Difference between revisions of "Part:BBa K5246043"

(Conclusions and future prospects)
(Introduction)
 
(8 intermediate revisions by 3 users not shown)
Line 6: Line 6:
 
Vilnius-Lithuania iGEM 2024 project <HTML><b><a href="https://2024.igem.wiki/vilnius-lithuania" target="_blank">Synhesion</a></b></html> 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 - <I> C. crescentus </I> and <I> H. baltica </I> - harness 12 protein synthesis pathways to produce sugars, anchoring them to the surfaces. We aimed to transfer the polysaccharide synthesis pathway to industrially used <I>E. coli</I> bacteria to produce adhesives. Our team concomitantly focused on creating a novel <I>E. coli</I> strain for more efficient production of adhesives.  
 
Vilnius-Lithuania iGEM 2024 project <HTML><b><a href="https://2024.igem.wiki/vilnius-lithuania" target="_blank">Synhesion</a></b></html> 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 - <I> C. crescentus </I> and <I> H. baltica </I> - harness 12 protein synthesis pathways to produce sugars, anchoring them to the surfaces. We aimed to transfer the polysaccharide synthesis pathway to industrially used <I>E. coli</I> bacteria to produce adhesives. Our team concomitantly focused on creating a novel <I>E. coli</I> strain for more efficient production of adhesives.  
  
This is <b> the complete holdfast tetrad assembly system. Parts of this composite can be found:<html><a href="https://parts.igem.org/Part:BBa_K5246041" target="_blank">BBa_K5246044</a></html> and <html><a href="https://parts.igem.org/Part:BBa_K5246042" target="_blank">BBa_K5246045</a></html></b>.  
+
This is <b> the complete holdfast tetrad assembly system. Parts of this composite can be found:<html><a href="https://parts.igem.org/Part:BBa_K5246041" target="_blank">BBa_K5246041</a></html> and <html><a href="https://parts.igem.org/Part:BBa_K5246042" target="_blank">BBa_K5246042</a></html></b>.  
  
 
<HTML><P>This part was used in Vilnius-Lithuania iGEM 2024 project "Synhesion" <HTML><b><a href="https://2024.igem.wiki/vilnius-lithuania" target="_blank">https://2024.igem.wiki/vilnius-lithuania/.</a></b></P></html>
 
<HTML><P>This part was used in Vilnius-Lithuania iGEM 2024 project "Synhesion" <HTML><b><a href="https://2024.igem.wiki/vilnius-lithuania" target="_blank">https://2024.igem.wiki/vilnius-lithuania/.</a></b></P></html>
 +
 +
__TOC__
  
 
===Biology and Usage===
 
===Biology and Usage===
Line 18: Line 20:
 
The holdfast synthesis (<i>hfs</i>) genes include those encoding predicted glycosyltransferases, carbohydrate modification factors, and components of a wzy-type polysaccharide assembly pathway. [4][5][6]
 
The holdfast synthesis (<i>hfs</i>) 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. <I>C. crescentus</I> or <I>H. baltica </I>, and securing it to the surface [8].
+
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. <I>C. crescentus</I> or <I>H. baltica </I>, and securing it to the surface [8].
  
 
<html>
 
<html>
Line 1,089: Line 1,091:
  
 
======Polysaccharides can not be purified using chemical purification======
 
======Polysaccharides can not be purified using chemical purification======
After successful holdfast biosynthesis, we aimed to purify the polysaccharides for further research and analysis. We adapted the only available C. crescentus holdfast chemical purification method and verified the results using dot blot assays with Heat Germ Aglutinnin (WGA) [22].
+
After successful holdfast biosynthesis, we aimed to purify the polysaccharides for further research and analysis. We adapted the only available C. crescentus holdfast chemical purification method and verified the results using dot blot assays with Wheat Germ Agglutinin (WGA) [22].
During the purification process, it was noticed that holdfast-producing cells stick together and can not be homogenized via pipetting or vortexing. Unfortunately, despite multiple attempts, we could not obtain pure holdfast material (Fig. 25.1-3.). None of the 3 attempts yielded significant differences between the CB2 system sample and the empty (control) sample. As the other experiments have showed, the <i>E. coli</I> with the CB2 system produces polysaccharides with distinct chemical features of holdfast attached to the cells, purification protocols specific for exopolysaccharide purification from the cell envelope could be tried upon the ring-formed cells but, sadly, not the protocol we used [23][24][25].  
+
During the purification process, it was noticed that holdfast-producing cells stick together and can not be homogenized via pipetting or vortexing. Unfortunately, despite multiple attempts, we could not obtain pure holdfast material (Fig. 25.1-3.). None of the 3 attempts yielded significant differences between the CB2 system sample and the empty (control) sample. As the other experiments have shown, the <i>E. coli</I> with the CB2 system produces polysaccharides with distinct chemical features of holdfast attached to the cells, purification protocols specific for exopolysaccharide purification from the cell envelope could be tried upon the ring-formed cells but, sadly, not the protocol we used [23][24][25].  
  
 
<html>
 
<html>
Line 1,097: Line 1,099:
 
           <img src="https://static.igem.wiki/teams/5246/results/polysaccharides-can-not-be-purified-using-chemical-purification/1-purification-of-holdfast-dot-blot.webp" style="width:300px;">
 
           <img src="https://static.igem.wiki/teams/5246/results/polysaccharides-can-not-be-purified-using-chemical-purification/1-purification-of-holdfast-dot-blot.webp" style="width:300px;">
 
         </div>
 
         </div>
         <figcaption><center><b> Fig. 25.1.</b> Chemical holdfast purification sample analysis using dot blot assay with WGA. 1. Media supernatant in 60% (v/v) EtOH. 2. A1 - aqueous phase from wash 1. 3. A2.- aqueous phase frpm wash 2,. 4. P3 -phenol phase from wash 3. 5. P4 - organic phase after centrifugation  6. P5-supernatant before overnight incubation. 7. P5 - supernatant after overnight incubation. 8. M80 pellet from overnight incubation at -20°C</center></figcaption>
+
         <figcaption><center><b> Fig. 25.1.</b> Chemical holdfast purification sample analysis using dot blot assay with WGA. 1. Media supernatant in 60% (v/v) EtOH. 2. A1 - aqueous phase from wash 1. 3. A2 - aqueous phase from wash 2. 4. P3 - phenol phase from wash 3. 5. P4 - organic phase after centrifugation  6. P5 - supernatant before overnight incubation. 7. P5 - supernatant after overnight incubation. 8. M80 pellet from overnight incubation at -20°C</center></figcaption>
 
       </figure>
 
       </figure>
 
</html>
 
</html>
Line 1,106: Line 1,108:
 
           <img src="https://static.igem.wiki/teams/5246/results/polysaccharides-can-not-be-purified-using-chemical-purification/2-purification-of-holdfast-dot-blot.webp" style="width:300px;">
 
           <img src="https://static.igem.wiki/teams/5246/results/polysaccharides-can-not-be-purified-using-chemical-purification/2-purification-of-holdfast-dot-blot.webp" style="width:300px;">
 
