Part:BBa_K5246046
Caulobacter crescentus CB2/CB2A HfsA-HfsB-HfsD-HfsF-HfsC-HfsI Polysaccharide export apparatus
Introduction
Vilnius-Lithuania iGEM 2024 project Synhesion aspires to create biodegradable and environmentally friendly adhesives. We were inspired by bacteria, which naturally produce adhesives made from polysaccharides. Two bacteria from aquatic environments - C. crescentus and H. baltica - harness 12 protein synthesis pathways to produce sugars, anchoring them to the surfaces. We aimed to transfer the polysaccharide synthesis pathway to industrially used E. coli bacteria to produce adhesives. Our team concomitantly focused on creating a novel E. coli strain for more efficient production of adhesives.
This is the complete holdfast polymerization and export apparatus. Parts of this composite can be found:BBa_K5246044 and BBa_K5246045.
This part was used in Vilnius-Lithuania iGEM 2024 project "Synhesion" https://2024.igem.wiki/vilnius-lithuania/.
Biology and Usage
Biology
Caulobacter crescentus is a common freshwater gram-negative oligotrophic bacterium of the clade Caulobacterales. Its distinguishing feature is its dual lifestyle. Initially, C. crescentus daughter cells are in a “swarmer” cell phase, which has a flagellum, enabling them to perform chemotaxis. After the motile phase, they differentiate into “stalked” cells. This phase features a tubular stalk with an adhesive structure called a holdfast, allowing them to adhere to surfaces and perform cell division. [1][2]
Caulobacterales synthesize a polysaccharide-based adhesin known as holdfast at one of their cell poles, enabling tight attachment to external surfaces. It is established that holdfast consists of repeating identical units composed of multiple monomers. Current literature agrees that in Caulobacter crescentus, these units form tetrads composed of glucose, an unidentified monosaccharide (either N-mannosamine uronic acid or xylose), N-acetylglucosamine, and N-glucosamine. These units are polymerized and exported to the outer membrane of the cell, where they function as anchors, securing the bacterium to a surface[3][4]. The C. crescentus holdfast is produced via a polysaccharide synthesis and export pathway similar to the group I capsular polysaccharide synthesis Wzy/Wzx-dependent pathway in Escherichia coli. The holdfast synthesis (hfs) genes include those encoding predicted glycosyltransferases, carbohydrate modification factors, and components of a wzy-type polysaccharide assembly pathway. [4][5][6] The synthesis of holdfast polysaccharides (Fig.1) occurs through a mechanism analogous to the Wzx/Wzy-dependent group I capsular polysaccharide biosynthesis pathway observed in Escherichia coli. The process is initiated in the cytoplasm by the glycosyltransferase (1) HfsE, which transfers an activated glucose-phosphate from UDP to an undecaprenyl-phosphate (Und-P) lipid carrier (1) [7]. Subsequent monosaccharide residues are added to the lipid carrier to form a repeating unit by the action of three glycosyltransferases: (2) HfsJ (adding N-mannosamine uronic acid or D-xylose), (3) hfsG (adds N-acetylglucosamine) and (4) HfsL (most likely adding another N-acetylglucosamine) [8]. Then some of the N-acetyl-D-glucosamine within these repeat units undergoes enzymatic modification through the activity of the deacetylases (5) HfsH and HfsK, which “incorporates” into the tetrad of another saccharide - D-glucosamine [9]. The completed repeat of four monomers is then flipped over the inner membrane to the periplasm by flippase HfsF (6) [8]. In the periplasm, the repeat unit is transferred to copolymerases HfsC and HfsI (7), which assemble holdfast into a mature polysaccharide [10]. Subsequently, following the polymerization, holdfast saccharides are exported through a multi-protein export channel made of HfsB, HfsA, and HfsD (8-10) [11]. After excretion, holdfast polymer is relocated to the anchoring Hfa group of proteins (11), where they function by holding the mature polysaccharide on the cell's surface of, e.g. C. crescentus or H. baltica , and securing it to the surface [8].
