon. Extract the chosen sequences from the data base in FASTA format.
   As the csgGFE cluster is antisense in E. coli genome, convert this sequence into its reverse complement counterpart by using the Clone Manager tools Operations> Process molecule>Invert molecule. Paste the csgEFG sequence behind csgBA by using the function "Ligate" (Clone> Ligate).
3. Add the appropriate promoter. By placing the five selected curli genes under control of the promoter Prcn, curli are predicted to be over-produced in presence of cobalt and nickel. The rcn locus encodes an efflux pump responsible for Ni and Co detoxification (rcnA) and its cognate metallo-regulator (rcnR). RcnR controls the expression of rcnA and its own gene in response to Ni and Co ¹⁹. The rcn sequence comprising rcnR CDS, the whole rcn intergenic region plus the 41 first nucleotides of rcnA was placedin front of the csgBAEFG chimerical sequence (Figure 1, the sequence of the whole construct is provided as supplementary data).
4. Optimize the transcriptional signals. A perfect ribosome binding site (or perfect RBS= AAGGAGGTATATA) was added in front of the first ATG of the csgBA DNA sequence. A second perfect RBS was added in front of the csgEFG sequence. Endogenous RBS for the csgB and csgF and csgG genes were conserved.
5. To fit iGEM standards, the device must be flanked by a standard BioBrick prefix and suffix, containing restriction sites for EcoRI, PstI (prefix) and SpeI and XbaI (suffix). Paste the corresponding sequences at each end of the device^d.
6. Eliminate any EcoRI, PstI, SpeI and XbaI recognition site in the device. To facilitate further assembly process, the BioBrick part itself may not contain any of these restriction sites. In silico restriction analysis of the device revealed one PstI site in the csgA sequence, one PstI site in the rcnR sequence and one EcoRI site in the csgE gene. These sites are respectively located in position 80 (Mut1), 1340 (Mut2) and 1830 (Mut3) of the device sequence (supplementary data) and were modified as follow by silent mutations.
   Mut1 PstI site CTGCAG changed in CGTCTG
   Mut2 PstI site CTGCAG changed in CAGCAG
   Mut3 EcoRI site GAATTC changed in GAATT
7. Run through the translation simulation using the Clone Manager software (Operation>Process molecules>Translate molecules). Use the sequence alignment program BLAST to verify the perfect homology between the wild type curli protein and the proteins encoded by the synthetic operon.
8. Order the synthetic operon. Commercial gene synthesis services are available from numerous companies worldwide, our partner was Genecust (Luxembourg). 4 μg of the artificial operon (3165 bp) were received few weeks later and inserted into pUC57 (pIG2).

2. Visualize and Quantify Adherent Bacteria on Polystyrene

1. Fill each well of a 24-well polystyrene plate with 2 ml of M63 minimal medium (glucose 0.2%) and inoculate each well with 106 cells of an overnight culture. Grow bacteria at 30 °C for 18 to 48 hr without shaking. Each column (4 wells) represents a modality. Add the proper amount of cobalt (25 to 100 mM) and antibiotic (ampicillin 100 μg.L^-1) when needed. The 3 first rows of the 24-well plate are used to quantify the adherent bacteria by averaging the 3 repetitions, the last row left is used to visualize the biofilm.
2. For the 3 first rows of the 24-well plate: for each well, recover the supernatant containing the planktonic cells.
3. Carefully rinse each well with 1 ml of M63 and pool the 1 ml wash with the initial supernatant obtained in 2.2). This pool is referred to as swimming cells (=S).
4. Recover the biofilm in 1 ml of M63 by scraping and pipetting up and down (=B). Vortex 15 sec. Estimate the number of surface-attached and swimming bacteria from the optical density at 600 nm (OD600) to give the adherence percentage corresponding to each modality.
5. The percentage of adherence is calculated by using the formula: Bx100/(3xS+B).
6. Only for the last row of the 24-well plate: discard planktonic cells.
7. Rinse with 1 ml of M63 the biofilm which had developed on the bottom of the plate.
8. Dry the open plate for 1 hr at 80 °C.
9. Add 100 μl of 20% crystal violet for 2 min in each well followed by extensive washes with water to visualize the surface-attached bacteria.
   Three independent assays (plates) have to be performed to ensure reproducibility.