         </div>
 
         </div>
         <figcaption><center><b> Fig. 25.2.</b> Chemical holdfast purification sample analysis using dot blot assay with WGA. 1. Media supernatant in 60% (v/v) EtOH. 2. A1 - aqueous phase from wash 1. 3. A2.- aqueous phase frpm wash 2,. 4. P3 -phenol phase from wash 3. 5. P4 - organic phase after centrifugation  6. P5-supernatant before overnight incubation. 7. P5 - supernatant after overnight incubation. 8. M80 pellet from overnight incubation at -20°C</center></figcaption>
+
         <figcaption><center><b> Fig. 25.2.</b> Chemical holdfast purification sample analysis using dot blot assay with WGA. 1. Media supernatant in 60% (v/v) EtOH. 2. A1 - aqueous phase from wash 1. 3. A2.- aqueous phase from wash 2. 4. P3 -phenol phase from wash 3. 5. P4 - organic phase after centrifugation  6. P5 - supernatant before overnight incubation. 7. P5 - supernatant after overnight incubation. 8. M80 pellet from overnight incubation at -20°C</center></figcaption>
 
       </figure>
 
       </figure>
 
</html>
 
</html>
Line 1,115: Line 1,117:
 
           <img src="https://static.igem.wiki/teams/5246/results/polysaccharides-can-not-be-purified-using-chemical-purification/3-purification-of-holdfast-dot-blot.webp" style="width:300px;">
 
           <img src="https://static.igem.wiki/teams/5246/results/polysaccharides-can-not-be-purified-using-chemical-purification/3-purification-of-holdfast-dot-blot.webp" style="width:300px;">
 
         </div>
 
         </div>
         <figcaption><center><b> Fig. 25.3.</b> Chemical holdfast purification sample analysis using dot blot assay with WGA. 1. Media supernatant in 60% (v/v) EtOH. 2. A1 - aqueous phase from wash 1. 3. A2.- aqueous phase frpm wash 2,. 4. P3 -phenol phase from wash 3. 5. P4 - organic phase after centrifugation  6. P5-supernatant before overnight incubation. 7. P5 - supernatant after overnight incubation. 8. M80 pellet from overnight incubation at -20°C</center></figcaption>
+
         <figcaption><center><b> Fig. 25.3.</b> Chemical holdfast purification sample analysis using dot blot assay with WGA. 1. Media supernatant in 60% (v/v) EtOH. 2. A1 - aqueous phase from wash 1. 3. A2 - aqueous phase from wash 2. 4. P3 - phenol phase from wash 3. 5. P4 - organic phase after centrifugation  6. P5 - supernatant before overnight incubation. 7. P5 - supernatant after overnight incubation. 8. M80 pellet from overnight incubation at -20°C</center></figcaption>
 
       </figure>
 
       </figure>
 
</html>
 
</html>
Line 1,148: Line 1,150:
 
   <div class="image-box">
 
   <div class="image-box">
 
     <img src="https://static.igem.wiki/teams/5246/results/e-coli-with-holdfast-synthesis-pathway-produce-biofilm-like-structures/sem-26.webp" style="width:200px;">
 
     <img src="https://static.igem.wiki/teams/5246/results/e-coli-with-holdfast-synthesis-pathway-produce-biofilm-like-structures/sem-26.webp" style="width:200px;">
     <p><b> Fig.26.1. </b> SEM pictures of negative control. Visible biofilm-like structures. Different locations of the same CB2 sample are shown. </p>
+
     <p><b> Fig.26.1. </b> SEM pictures of negative control.</p>
 
   </div>
 
   </div>
 
   <div class="image-box">
 
   <div class="image-box">
Line 1,686: Line 1,688:
 
<br>
 
<br>
 
30.Wiercigroch, E., Szafraniec, E., Czamara, K., Pacia, M. Z., Majzner, K., Kochan, K., Kaczor, A., Baranska, M., & Malek, K. (2017). Raman and infrared spectroscopy of carbohydrates: A review. Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, 185, 317–335. https://doi.org/10.1016/j.saa.2017.05.045
 
30.Wiercigroch, E., Szafraniec, E., Czamara, K., Pacia, M. Z., Majzner, K., Kochan, K., Kaczor, A., Baranska, M., & Malek, K. (2017). Raman and infrared spectroscopy of carbohydrates: A review. Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, 185, 317–335. https://doi.org/10.1016/j.saa.2017.05.045
<br>
 
31.Kalivoda, E. J., Stella, N. A., O’Dee, D. M., Nau, G. J., & Shanks, R. M. Q. (2008). The Cyclic AMP-Dependent Catabolite Repression System of Serratia marcescens Mediates Biofilm Formation through Regulation of Type 1 Fimbriae. Applied and Environmental Microbiology, 74(11), 3461–3470. https://doi.org/10.1128/aem.02733-07
 
<br>
 
32.Bak, G., Lee, J., Suk, S., Kim, D., Young Lee, J., Kim, K., Choi, B.-S., & Lee, Y. (2015). Identification of novel sRNAs involved in biofilm formation, motility and fimbriae formation in Escherichia coli. Scientific Reports, 5(1). https://doi.org/10.1038/srep15287
 
<br>
 
33.Wu, Y., & Outten, F. W. (2008). IscR Controls Iron-Dependent Biofilm Formation in Escherichia coli by Regulating Type I Fimbria Expression. Journal of Bacteriology, 191(4), 1248–1257. https://doi.org/10.1128/jb.01086-08
 
<br>
 
34.ZAMANI, H., & SALEHZADEH, A. (2018). Biofilm formation in uropathogenic Escherichia coli: association with adhesion factor genes. TURKISH JOURNAL of MEDICAL SCIENCES, 48, 162–167. https://doi.org/10.3906/sag-1707-3
 
<br>
 
35.Beloin, C., Roux, A., & Ghigo, J. M. (2008). Escherichia coli biofilms. Current Topics in Microbiology and Immunology, 322, 249–289. https://doi.org/10.1007/978-3-540-75418-3_12
 
<br>
 
36.Niba, E. T. E., Naka, Y., Nagase, M., Mori, H., & Kitakawa, M. (2008). A Genome-wide Approach to Identify the Genes Involved in Biofilm Formation in E. coli. DNA Research, 14(6), 237–246. https://doi.org/10.1093/dnares/dsm024
 
<br>
 
37.Westerlund-Wikström, B., & Korhonen, T. K. (2005). Molecular structure of adhesin domains in Escherichia coli fimbriae. International Journal of Medical Microbiology, 295(6-7), 479–486. https://doi.org/10.1016/j.ijmm.2005.06.010
 
<br>
 
38.Arban Domi, & Moss, B. (2002). Cloning the vaccinia virus genome as a bacterial artificial chromosome in Escherichia coli and recovery of infectious virus in mammalian cells. Proceedings of the National Academy of Sciences of the United States of America, 99(19), 12415–12420. https://doi.org/10.1073/pnas.192420599
 
<br>
 
39.Lalioti, M. D. (2001). A new method for generating point mutations in bacterial artificial chromosomes by homologous recombination in Escherichia coli. Nucleic Acids Research, 29(3), 14e14. https://doi.org/10.1093/nar/29.3.e14
 
<br>
 
40.Messerle, M., Crnkovic, I., Hammerschmidt, W., Ziegler, H., & Koszinowski, U. H. (1997). Cloning and mutagenesis of a herpesvirus genome as an infectious bacterial artificial chromosome. Proceedings of the National Academy of Sciences, 94(26), 14759–14763. https://doi.org/10.1073/pnas.94.26.14759
 
<br>
 
41.Roy, P., & Noad, R. (2012). Use of Bacterial Artificial Chromosomes in Baculovirus Research and Recombinant Protein Expression: Current Trends and Future Perspectives. ISRN Microbiology (Print), 2012, 1–11. https://doi.org/10.5402/2012/628797
 
<br>
 
42.Blaas, L., Musteanu, M., Eferl, R., Bauer, A., & Casanova, E. (2009). Bacterial artificial chromosomes improve recombinant protein production in mammalian cells. BMC Biotechnology, 9(1), 3. https://doi.org/10.1186/1472-6750-9-3
 