Usage
BAIGT
Sequence and Features
- 10INCOMPATIBLE WITH RFC[10]Illegal EcoRI site found at 1740
Illegal XbaI site found at 5937
Illegal PstI site found at 4245
Illegal PstI site found at 5744 - 12INCOMPATIBLE WITH RFC[12]Illegal EcoRI site found at 1740
Illegal PstI site found at 4245
Illegal PstI site found at 5744
Illegal NotI site found at 475
Illegal NotI site found at 5417 - 21INCOMPATIBLE WITH RFC[21]Illegal EcoRI site found at 1740
Illegal BglII site found at 5163
Illegal BglII site found at 5535
Illegal BglII site found at 5940
Illegal BglII site found at 6996
Illegal BamHI site found at 3305
Illegal XhoI site found at 6410 - 23INCOMPATIBLE WITH RFC[23]Illegal EcoRI site found at 1740
Illegal XbaI site found at 5937
Illegal PstI site found at 4245
Illegal PstI site found at 5744 - 25INCOMPATIBLE WITH RFC[25]Illegal EcoRI site found at 1740
Illegal XbaI site found at 5937
Illegal PstI site found at 4245
Illegal PstI site found at 5744
Illegal NgoMIV site found at 151
Illegal NgoMIV site found at 343
Illegal NgoMIV site found at 352
Illegal NgoMIV site found at 924
Illegal NgoMIV site found at 1087
Illegal NgoMIV site found at 2026
Illegal NgoMIV site found at 2672
Illegal AgeI site found at 3363
Illegal AgeI site found at 6190 - 1000COMPATIBLE WITH RFC[1000]
Experimental characterization
Part assembly
All of the proteins composing this system are responsible for polysaccharide polymerization and export. Since the system's proteins are found in the membrane, we concluded that using a low-copy plasmid would decrease the probability of inclusion body formation. Their formation would diminish the functionality of our system, as the proteins would not allow the polysaccharide to be exported outside the bacteria.
We had to assemble this part to further create the holdfast synthesis pathway in E. coli together with composite part: BBa_K52460463, we had to assemble this part first into a backbone of pACYC-Duet-1. We designed a strategy to maximize the success of plasmid assembly by first assembling plasmids with 3 genes (part:BBa_K5246044) and, after verifying the sequences, integrating 3 left genes (part:BBa_K5246045) into that backbone (Fig. 2). In this way, we prevented Golden Gate assembly errors by trying to construct plasmids from 8 or more fragments.
The BBa_K5246044 assembly was done using Golden Gate assembly with IIS AarI restriction enzyme sites introduced during PCR amplification. The backbone of pACYC-Duet-1 (Novagen) and fragments were amplified using Phusion Plus DNA polymerase, as the genome of C. crescentus has a high GC% content making the appearance of non-specific products during PCR amplification more common and primer design more challenging (Fig. 3). Since hfsA gene had an AarI RE site directly in the gene, this site was domesticated during side directed mutagenesis.
Due to the high amount of non-specific products, the fragments were gel-purified. Vectors and fragments composing this operon were mixed in equimolar amounts with GG reaction components and incubated as described in the protocol. The reaction was later transformed into E. coli Mach1 (Thermo Scientific) competent cells. The assembly was then confirmed with restriction digest analysis (Fig. 4), and positive colonies were sequenced.
After acquiring sequence-verified clones, we further cloned the 3 remaining genes: hfsF,hfsC, hfsI, this was done the same way as the first 3 genes. After transformation into E. coli , obtained colonies were once again screened with cPCR (Fig. 5) and restriction digestion analysis (Fig. 6). After choosing positive colonies full plasmids with hfsA-hfsB-hfsD-hfsF-hfsC-hfsI were once again sequenced.
Part expression optimization
BL21(DE3)
KRX(DE3)
C41(DE3)
Rosetta(DE3) pLysS
Holdfast polymerization and export apparatus usage for holdfast synthesis
Holdfast synthesis system expression optimization
The intricate holdfast synthesis pathway involves numerous proteins that must be efficiently co-expressed in Escherichia coli. After obtaining plasmids used for full holdfast synthesis pathway assembly, we had to optimize the expression of the whole system in E. coli. Previously, only three studies have tried to recombinantly express C. crescentus proteins in E. coli for unassociated studies with our project's goal [12][13][14]. Since the E. coli strains and protein expression conditions were unrelated to each other, and before our project, no one in iGEM besides the 2009 iGEM ULB-Brussels team ever tried expressing more than two C. crescentus proteins in E. coli at the same time, we had no solid foundation for expression and chose to experiment with different E. coli strains and conditions. Therefore, it was essential to optimize the conditions for simultaneous protein expression by trying different media, temperatures, IPTG concentrations, and expression times on multiple E. coli strains. We used SDS-PAGE analysis of cell lysates and HPLC-MC proteomics to verify the expression results.