3. Visualize Adherent Bacteria on Glass by Microscopy

1. Get a fluorescent chassis. The E. coli SCC1^e strain which constitutively expresses green fluorescent protein (GFP) with no observable difference from the parent strain MG1655 ²⁰ is a suitable host for the plasmid bearing the synthetic curli operon.
2. Transform SCC1 with the pIG2 plasmid (=synthetic curli operon inserted at the EcoRI/PstI site of the pUC57 plasmid) to obtain the S23 strain. Transform SCC1 with a control plasmid (pUC18) to obtain the control strain S24 ²¹.
3. Grow overnight precultures of the S23 and of the control (S24) strains at 30 °C in M63 medium supplemented with glucose (0.2 %) and ampicillin (100 μg.L^-1).
4. Inoculate 15 ml of the same medium in Petri dishes with 100 μl of the precultures. Add the appropriate concentration of cobalt (i.e. 25 μM) and don't forget the negative control without cobalt. Introduce 3 rectangular glass coverslip in each Petri dish. Incubate overnight at 30 °C without shaking.
5. Remove the coverslip from the Petri dish and carefully drain it. Carefully clean the lower face with a small cotton stuff impregnated with 70 ° ethanol by wiping off every bacterial residue. For confocal observation, clean both upper ends on a few millimeters to allow further fixation of the coverslip.
6. Adherent bacteria can be visualized directly but quickly under fluorescence microscope, but carefully avoid drying of the sample.
7. For confocal observation, deposit the coverslip on a glass slide with the upper face covered by the biofilm placed face up. The biofilm is then covered with a larger coverslip, which is fixed to the glass slide with varnish. Invert the setup so that the biofilm will now be on the lower face.
8. Place the setup under the confocal laser microscope. A right Axioplan2 LSM510 (Zeiss) confocal laser microscope was used at the Platim platform^f.
9. Setting. Excite GFP at 488 nm, and collect the bacterial fluorescence in the range 500 to 600 nm. Use 40x oil immersion objective for acquiring images in laser scanning confocal mode. Scan the overall three-dimensional structures of the biofilms from the solid surface to the interface with the growth medium, using a step of 1 μm.
10. Perform three-dimensional projections with IMARIS software (Bitplane, Zürich, Switzerland). Determine biofilm thickness by the analysis of the average z value along statistical longitudinal sections. Quantification of biofilm biovolumes can be extracted from confocal z-stacks as described elsewhere ²².

^aRegulonDB provides mechanistic information about operon organization and their decomposition into transcription units, promoters and their sigma type, genes and their ribosome binding sites, terminators, binding sites of specific transcriptional regulators,as well as their organization into regulatory phrases. http://regulondb.cs.purdue.edu/index.jsp

^bThe EcoGene database contains updated information about the E. coli K-12 genome and proteome sequences, including extensive gene bibliographies. A major EcoGene focus has been the re-evaluation of translation start sites. http://ecogene.org/

^chttp://www.scied.com/dl_cmp9d.htm

^dhttp://partsregistry.org/wiki/index.php?title=Help:BioBrick_Prefix_and_Suffix

^eGift of Chun Chau Sze, Nan Yang Technical University, Singapore.

^fPlatim microscopic platform UMS3444 BioSciences Gerland - Lyon Sud.

Results

In silico annotation of the wild type csg sequence of E. coli K12 associated with the optimization of transcriptional and translational signals has allowed to design the single synthetic curli operon Prcn-csg shown in Figure 3 (full sequence in supplementary data). Protocol 2 and protocol 3 were used to visualize and quantify adherence associated with curli production. Using crystal violet staining on 24-well polystyrene plates (protocole 2) biofilm formation at the bo...

Discussion

Critical steps

The most critical step in this synthetic biology approach is the gene design. Synthetic gene design has to be meticulous to ensure an efficient system production. Two genes encoding the fiber monomers and three genes encoding proteins involved in their secretion system have been assembled with a strong and metal-inducible promoter to create a new functional unit for a novel application: the bio-decontamination of nuclear effluent. As planned and predicted, this device leads to...

Materials

Name	Company	Catalog Number	Comments
pIG2			pUC57(pMB1 ori, 2710 bp) with a 3165 bp EcoRI/PstI fragment containing the synthetic Prcn-csgBAEFG operon ; Ampr
pUC18			Multicopy plasmid (pMB1 ori, 2686 bp), Ampr
S23			SSC1 (= GFP-tagged MG1655, gift of C.C. Sze)/pIG2
S24			SSC1/pUC18
CoCl2	Sigma		0,1M stock solution kept at Room Temperature
M63			29
24-well plate	Nunc	55429	Polystyrene 24-well plates