<br>
 
43.Egger, E., Tauer, C., Cserjan-Puschmann, M., Grabherr, R., & Striedner, G. (2020). Fast and antibiotic free genome integration into Escherichia coli chromosome. Scientific Reports, 10(1). https://doi.org/10.1038/s41598-020-73348-x
 
<br>
 
44.Nakamura, T., Koma, D., Oshima, M., Hoshino, H., Ohmoto, T., & Uegaki, K. (2018). Application of chromosomal gene insertion into Escherichia coli for expression of recombinant proteins. Journal of Bioscience and Bioengineering, 126(2), 266–272. https://doi.org/10.1016/j.jbiosc.2018.02.016
 
<br>
 
45.Chiang, C.-J., Chen, P.-T., & Chao, Y.-P. (2008). Replicon-free and markerless methods for genomic insertion of DNAs in phage attachment sites and controlled expression of chromosomal genes inEscherichia coli. Biotechnology and Bioengineering, 101(5), 985–995. https://doi.org/10.1002/bit.21976
 
<br>
 
46.Hershey, D. M., Porfírio, S., Black, I., Jaehrig, B., Heiss, C., Azadi, P., Fiebig, A., & Crosson, S. (2019). Composition of the Holdfast Polysaccharide from Caulobacter crescentus. Journal of Bacteriology, 201(17). https://doi.org/10.1128/JB.00276-19
 
<br>
 
47.Shi, L. (2016). Bioactivities, isolation and purification methods of polysaccharides from natural products: A review. International Journal of Biological Macromolecules, 92, 37–48. https://doi.org/10.1016/j.ijbiomac.2016.06.100
 
<br>
 
48.Chepkwony, N. K., Berne, C., & Brun, Y. V. (2019). Comparative Analysis of Ionic Strength Tolerance between Freshwater and Marine Caulobacterales Adhesins. Journal of Bacteriology, 201(18). https://doi.org/10.1128/jb.00061-19
 
 
<br>
 
<br>

Latest revision as of 06:27, 2 October 2024


Caulobacter crescentus CB2/CB2A HfsE-HfsJ-HfsG-HfsH-HfsK-HfsL Polysaccharide tetrad assembly

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 tetrad assembly system. Parts of this composite can be found:BBa_K5246041 and BBa_K5246042.

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].

Fig. 1. Holdfast synthesis pathway in C. crescentus consisting of 12 proteins.

Usage

Genes from this composite part are responsible for tetrasaccharide assembly in the holdfast biosynthesis pathway. HfsE (BBa_K5246005 ) transfers an activated glucose-phosphate from UDP to an undecaprenyl-phosphate (Und-P) lipid carrier, HfsJ (BBa_K5246010 ) adds N-mannosamine uronic acid. then HfsG (BBa_K5246007 ) and HfsL (BBa_K5246012 ) joins two N-acetyl-D-glucosamines (HfsG transfers to mannosaminuronic acid, HfsL to another N-acetyl-D-glucosamine) then last N-acetyl-D-glucosamine is deacetylated by HfsH and HfsK (BBa_K5246008 ) (BBa_K5246011 )

In the end, we have a glycolipid - a lipid carrier undecaprenyl phosphate (UndP) with an oligosaccharide (glucose--mannosaminuronic acid--N-acetyl-D-glucosamine--D-glucosamine) attached to it.

Then, the tetrasaccharide can be polymerized by polysaccharide polymerization and export apparatus (BBa_K5246046 ) to get a full polysaccharide if used together

-->This part works as a system for holdfast synthesis together with part BBa_K5246046.

Sequence and Features


Assembly Compatibility:
  • 10
    INCOMPATIBLE WITH RFC[10]
    Illegal EcoRI site found at 3690
    Illegal XbaI site found at 4450
    Illegal PstI site found at 4539
  • 12
    INCOMPATIBLE WITH RFC[12]
    Illegal EcoRI site found at 3690
    Illegal PstI site found at 4539
    Illegal NotI site found at 619
    Illegal NotI site found at 3444
  • 21
    INCOMPATIBLE WITH RFC[21]
    Illegal EcoRI site found at 3690
    Illegal BglII site found at 2280
    Illegal BglII site found at 4453
    Illegal BamHI site found at 2428
    Illegal XhoI site found at 2647
    Illegal XhoI site found at 5268
  • 23
    INCOMPATIBLE WITH RFC[23]
    Illegal EcoRI site found at 3690
    Illegal XbaI site found at 4450
    Illegal PstI site found at 4539
  • 25
    INCOMPATIBLE WITH RFC[25]
    Illegal EcoRI site found at 3690
    Illegal XbaI site found at 4450
    Illegal PstI site found at 4539
    Illegal NgoMIV site found at 758
    Illegal NgoMIV site found at 1389
    Illegal NgoMIV site found at 2001
    Illegal NgoMIV site found at 3099
    Illegal NgoMIV site found at 3748
    Illegal NgoMIV site found at 3772
    Illegal NgoMIV site found at 3776
    Illegal AgeI site found at 1088
  • 1000
    COMPATIBLE WITH RFC[1000]


Experimental characterization

Part cloning

All of the proteins composing this system are responsible for tetrad assembly. Since the system's proteins are found in the cytoplasm, we concluded that using a high-copy plasmid would ensure sufficient protein concentration for tetrasaccharide repeat synthesis and activation of the whole pathway. This would provide adequate substrate supply for polysaccharide polymerization and export.

To assemble specifically this part into BBa_K5246043 to then further assemble the holdfast synthesis pathway in E. coli , we had to assemble this part first into a backbone of pRSF-Duet-1. We designed a strategy to maximize the success of plasmid assembly by first assembling plasmids with 3 genes and, after verifying the sequences, integrating 3 left genes into that backbone (Fig. 1). In this way, we prevented Golden Gate assembly errors by trying to construct plasmids from 8 or more fragments.

Fig. 1. Plasmid construction strategy. Plasmids are constructed in two rounds, cloning 3 genes at a time. Verified by colony PCR, restriction digestion analysis, and Nanopore sequencing


The assembly was done using Golden Gate assembly with IIS AarI restriction enzyme sites introduced during PCR amplification. The backbone of pRSF-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. 2). Since hfsA gene had an AarI RE site directly in the gene, this site was domesticated during side directed mutagenesis.


Fig. 2. PCR amplification of target genes from the genome after purification of C. crescentus CB2

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 protocol. The reaction was later transformed into E. coli Mach1 (Thermo Scientific) competent cells. The assembly was then confirmed with colony PCR (Fig.3) and restriction digest analysis (Fig. 3) and positive colonies were sequenced.

Fig. 3. cPCR of C. crescentus CB2 hfsE-hfsJ-hfsG Golden Gate assembly into pRSF-Duet-1. Expected product length - ~1 kb. -C - negative control, 1-10 - different colonies, M - molecular weight ladder, GeneRuler DNA Ladder Mix (Thermo Scientific)..

Fig. 4. Restriction digest analysis of C. crescentus CB2 pRSF-hfsE-hfsJ-hfsG. On the left - expected in silico profile of restriction digest with NotI and XhoI, on the right - digested plasmids - 4,6,10 positive cPCR colonies, M - molecular weight ladder, GeneRuler DNA Ladder Mix (Thermo Scientific).