Results overview: Optimal C.crescentus protein expression was achieved in the BL21(DE3) strain cultivated in the LB medium. The most favorable conditions included an incubation temperature of 37°C, induction with 0.5 mM IPTG, and an expression duration of 3 hours at 37°C.
KRX(DE3)
To determine the best conditions for the whole system expression, we first used E. coli KRX(DE3) strain. We tried expressing separate plasmids pRSF-(1)HfsE-hsfJ-hfsG-(2)hfsH-hfsK-hfsL (BBa_K5246043) and pACYC-(3)hfsA-hfsB-hfsD-(4)hfsF-hfsC-hfsI (BBa_K5246046) with different IPTG concentrations - 0.1, 0.25, 0.5, 0.75 and 1 mM - and 0.1% rhamnose with protein expression for 3h at 37°C after induction. As we saw, some bands, corresponding to our protein sizes, were appearing in pACYC-(3)hfsA-hfsB-hfsD-(4)hfsF-hfsC-hfsI (BBa_K5246046) expression (Fig. 7.1), but we were not sure if they were our system proteins, therefore for pRSF-(1)HfsE-hsfJ-hfsG-(2)hfsH-hfsK-hfsL (BBa_K5246043) we used negative control with empty pRSF vector and expressed the proteins in similar conditions. We saw that pRSF-(1)HfsE-hsfJ-hfsG-(2)hfsH-hfsK-hfsL (BBa_K5246043) operon proteins were also expressed (Fig. 7.2) with minimal IPTG concentration impact on protein amount.
Protein name | hfsA | hfsE | hfsF | hfsI | hfsC | hfsK | hfsJ | hfsG | hfsL | hfsH | hfsD | hfsB |
---|---|---|---|---|---|---|---|---|---|---|---|---|
Size (kDa) | 55 | 54 | 50 | 48 | 46 | 43 | 35 | 34 | 33 | 28 | 26 | 25 |
Fig. 7.1. SDS-PAGE analysis of pACYC-hfsA-hfsB-hfsD-hfsF-hfsC-hfsI (BBa_K5246046) expression in KRX(DE3) at different IPTG concentrations at 37°C for 3h. M - molecular weight ladder in kDa, Pageruler Unstained Protein Ladder, 26610 (Thermo Scientific).
Fig. 7.2. SDS-PAGE analysis of pRSF-(1)HfsE-hsfJ-hfsG-(2)hfsH-hfsK-hfsL (BBa_K5246043) expression in KRX(DE3) at different IPTG concentrations at 37°C for 3h. M - molecular weight ladder in kDa, Pageruler Unstained Protein Ladder, 26614 (Thermo Scientific).
We decided to use the lower IPTG concentrations - 0.25, 0.5, and 0.75 mM - for gene expression induction of the full system, as it is more cost-effective for upscale in the future. But, unfortunately, full system expression at different temperatures and expression times did not provide clear bands of proteins in SDS-PAGE gel analysis (Fig. 8. 1-5).
Protein name | hfsA | hfsE | hfsF | hfsI | hfsC | hfsK | hfsJ | hfsG | hfsL | hfsH | hfsD | hfsB |
---|---|---|---|---|---|---|---|---|---|---|---|---|
Size (kDa) | 55 | 54 | 50 | 48 | 46 | 43 | 35 | 34 | 33 | 28 | 26 | 25 |
Fig. 8.1. SDS-PAGE analysis of CB2 system expression in KRX(DE3) at different IPTG concentrations for 3h at 37°C. M - molecular weight ladder in kDa, Pageruler Unstained Protein Ladder, 26614 (Thermo Scientific).