To assemble specifically this part into BBa_K5246043 to then further assemble the holdfast synthesis pathway in E. coli , we had to assemble this part first into a backbone of pRSF-Duet-1. We designed a strategy to maximize the success of plasmid assembly by first assembling plasmids with 3 genes and, after verifying the sequences, integrating 3 left genes into that backbone (Fig. 1). In this way, we prevented Golden Gate assembly errors by trying to construct plasmids from 8 or more fragments. In this particular case, we are inserting BBa K5246042 (CB2/CB2A hfsL-hfsH-hfsK) operon into a backbone with BBa_K5246041(CB2/CB2A hfsE-hfsJ-hfsG)


Due to the high amount of non-specific products, the fragments for the second round were also gel-purified. Vectors and fragments composing this operon, were mixed in equimolar amounts with GG reaction components and incubated as described in protocol. The reaction was later transformed into E. coli Mach1 (Thermo Scientific) competent cells. The assembly was then confirmed with colony PCR (Fig.5) and restriction digest analysis (Fig. 4) and positive colonies were sequenced.

Fig. 5. cPCR of C. crescentus CB2 hfsE-hfsJ-hfsG-hfsH-hfsK-hfsL Golden Gate assembly into pRSF-Duet-1. Expected product length - ~1.3 kb. 1-6 - different colonies, M - molecular weight ladder, GeneRuler DNA Ladder Mix (Thermo Scientific)..

Fig. 6. Restriction digest analysis of C. crescentus CB2 pRSF-hfsE-hfsJ-hfsG-hfsH-hfsK-hfsL. On the left - expected in silico profile of restriction digest with EcoRI, NotI and XhoI, on the right - digested plasmids - 1-6 positive cPCR colonies, M - molecular weight ladder, GeneRuler DNA Ladder Mix (Thermo Scientific).

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 Sizes Table

C. crescentus CB2 system protein sizes in kDa
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

side by side

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 Sizes Table

C. crescentus CB2 system protein sizes in kDa
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

Images with Captions

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).

Images with Captions

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).

Fig. 8.5. SDS-PAGE analysis of CB2 system expression in KRX(DE3) at different IPTG concentrations overnight 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 Sizes Table

C. crescentus CB2 system protein sizes in kDa
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

side by side

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 Sizes Table

C. crescentus CB2 system protein sizes in kDa
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

side by side

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).

Fig. 10.3. SDS-PAGE analysis of CB2 system expression in BL21(DE3) at different IPTG concentrations overnight at 16°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)).

Fig. 11. Graphs depicting proteomic analysis of combined protein abundance (in absorbance units) in (a) CB2 export apparatus, (b) CB2 tetrad assembly, and (c) CB2 full systems. Expression was done in BL21(DE3) with 0.5 mM IPTG induction followed by expression for 3h at 37°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 Sizes Table

C. crescentus CB2 system protein sizes in kDa
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

side by side

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).

Fig. 12.3. SDS-PAGE analysis of CB2 system expression in C41(DE3) at different IPTG concentrations for 3h at 37°C. M - molecular weight ladder in kDa, Pageruler Unstained Protein Ladder, 26614 (Thermo Scientific).

Rosetta(DE3) pLysS

Even though to this point we found E. coli strain with, in our perspective, sufficient system expression, we were determined to improve the expression even more. A study was conducted, where C. crescentus hfsJ gene was expressed in E. coli to determine its interaction with hfiA (inhibitor of holdfast development), we investigated the strain they used for expression - Rosetta (DE3) pLysS - for our own purpose [4]. Since we decided to use this strain, we had to carefully reconsidering our CB2 systems’ design, as the pRARE plasmid, native to Rosetta, contains the same antibiotic resistance - chloramphenicol - and the same origin of replication - p15A - as one of our system’s plasmids - pACYC-(3)hfsA-hfsB-hfsD-(4)hfsF-hfsC-hfsI (BBa_K5246046). For this we decided to change the backbone’s antibiotic resistance and origin of replication (ori) (Fig.13).

Fig. 13. Design reconsideration in order to use Rosetta(DE3) pLysS in Holdfast protein expression.

As a donor of new antibiotic resistance and origin of replication we choose pBAD-PhoCl2f plasmid, which was kindly gifted to us by VU LSC Institute of Biotechnology. This particular plasmid contains the ampicillin resistance gene and ColE1 origin of replication compatible with our pRSF operon and pRARE plasmid.

To save time we decided to utilize Golden Gate assembly for resistance/ori switching. We successfully acquired plasmids with new resistance/ori, which, after testing them with colony PCR, restriction analysis (Fig. 14), were sequenced by whole plasmid sequencing by SeqVision. Since after transformation into electrocompetent Rosetta cells they grew without any problems on LB agar plates with 3 different antibiotics, we came to a conclusion that the resistance/ori switch worked.

Fig. 14. Restriction digest analysis of pACYC-(3)hfsA-hfsB-hfsD-(4)hfsF-hfsC-hfsI with switched replication of origin and ampicillin antibiotic resistance gene. On the left - expected in silico profile of restriction digest, on the right - digested plasmids - 1-5 colonies, M - molecular weight ladder, GeneRuler DNA Ladder Mix (Thermo Scientific).

To test the expression we used different IPTG concentrations - 0.25, 0.5 and 0.75 mM - and our standard expression temperature of 37°C with checking the total expressed protein amount after 3 hours by SDS-PAGE analysis. Unfortunately, we saw very low or almost no protein expression in separate plasmids, leading to the same happening when we tried expressing the whole system (Fig. 15. 1-3). We reason that this might be due to increased metabolic strain on E. coli due to a whole additional plasmid introduced into the system during expression. This E. coli strain might be suitable for specific C. crescentus protein expression but, sadly, is not fitting for our needs.

Protein Sizes Table

C. crescentus CB2 system protein sizes in kDa
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

side by side

Fig. 15.1. SDS-PAGE analysis of pRSF-(1)HfsE-hsfJ-hfsG-(2)hfsH-hfsK-hfsL expression in Rosetta(DE3) pLysS at different IPTG concentrations at 37°C for 3h. M - molecular weight ladder in kDa, Pageruler Unstained Protein Ladder, 26614 (Thermo Scientific).

Fig. 15.2. SDS-PAGE analysis of pACYC-(3)hfsA-hfsB-hfsD-(4)hfsF-hfsC-hfsI expression in Rosetta(DE3) pLysS at different IPTG concentrations at 37°C for 3h. M - molecular weight ladder in kDa, Pageruler Unstained Protein Ladder, 26610 (Thermo Scientific).

Fig. 15.3. SDS-PAGE analysis of CB2 system expression in Rosetta (DE3) pLysS at different IPTG concentrations for 3h at 37°C. M - molecular weight ladder in kDa, Pageruler Unstained Protein Ladder, 26614 (Thermo Scientific).

HMS174(DE3)

Since one of the strains used for more efficient polysaccharide production (see down below) was E. coli HMS174(DE3), we also expressed CB2 and an empty system in previously optimized conditions. We also analyzed protein production after overnight incubation with 1% glucose. After performing SDS-PAGE gel analysis, we saw that this strain also expresses some of the proteins of the CB2 system (Fig. 16). Remarkably, after overnight incubation with 1% glucose, more protein bands appear, corresponding to, e.g., hfsH or hfsD, proteins, indicating that it is likely that prolonged incubation does not negatively impact protein production. This might explain why some of the strains, previously expressing few proteins after 3 hours, were still forming rings after overnight incubation, as this strain also formed rings (see explanation in holdfast synthesis part down below).

Protein Sizes Table

C. crescentus CB2 system protein sizes in kDa
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. 16 SDS-PAGE analysis of the empty and CB2 system expression in HMS174(DE3) at 0.5 mM IPTG concentration with protein expression after 3h at 37°C and overnight at 30°C. M - molecular weight ladder in kDa, Pageruler Unstained Protein Ladder, 26614 (Thermo Scientific).

Holdfast biosynthesis

Following the optimization of protein expression, we examined the conditions required for successful holdfast polysaccharide production. Previous experiments demonstrated that the presence of the proteins does not guarantee holdfast synthesis, prompting further investigation into the underlying factors.


Results overview: The addition of 1% glucose and incubation overnight at 30°C are required for polysaccharide synthesis. E. coli cultures produce ring-like structures after incubation. Holdfast is primarily produced in the ring cells, detectable by Wheat Germ agglutinin lectin, and contains considerable amounts of N-acetyl-D-glucosamine. Cells producing the holdfast are morphologically different, forming biofilm-like structures. The best substrate for polysaccharide production is glucose, with mannose as a second choice, altough more expensive.

Holdfast synthesis requires glucose

Multiple experiments revealed that having the proteins alone is insufficient for holdfast synthesis. We attempted to purify the holdfast from the media (see Experiments for detailed purification protocol), but the results were not as expected (Fig. 18). No holdfast was produced under the given conditions, despite the presence of all the proteins. No differences were observed between the control and target samples in the dot blot assay of the purification samples.

Fig. 18. Dot blot assay for holdfast purification sample using Alexa Fluor 680 Wheat Germ Agglutinin (Thermo Scientific) primary lectins. Holdfast was purified from the media. 1. Media supernatant in EtOH 60% v/v. 2. A1 aqueous phase. 3. A2 - aqueous phase. 3. P3 - organic phase. 4. P4 supernatant. 5. P5 supernatant. 7. P5 in EtOH after incubation at -20°C 8. M80 pellet.


So we considered adding precursors for the biosynthesis pathway to facilitate its’ activation. We hypothesized that we should be able to adapt methods, suitable for polymer production in E. coli [15][16]. Holdfast synthesis begins from UDP-D-glucose transfer to an UndP lipid carrier, so having an excess of available glucose could solve the problem. We designed a protocol based on previous studies [17][18][19]. Adding 1% (w/v) glucose after target protein expression, as the addition of glucose lowers expression levels by targeting lac operator, and incubating overnight at 30°C with a shaking speed lowered to 170 rpm resulted in distinct rings forming around the edges of the shaking media (Fig.19) [20].

Fig. 19. Appearance of rings in expression flask after the addition of 1% glucose and incubation O/N at 30C. (a) control flasks, BL21(DE3) does not contain any target genes. No rings present. (b) flasks containing CB2 system proteins, visible rings forming.

In addition, for further experiments, e.g. holdfast purification, we expressed and synthesized ring-like formations, later deemed to be the holdfast, in larger flasks. This increase in size - from 500 mL to 1 L flask did not diminish the ability to form the rings (Fig. 20). Not only that but after multiple day incubation and consistently lowering the shaking speed, we were able to get multiple rings to form around the 1 L flask walls. This information was later used to produce rings for other experimental applications where larger amounts of starting material were required.

Fig. 20. Photos of 1 L flasks depicting multiple formed rings around the flask walls. (a) - flask containing 2 rings, (b) - flask containing 4 rings after multiple day incubation, (c) - flask containing 5th ring formed after overnight incubation of (b).

Polysaccharides are produced only in the part of the population

Wheat Germ Agglutinin (WGA) specifically binds to N-acetyl-D-glucosamine - a characteristic component of the holdfast, found in abundance in the polysaccharide [21]. This allowed us to determine the localization of the holdfast. We tested various samples, including cells from the media, the supernatant, material from the ring, sonicated cells, and the supernatant of the sonicated cells. After performing the dot blot assay (see see Experiments for detailed protocol), we saw that the holdfast is produced (indicated by considerable presence of N-acetyl-D-glucosamine) but is localized exclusively within the ring material (Fig. 21).

Fig. 21. Dot blot assay for holdfast localization with Alexa Fluor 680 Wheat Germ Agglutinin (ThermoFisher Scientific) primary lectins. All samples contain equal amounts of cells and were taken after incubation overnight at 30°C with 1% glucose. 1. Cells from the media. 2. Supernatant from the media 3. Sample from the ring (in TES buffer) 4. Sonicated cells (in PBS) 5. Sonicated cells’ supernatant (in PBS).

We made the conclusion that holdfast was located in the ring, but we still did not know the nature of the material, so we investigated if there were any living bacteria in it. Following the expression, after the rings formed, we resuspended the samples in LB media and streaked them on LB agar plates under four different conditions: (1) with appropriate antibiotics, (2) antibiotics + 0.5mM IPTG, (3) antibiotics + 1% glucose, and (4) antibiotics + 0.5mM IPTG + 1% glucose. The plates were then incubated overnight at 30°C. Variety of plates was supposed to show if there are any visible morphological differences between living bacterial cells from the ring, bacterial cells that express proteins of interest, and bacterial cells that not only express proteins but also, in theory, produce holdfast. It seems like ring formation consists of living bacteria that can grow on agar plates. Although they do not have any morphological differences (Fig. 22), they do appear to be more of a liquid-like appearance.


Fig. 22. Streaked bacteria from the rings after O/N incubation at 30°C. (a) Appropriate antibiotics + 0.5mM IPTG + 1% glucose (b) Appropriate antibiotics + 1% glucose (c) Appropriate antibiotics + 0.5mM IPTG (d) appropriate antibiotics.

Following the discovery, we hypothesized that only part of the bacterial population is able to effectively express all 12 proteins, so we used plated bacteria from rings for standard protein expression and ran a SDS-PAGE analysis (Fig. 23). It is clearly noticeable that bacteria from the ring expresses proteins much better than the fresh ones.

C. crescentus CB2 system protein sizes in kDa
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. 23. SDS-PAGE analysis of CB2 system expression in BL21(DE3) at 0.5 mM IPTG concentrations for 3h at 37°C. Comparison between fresh bacteria and bacteria taken from the ring. M - molecular weight ladder in kDa, Pageruler Unstained Protein Ladder, 26614 (Thermo Scientific).

Surprisingly, after incubating overnight, we did not notice any significant difference in the quantity of holdfast produced, based on ring appearance.

After understanding that the ring contains our target polysaccharides with bacteria, we further investigated the exact location of the holdfast. We expanded the dot blot assay method, including more samples from the ring: lysed ring cells, lysed ring cells’ supernatant, and lysed ring cells’ sediment. This lets us pinpoint the location of the polysaccharides and confirm where the holdfast is produced. Dot blot assays showed that holdfast is produced only in the ring cells mostly located in the soluble fraction of the lysate. These results were replicable for multiple biological repetitions (Fig.24.1-3).

Fig. 24.1. Dot blot assay of CB2 system expression, incubation with 1% glucose at 30°C O/N, and negative control of empty system expression. All samples contained equal amounts of cell material 1. Cells with the media 2. Supernatant from the media 3. Cell sediment resuspended in PBS. 4. PBS resuspended cells - lysed. 5. Cell lysate supernatant 6. Lysate sediment resuspended in PBS 7. Ring material resuspended in TES 8. TES resuspended ring - lysed 9. Ring lysate supernatant resuspended in TES 10. Ring lysate sediment resuspended in TES.