Fig. 8.2. SDS-PAGE analysis of CB2 system expression in KRX(DE3) at different IPTG concentrations for 3h at 30°C. M - molecular weight ladder in kDa, Pageruler Unstained Protein Ladder, 26614 (Thermo Scientific).
Fig. 8.3. SDS-PAGE analysis of CB2 system expression in KRX(DE3) at different IPTG concentrations overnight at 30°C. M - molecular weight ladder in kDa, Pageruler Unstained Protein Ladder, 26614 (Thermo Scientific).
Fig. 8.4. SDS-PAGE analysis of CB2 system expression in KRX(DE3) at different IPTG concentrations for 3h at 22°C. M - molecular weight ladder in kDa, Pageruler Unstained Protein Ladder, 26614 (Thermo Scientific).
Only some proteins, in the size range of 30-50 kDa, appeared, but in general, the results of expression of the whole system were inconclusive, leading to the need to test another E. coli strain.
BL21(DE3)
The next E. coli strain we tested was BL21(DE3). Since the IPTG concentration appeared not to make that big of an impact on the expression, we settled on IPTG concentrations of - 0.25, 0.5, and 0.75 mM - in this way covering a wide range of them and accelerating the optimization effort, if the system would be expressed. We also decided to yet again test different expression temperatures - 37°C, 30°C, 16°C - before and after gene expression induction.
Initially, we tested pACYC-(3)hfsA-hfsB-hfsD-(4)hfsF-hfsC-hfsI (BBa_K5246046) operon expression at 37°C for 3h, which did not give promising results (Fig. 9.1), as we could not see distinguishable differences before and after induction. Nevertheless, we proceeded with pRSF-(1)HfsE-hsfJ-hfsG-(2)hfsH-hfsK-hfsL (BBa_K5246043) operon expression at the same conditions, which appeared to be working (Fig. 9.2), as we could see stark differences between empty E. coli and our operon lysates. As with the expression in the KRX strain, we could not see many differences between the IPTG concentrations.
Protein name | hfsA | hfsE | hfsF | hfsI | hfsC | hfsK | hfsJ | hfsG | hfsL | hfsH | hfsD | hfsB |
---|---|---|---|---|---|---|---|---|---|---|---|---|
Size (kDa) | 55 | 54 | 50 | 48 | 46 | 43 | 35 | 34 | 33 | 28 | 26 | 25 |
Fig. 9.1. SDS-PAGE analysis of pRSF-(1)HfsE-hsfJ-hfsG-(2)hfsH-hfsK-hfsL expression in BL21(DE3) at different IPTG concentrations at 37°C for 3h. M - molecular weight ladder in kDa, Pageruler Unstained Protein Ladder, 26614 (Thermo Scientific).
Fig. 9.2. SDS-PAGE analysis of pACYC-(3)hfsA-hfsB-hfsD-(4)hfsF-hfsC-hfsI expression in BL21(DE3) at different IPTG concentrations at 37°C for 3h. M - molecular weight ladder in kDa, Pageruler Unstained Protein Ladder, 26610 (Thermo Scientific). Note: negative control cultures for 0.25 mM and 0.75 mM were contaminated and subsequently not used for SDS-PAGE analysis.
We advanced with the whole system expression. After analyzing expression at 37°C for 3h conditions, we saw that there were pronounced differences between the uninduced system and the system after 3 hours (Fig. 10.1). As with KRX(DE3) expression, we saw that IPTG concentration used for gene expression induction did not make a big impact for overall expression.
Since the CB2 system was expressing, we tried different temperatures to optimize protein expression further. Remarkably, decreasing the expression temperature to 30°C and expression overnight did not make a significant difference as the proteins were still expressed in similar amounts to that of 37°C (Fig. 10.2). Expression of 16°C overnight produced some of the expected bands but not in the same capacity as expression at higher temperatures (Fig.10.3).
Protein name | hfsA | hfsE | hfsF | hfsI | hfsC | hfsK | hfsJ | hfsG | hfsL | hfsH | hfsD | hfsB |
---|---|---|---|---|---|---|---|---|---|---|---|---|
Size (kDa) | 55 | 54 | 50 | 48 | 46 | 43 | 35 | 34 | 33 | 28 | 26 | 25 |
Fig. 10.1. SDS-PAGE analysis of CB2 system expression in BL21(DE3) at different IPTG concentrations for 3h at 37°C. M - molecular weight ladder in kDa, Pageruler Unstained Protein Ladder, 26614 (Thermo Scientific).