Fig. 24.2. Dot blot assay of CB2 system expression, incubation with 1% glucose at 30°C O/N, and negative control of empty system expression. All samples contained equal amounts of cell material 1. Cells with the media 2. Supernatant from the media 3. Cell sediment resuspended in PBS. 4. PBS resuspended cells - lysed. 5. Cell lysate supernatant 6. Lysate sediment resuspended in PBS 7. Ring material resuspended in TES 8. TES resuspended ring - lysed 9. Ring lysate supernatant resuspended in TES 10. Ring lysate sediment resuspended in TES.

Fig. 24.3. Dot blot assay of CB2 system expression, incubation with 1% glucose at 30°C O/N, and negative control of empty system expression. All samples contained equal amounts of cell material 1. Cells with the media 2. Supernatant from the media 3. Cell sediment resuspended in PBS. 4. PBS resuspended cells - lysed. 5. Cell lysate supernatant 6. Lysate sediment resuspended in PBS 7. Ring material resuspended in TES 8. TES resuspended ring - lysed 9. Ring lysate supernatant resuspended in TES 10. Ring lysate sediment resuspended in TES.

The addition of glucose is required to activate the holdfast synthesis pathway. Even after the activation, only part of the bacterial population is capable of synthesizing polysaccharides, forming ring-like structures on surfaces. After the synthesis, most of the holdfast is attached to the cells.

Polysaccharides can not be purified using chemical purification

After successful holdfast biosynthesis, we aimed to purify the polysaccharides for further research and analysis. We adapted the only available C. crescentus holdfast chemical purification method and verified the results using dot blot assays with Wheat Germ Agglutinin (WGA) [22]. During the purification process, it was noticed that holdfast-producing cells stick together and can not be homogenized via pipetting or vortexing. Unfortunately, despite multiple attempts, we could not obtain pure holdfast material (Fig. 25.1-3.). None of the 3 attempts yielded significant differences between the CB2 system sample and the empty (control) sample. As the other experiments have shown, the E. coli with the CB2 system produces polysaccharides with distinct chemical features of holdfast attached to the cells, purification protocols specific for exopolysaccharide purification from the cell envelope could be tried upon the ring-formed cells but, sadly, not the protocol we used [23][24][25].

Fig. 25.1. Chemical holdfast purification sample analysis using dot blot assay with WGA. 1. Media supernatant in 60% (v/v) EtOH. 2. A1 - aqueous phase from wash 1. 3. A2 - aqueous phase from wash 2. 4. P3 - phenol phase from wash 3. 5. P4 - organic phase after centrifugation 6. P5 - supernatant before overnight incubation. 7. P5 - supernatant after overnight incubation. 8. M80 pellet from overnight incubation at -20°C

Fig. 25.2. Chemical holdfast purification sample analysis using dot blot assay with WGA. 1. Media supernatant in 60% (v/v) EtOH. 2. A1 - aqueous phase from wash 1. 3. A2.- aqueous phase from wash 2. 4. P3 -phenol phase from wash 3. 5. P4 - organic phase after centrifugation 6. P5 - supernatant before overnight incubation. 7. P5 - supernatant after overnight incubation. 8. M80 pellet from overnight incubation at -20°C

Fig. 25.3. Chemical holdfast purification sample analysis using dot blot assay with WGA. 1. Media supernatant in 60% (v/v) EtOH. 2. A1 - aqueous phase from wash 1. 3. A2 - aqueous phase from wash 2. 4. P3 - phenol phase from wash 3. 5. P4 - organic phase after centrifugation 6. P5 - supernatant before overnight incubation. 7. P5 - supernatant after overnight incubation. 8. M80 pellet from overnight incubation at -20°C

E. coli with holdfast synthesis pathway produce biofilm-like structures

Understanding that holdfast stays attached to the producing cells led us to the hypothesis that they ought to have some noticeable morphological differences. SEM analysis revealed that the polysaccharide-producing bacteria form tight conglomerates and differ morphologically compared to the control group. SEM pictures clearly show that holdfast-producing bacteria have altered cell wall morphology appearing bigger, and more “puffy” with uneven envelope topology. Moreover, the CB2 system containing bacteria seems to form large aggregates, sticking together into difficult-to-disrupt lumps. This characteristic was noticed beforehand in holdfast purification experiments, but only in SEM, it became clear that the underlying cause of the phenomenon is biofilm-like structures (Fig. 26. 1-4., Fig. 27. 1-3.) [18][19].

side by side 3

Fig.26.1. SEM pictures of negative control.

Fig. 26.2. SEM pictures of holdfast-producing bacteria samples. Visible biofilm-like structures. Different locations of the same CB2 sample are shown.

Fig. 26.3. SEM pictures of holdfast-producing bacteria samples. Visible biofilm-like structures. Different locations of the same CB2 sample are shown.

Fig.26.4. SEM pictures of holdfast-producing bacteria samples. Visible biofilm-like structures. Different locations of the same CB2 sample are shown.

side by side 3

Fig.27.1. Close-up of Fig.26.4. showing the “crack” in the ring material revealing tightly associated bacteria forming biofilm-like structures. Picture analyzed using Fiji software.

Fig. 27.2. Close-up of Fig.26.4 showing the “crack” in the ring material revealing tightly associated bacteria forming biofilm-like structures. Picture analyzed using Fiji software.

Fig. 27.3. Close-up of Fig.26.4. showing the “crack” in the ring material revealing tightly associated bacteria forming biofilm-like structures. Picture analyzed using Fiji software.

Similar results were seen in flow cell bright-field microscopy, where it is noticeable that the CB2 sample has a considerable amount of big bacterial aggregates (Fig.28). Biofilm-like clumps noticeable in the video can not be homogenized by pipetting or vortexing, suggesting strong associations between cells. This could explain why CB2 sample bacteria were not evenly coating the glass slide, as the aggregates prevented enough bacteria from covering the bottom of the flow cell.

Fig. 28. Flow cell bright-field experiments. Noticeable aggregates of biofilm-like masses of cells can be observed floating away in CB2 sample compared to control.

SEM and bright field microscopy analysis revealed that the ring material of E. coli cells producing the holdfast are morphologically different and produce biofilm-like structures.

Different E. coli strains form holdfast polysaccharide

We decided to test E. coli strain testing, we used C41(DE3), Rosetta(DE3) pLysS, and HMS174(DE3), and repeated the expression conditions with different IPTG concentrations (0.25, 0.5, and 0.75 mM) with protein expression for 3h at 37°C. After the expression, we added 1% glucose and left the flasks to incubate overnight at 30°C, 170 rpm. All of the flasks, after incubation, had prominent rings in CB2 system flasks compared to the control (Fig. 29.1-3.). However, the formed rings were not as prominent as the ones formed in BL21(DE3).

side by side 3

Fig.29.1. Photos showing formed rings after overnight incubation with 1% glucose in E. coli C41(DE3) strain with different IPTG concentrations.

Fig. 29.2. Photos showing formed rings after overnight incubation with 1% glucose in E. coli Rosetta(DE3) pLysS strain with different IPTG concentrations.

Fig. 29.3. Photos showing formed rings after overnight incubation with 1% glucose in E. coli HMS174(DE3) strain with 0.5 mM IPTG concentration. Note: this strain was only incubated with one IPTG concentration as our chosen optimized conditions.

This indicated that even though these strains were not producing visible amounts of CB2 system proteins, the low amount of the expressed system was still sufficient enough to promote ring formation. As we ran out of time, we did not perform dot blot assays of the formed rings, but it is likely that they would also contain holdfast with N-acetyl-D-glucosamine as they appear during the same conditions used for BL21(DE3) rings production.