Fig. 10.2. SDS-PAGE analysis of CB2 system expression in BL21(DE3) at different IPTG concentrations overnight at 30°C. M - molecular weight ladder in kDa, Pageruler Unstained Protein Ladder, 26614 (Thermo Scientific).
Proteomic analysis of samples induced by 0.5 mM IPTG from separate parts and the whole system, revealed that proteins responsible for holdfast polymerization - hfsC and hfsI - were not expressed (Fig. 11 (a),(b)). In addition, protein levels during full system expression dropped notably compared to separate part expression. However, proteins were still expressed in slightly higher quantities than in control (Fig. 11. (c)).
Nevertheless, as later experiments showed, these proteins were probably substituted by paralogous proteins found in E. coli as the system without 2 parts was still producing a polysaccharide (see BBa_K5246003 and BBa_K5246009 ). We reason that in the future, we should first test whether the separate proteins - hfsC and hfsI - are expressed and at what conditions before assembling new plasmids with different operon orders or additional promoters. T7/lac could serve as a good starting point, other considerations could involve separately inducible or constitutive promoters available in iGEM Parts Registry.
C41(DE3)
Once the system was successfully expressed in BL21(DE3) strain, we proceeded to optimize the expression further by testing another E. coli strain - C41(DE3). We decided to test separate system parts and the whole CB2 system with different IPTG concentrations - 0.25, 0.5, and 0.75 mM. Since we saw that the proteins were best expressed at 37°C in KRX(DE3) and BL21(DE3) strains, we settled on testing only this temperature. SDS-PAGE analysis of cell lysates before and after gene expression induction revealed that proteins were expressed in separate parts of the system and the whole system (Fig. 12. 1-3). Regrettably, the quantity was visibly less than that seen in BL21(DE3) strain indicating that this strain is not suitable for efficient system expression.
Protein name | hfsA | hfsE | hfsF | hfsI | hfsC | hfsK | hfsJ | hfsG | hfsL | hfsH | hfsD | hfsB |
---|---|---|---|---|---|---|---|---|---|---|---|---|
Size (kDa) | 55 | 54 | 50 | 48 | 46 | 43 | 35 | 34 | 33 | 28 | 26 | 25 |
Fig. 12.1. SDS-PAGE analysis of pACYC-(3)hfsA-hfsB-hfsD-(4)hfsF-hfsC-hfsI expression in C41(DE3) at different IPTG concentrations at 37°C for 3h. M - molecular weight ladder in kDa, Pageruler Unstained Protein Ladder, 26610 (Thermo Scientific)
Fig. 12.2. SDS-PAGE analysis of pRSF-(1)HfsE-hsfJ-hfsG-(2)hfsH-hfsK-hfsL expression in C41(DE3) at different IPTG concentrations at 37°C for 3h. M - molecular weight ladder in kDa, Pageruler Unstained Protein Ladder, 26614 (Thermo Scientific).
Rosetta(DE3) pLysS
HMS174(DE3)
12. Liu, Q., Hao, L., Chen, Y., Liu, Z., Xing, W., Zhang, C., Fu, W., & Xu, D. (2022). The screening and expression of polysaccharide deacetylase from Caulobacter crescentus and its function analysis. Biotechnology and Applied Biochemistry, 70(2), 688–696. https://doi.org/10.1002/bab.2390
13. Fiebig, A., Herrou, J., Fumeaux, C., Radhakrishnan, S. K., Viollier, P. H., & Crosson, S. (2014). A Cell Cycle and Nutritional Checkpoint Controlling Bacterial Surface Adhesion. PLoS Genetics, 10(1), e1004101. ,https://doi.org/10.1371/journal.pgen.1004101
14. Patel, K. B., Toh, E., Fernandez, X. B., Hanuszkiewicz, A., Hardy, G. G., Brun, Y. V., Bernards, M. A., & Valvano, M. A. (2012). Functional Characterization of UDP-Glucose:Undecaprenyl-Phosphate Glucose-1-Phosphate Transferases of Escherichia coli and Caulobacter crescentus. Journal of Bacteriology, 194(10), 2646–2657. https://doi.org/10.1128/jb.06052-11
Holdfast biosynthesis
Holdfast synthesis requires glucose
Polysaccharides are produced only in the part of the population
Polysaccharides can not be purified using chemical purification
E. coli with holdfast synthesis pathway produce biofilm-like structures
Different E. coli strains form holdfast polysaccharide
Suitable substrate search for holdfast production
Holdfast composition investigation
Holdfast Protein Expression and Production of Polysaccharides in HMS174(DE3)ΔwecA
Increasing holdfast production efficiency
Investigating the composition of the holdfast polysaccharide
UDP-N-acetyl mannosaminuronic acid (UDP-ManNAc) is a sugar used to make polysaccharides in the CB2 system
FTIR analysis of the holdfast material
References
1. Hendrickson, H., & Lawrence, J. G. (2000). Mutational bias suggests that replication termination occurs near the dif site, not at Ter sites. FEMS Microbiology Reviews, 24(2), 177–183. https://doi.org/10.1111/j.1574-6976.2000.tb00539.x
2. Andrews, S. C., Robinson, A. K., & Rodríguez-Quiñones, F. (2004). Bacterial iron homeostasis. Journal of Bacteriology, 186(5), 1438–1447. https://doi.org/10.1128/jb.186.5.1438-1447.2004
3.Rabah, A., & Hanchi, S. (2023). Experimental and modeling study of the rheological and thermophysical properties of molybdenum disulfide-based nanofluids. Journal of Molecular Liquids, 384, 123335. https://doi.org/10.1016/j.molliq.2023.123335
4. Boutte, C. C., & Crosson, S. (2009). Bacterial lifestyle shapes stringent response activation. Journal of Bacteriology, 191(9), 2904-2912. https://doi.org/10.1128/jb.01003-08
5. Mackie, J., Liu, Y. C., & DiBartolo, G. (2019). The C-terminal region of the Caulobacter crescentus CtrA protein inhibits stalk synthesis during the G1-to-S transition. mBio, 10(2), e02273-18. https://doi.org/10.1128/mbio.02273-18
6.Thanbichler, M., & Shapiro, L. (2003). MipZ, a spatial regulator coordinating chromosome segregation with cell division in Caulobacter. Journal of Bacteriology, 185(4), 1432-1442. https://doi.org/10.1128/jb.185.4.1432-1442.2003
7. Toh, E., Kurtz, H. D., & Brun, Y. V. (2008b). Characterization of the Caulobacter crescentus Holdfast Polysaccharide Biosynthesis Pathway Reveals Significant Redundancy in the Initiating Glycosyltransferase and Polymerase Steps. Journal of Bacteriology, 190(21), 7219–7231. https://doi.org/10.1128/jb.01003-08
8.Chepkwony, N. K., Hardy, G. G., & Brun, Y. V. (2022). HfaE Is a Component of the Holdfast Anchor Complex That Tethers the Holdfast Adhesin to the Cell Envelope. Journal of Bacteriology. https://doi.org/10.1128/jb.00273-22
9. Hershey, D. M., Fiebig, A., & Crosson, S. (2019). A Genome-Wide Analysis of Adhesion inCaulobacter crescentusIdentifies New Regulatory and Biosynthetic Components for Holdfast Assembly. mBio, 10(1). https://doi.org/10.1128/mbio.02273-18
10. Toh, E., Kurtz, H. D., & Brun, Y. V. (2008c). Characterization of the Caulobacter crescentus Holdfast Polysaccharide Biosynthesis Pathway Reveals Significant Redundancy in the Initiating Glycosyltransferase and Polymerase Steps. Journal of Bacteriology, 190(21), 7219–7231. https://doi.org/10.1128/jb.01003-08
11. Javens, J., Wan, Z., Hardy, G. G., & Brun, Y. V. (2013). Bypassing the need for subcellular localization of a polysaccharide export-anchor complex by overexpressing its protein subunits. Molecular Microbiology, 89(2), 350–371. https://doi.org/10.1111/mmi.12281
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