Suitable substrate search for holdfast production

We chose sugars that could be relevant to the polysaccharide composition: glucose, mannose, fructose, saccharose, N-acetyl-D-mannosamine, D-glucuronic acid, D-glucosamine, and xylose. After performing holdfast synthesis with standard conditions (in BL21(DE3)) optimized in earlier iterations, we observed the formation of rings with some substrates (Fig. 30.1-8). Notably, D-glucosamine substrate - a direct component of holdfast polysaccharide does not produce prominent rings, which indicates that it is incorporated into the holdfast as a N-acetyl-D-glucosamine that, after deacetylation with hfsH, only then becomes D-glucosamine (Fig. 30.7.) [28].

side by side 3

Fig. 30.1. A photo of culture flasks containing D-glucose substrate (number 1) with formed rings after overnight incubation at 30°C. CB2 system - bacteria containing holdfast synthesis pathway, empty system - bacteria without holdfast production system.

Fig. 30.2. A photo of culture flasks containing D-mannose substrate (number 2) with formed rings after overnight incubation at 30°C. CB2 system - bacteria containing holdfast synthesis pathway, empty system - bacteria without holdfast production system.

side by side 3

Fig. 30.3. A photo of culture flasks containing D-fructose substrate (number 3) with formed rings after overnight incubation at 30°C. CB2 system - bacteria containing holdfast synthesis pathway, empty system - bacteria without holdfast production system.

Fig. 30.4. A photo of culture flasks containing D-saccharose substrate (number 4) with formed rings after overnight incubation at 30°C. CB2 system - bacteria containing holdfast synthesis pathway, empty system - bacteria without holdfast production system.


side by side 3

Fig. 30.5. A photo of culture flasks containing N-acetyl-D-mannosamine substrate (number 5) with formed rings after overnight incubation at 30°C. CB2 system - bacteria containing holdfast synthesis pathway, empty system - bacteria without holdfast production system.

Fig. 30.6. A photo of culture flasks containing N-glucoronic acid substrate (number 6) with formed rings after overnight incubation at 30°C. CB2 system - bacteria containing holdfast synthesis pathway, empty system - bacteria without holdfast production system.


side by side 3

Fig. 30.7. A photo of culture flasks containing D-glucosamine substrate (number 7) with formed rings after overnight incubation at 30°C. CB2 system - bacteria containing holdfast synthesis pathway, empty system - bacteria without holdfast production system.

Fig. 30.8. . A photo of culture flasks containing N-xylsoe substrate (number 8) with formed rings after overnight incubation at 30°C. CB2 system - bacteria containing holdfast synthesis pathway, empty system - bacteria without holdfast production system.

Then, we examined the amount of holdfast produced with each monosaccharide substrate by dot blot assay (Fig. 31). As with visual representation of glucose formed rings (Fig. 30.1.), it appears that glucose is still the best choice as a substrate for holdfast production, with mannose coming second and D-glucosamine - third.

Fig. 31. Dot blot assay of ring cells from flasks with different sugar substrates. A - intact ring cells, B - lysed ring cells resuspended in TES C - cell lysate supernatant, D - cell lysate pellet in TES. 1 - D-glucose, 2 - D-mannose, 3 - D-fructose, 4 -D-saccharose, 5- N-Acetyl-D-mannosamine, 6 - D-glucuronic acid, 7 - D-glucosamine, 8- D-xylose.

Additionally, crystal violet staining (see Experiments) experiments yielded similar results (repeated in 3 biological replicates), with glucose and mannose samples producing the largest amount of “biofilm”. This data was used in the model construction to estimate optimal substrate and its concentration (see Model).

Increasing holdfast production efficiency

We aimed to reduce the metabolic burden on the cell membrane for polysaccharide production. We decided to deactivate one of the metabolic pathways in E. coli that produces polysaccharides, allowing substrates to be redirected towards our desired polysaccharide synthesis.

Goal: Inactivate the Enterobacterial Common Antigen (ECA) pathway in E. coli, which produces polysaccharides, and evaluate its impact on polysaccharide production.

Results overview: One of the essential genes, wecA was knocked out from E.coli, and the ECA pathway was eliminated from these expression strains: BL21(DE3), Rosetta(DE3), and HMS174(DE3). The HMS174(DE3)ΔWecA strain, expressing the CB2 polysaccharide production system, exhibited slower growth than the wild-type strain, but it still produced a sufficient quantity of polysaccharides.

Holdfast Protein Expression and Production of Polysaccharides in HMS174(DE3)ΔwecA

CB2 holdfast system proteins are expressed, and polysaccharides were produced in HMS174(DE3)ΔWecA. We discovered that wecA gene deletion did not interfere with CB2 system protein production. Additionally, we compared it to the not edited HMS174(DE3) strain (Fig 32.).

C. crescentus CB2 system protein sizes in kDa
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. 32. SDS-PAGE analysis of CB2 system expression in HMS174(DE3) and HMS174(DE3)ΔwecA at 0.5mM IPTG for 3h at 37°C and overnight at 30°C. M - molecular weight ladder in kDa, Pageruler Unstained Protein Ladder, 26614 (Thermo Scientific).

We analyzed polysaccharide and ring production after overnight incubation with 1% glucose in an ECA-deficient HMS174(DE3)ΔWecA strain (Fig. 33). Although cells with the CB2 system grew slower than an empty control, they still produced rings with the polysaccharides, with thicker bands of the ring visible in figure 33.

Fig. 33. Appearance of rings in expression flask after the addition of 1% glucose and incubation O/N at 30ºC in HMS174(DE3)ΔwecA. The empty system flask contains no target genes, and no rings are present. A flask containing CB2 system proteins contains visible rings.

Investigating the composition of the holdfast polysaccharide

We aimed to learn about the composition of holdfast polysaccharides by retracting one of the substrates synthesized by E.coli. We wanted to inactivate WecB - the enzyme that catalyzes the initial reaction in the production of the substrate UDP-N-acetyl mannosaminuronic acid (UDP-ManNAc), which is thought to be in the composition of our polysaccharide.


Results overview: The wecB gene was knocked out from E. coli expression strains BL21(DE3), Rosetta(DE3), and HMS174(DE3).

UDP-N-acetyl mannosaminuronic acid (UDP-ManNAc) is a sugar used to make polysaccharides in the CB2 system

CB2 holdfast system proteins are expressed but polysaccharides are not produced in HMS174(DE3)ΔwecB. We discovered that wecB gene deletion did not interfere with CB2 system protein production (Fig. 34).

C. crescentus CB2 system protein sizes in kDa
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. 34. SDS-PAGE analysis of CB2 system expression in HMS174(DE3)ΔwecB at 0.5mM IPTG for 3h at 37°C and overnight at 30°C. M - molecular weight ladder in kDa, Pageruler Unstained Protein Ladder, 26614 (Thermo Scientific).

We analyzed polysaccharide and ring production after overnight incubation with 1% glucose in the HMS174(DE3)ΔwecB strain. Cells with the CB2 system grew faster than unedited HMS174(DE3) and did not produce rings with polysaccharides. The flask with the E. coli containing the CB2 system looked the same as the E. coli without (Fig 35).

Fig. 35. Appearance of rings in expression flask after the addition of 1% glucose and incubation O/N at 30ºC in HMS174(DE3)ΔwecB. The empty system flask contains no target genes, CB2 system flask contains the required proteins for polysaccharide production, but in both, no thick rings are present.


Additionally, we compared HMS174(DE3)ΔWecA with HMS174(DE3)ΔwecB containing CB2 system to see the difference of polysaccharide and ring production (Fig. 36).

Fig. 36. Difference in ring formation between knocked out HMS174(DE3)ΔwecA and HMS174(DE3)ΔwecB, both containing CB2 system proteins after the addition of 1% glucose and incubation O/N at 30ºC. HMS174(DE3)ΔwecA flask features visible rings, and HMS174(DE3)ΔwecB flask does not.

FTIR analysis of the holdfast material

These experiments were done by our colleagues at the Vilnius University Center of Physical Sciences And Technology. Dr. Martynas Talaikis and Dr. Ilja Ignatjev. FTIR analysis reveals chemical properties of our holdfast. A shows the ATR-FTIR spectra of intact cell samples between the control and CB2 system samples (Fig.37.1.A). Since they are very similar, a difference spectrum was constructed by subtracting the control spectrum from the sample spectrum (Fig. 37.1.B) to highlight the differences. In the difference spectrum, the vibrational modes directed upwards belong to the CB2 sample. Vibrational modes of the amide functional group appear at 1618 cm-1 (Amide-I, C=O stretching), 1517 cm-1 (Amide-II, N-H in-plane bending), and 1235 cm-1 (Amide-III, N-H in-plane bending coupled with C-N stretching, and C-C stretching) were related to the amide fragment of N-Acetyl glucosamine. Another important vibration mode observed at 1169 cm-1 belongs to the C-O stretching vibration mode in glycosidic linkage, COH stretching, and C-H in-plane bending. Also, glycosidic linkage was observed at 978 cm-1 (symmetric C-O stretching), 931 cm-1 (C‑O stretching), and 833 cm-1 (C-C stretching of α-glycosidic linkage). All assignments were done according to literature [29][30]. All vibrational modes individually and collectively indicate the presence of polysaccharides. Figure 37.2 represent the control and sample spectra of cell debris with their difference spectra. The spectral assignment is similar to that presented in Figure 37.1. In both cases, the positive intensities in the difference spectra are related to sample-contained N-Acetyl glucosamine fragment and polysaccharides.

Fig. 37.1. FTIR analysis of cells producing polysaccharides. Spectra shows peaks indicating the presence of C-N linkages indicating N-acetyl-D-glucosamine and C-O linkages indicating glycosidic bond and presence of polysaccharides.

Fig. 37.2. FTIR analysis of insoluble cell lysate fraction from cells producing polysaccharides. Spectra shows peaks indicating the presence of C-N linkages indicating N-acetyl-D-glucosamine and C-O linkages indicating glycosidic bond and presence of polysaccharides.

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
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
15. Bodenmiller, D., Toh, E., & Brun, Y. V. (2004). Development of Surface Adhesion in Caulobacter crescentus. Journal of Bacteriology, 186(5), 1438–1447. https://doi.org/10.1128/jb.186.5.1438-1447.2004
16. Li, G., Smith, C. S., Brun, Y. V., & Tang, J. X. (2005). The Elastic Properties of the Caulobacter crescentus Adhesive Holdfast Are Dependent on Oligomers of N-Acetylglucosamine. Journal of Bacteriology, 187(1), 257–265. https://doi.org/10.1128/jb.187.1.257-265.2005
17. Wijemanne, P., & Moxley, R. A. (2014). Glucose Significantly Enhances Enterotoxigenic Escherichia coli Adherence to Intestinal Epithelial Cells through Its Effects on Heat-Labile Enterotoxin Production. PLoS ONE, 9(11), e113230. https://doi.org/10.1371/journal.pone.0113230
18.Mansey, M. S., Ghareeb, K. A., Moghazy, A. N., Tawfick, M. M., Fouda, M. M., El Marzugi, N. A., Othman, N. Z., & El Enshasy, H. A. (2014). Glucose concentration affects recombinant interferon \a-2b production in Escherichia coli using thermo-induction system. Journal of Applied Pharmaceutical Science, 4. https://doi.org/10.7324/japs.2014.40501
19.Xu, Y. Q., Liu, C. Y., Cai, F. J., & Hu, J. Y. (2013). The Influence of Different Concentration of Glucose on the Growth of Recombinant E.coli and Plasmid Stability. Advanced Materials Research, 647, 185–189. https://doi.org/10.4028/www.scientific.net/AMR.647.185
20. Pan, S.-h., & Malcolm, B. A. (2000). Reduced Background Expression and Improved Plasmid Stability with pET Vectors in BL21 (DE3). BioTechniques, 29(6), 1234–1238. https://doi.org/10.2144/00296st03
21. Merker, R. I., & Smit, J. (1988). Characterization of the Adhesive Holdfast of Marine and Freshwater Caulobacters. Applied and Environmental Microbiology, 54(8), 2078–2085. https://doi.org/10.1128/aem.54.8.2078-2085.1988
22.Hershey, D. M., Porfírio, S., Black, I., Jaehrig, B., Heiss, C., Azadi, P., Fiebig, A., & Crosson, S. (2019). Composition of the Holdfast Polysaccharide from Caulobacter crescentus. Journal of Bacteriology, 201(17). https://doi.org/10.1128/JB.00276-19
23.Srivastava, N., Kumari, S., Kurmi, S., Pinnaka, A. K., & Choudhury, A. R. (2022). Isolation, purification, and characterization of a novel exopolysaccharide isolated from marine bacteria Brevibacillus borstelensis M42. Archives of Microbiology, 204(7). https://doi.org/10.1007/s00203-022-02993-9
24.Trabelsi, I., Slima, S. B., Chaabane, H., & Riadh, B. S. (2015). Purification and characterization of a novel exopolysaccharides produced by Lactobacillus sp. Ca6. International Journal of Biological Macromolecules, 74, 541–546. https://doi.org/10.1016/j.ijbiomac.2014.12.045
25. Liu, K., & Catchmark, J. M. (2018). Effects of exopolysaccharides from Escherichia coli ATCC 35860 on the mechanical properties of bacterial cellulose nanocomposites. Cellulose, 25(4), 2273–2287. https://doi.org/10.1007/s10570-018-1709-3
26.Kerekes, E. B., Vidács, A., Takó, M., Petkovits, T., Vágvölgyi, C., Horváth, G., Balázs, V. L., & Krisch, J. (2019). Anti-Biofilm Effect of Selected Essential Oils and Main Components on Mono- and Polymicrobic Bacterial Cultures. Microorganisms, 7(9), 345. https://doi.org/10.3390/microorganisms7090345
27.Singh, K., Gujju, R., Bandaru, S., Misra, S., Babu, K. S., & Puvvada, N. (2022). Facet-Dependent Bactericidal Activity of Ag3PO4 Nanostructures against Gram-Positive/Negative Bacteria. American Chemical Society. https://doi.org/10.1021/acsomega.2c00864
28.Chepkwony, N. K., Berne, C., & Brun, Y. V. (2019). Comparative Analysis of Ionic Strength Tolerance between Freshwater and Marine Caulobacterales Adhesins. Journal of Bacteriology, 201(18). https://doi.org/10.1128/jb.00061-19
29.Shigemasa, Y., Matsuura, H., Sashiwa, H., & Saimoto, H. (1996). Evaluation of different absorbance ratios from infrared spectroscopy for analyzing the degree of deacetylation in chitin. International Journal of Biological Macromolecules, 18(3), 237–242. https://doi.org/10.1016/0141-8130(95)01079-3
30.Wiercigroch, E., Szafraniec, E., Czamara, K., Pacia, M. Z., Majzner, K., Kochan, K., Kaczor, A., Baranska, M., & Malek, K. (2017). Raman and infrared spectroscopy of carbohydrates: A review. Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, 185, 317–335. https://doi.org/10.1016/j.saa.2017.05.045