Team:Imperial/Gluconacetobacter

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Imperial iGEM 2014

G. xylinus

Overview

Bacterial cellulose has great potential in many areas, including water purification, tissue scaffolds, wound dressings, etc., however, until now, all bacterial cellulose-based materials have been created using chemical or physical post-production processing, not genetic engineering. This is due to the lack of well-developed tools and methods for Gluconacetobacter genetic engineering, as well as the lack of genome sequence of the highest cellulose-producing strain ATCC 53582. We have overcome the numerous difficulties associated with G.xylinus genetic engineering, and turned G.xylinus KI and ATCC 53852 strains into new platforms for the production of cellulose-based biomaterials by sequencing the genomes of ATCC 53582 and KI, creating a genetic toolbox of consisting of five new plasmid backbones and 40 widely used genes, and developing a set of new and improved protocols for G.xylinus genetic engineering.

Key Achievements

  • Isolated a new strain of Gluconacetobacter from Kombucha tea and characterized its properties fully.
  • Sequenced the previously unknown genomes of two G. xylinus strains - cellulose high-producing ATCC 53582 and our Kombucha-isolated strain - the first genomes sequenced in the history of iGEM
  • Discovered four new plasmids capable of replication in Gluconacetobacter species - pSEVA321, pSEVA331, pSEVA351 and pBAV1K, which replicate both in G. xylinus ATCC 53582 and in Kombucha-isolated strains as well as E.coli
  • Created the first transgenic cells of the Kombucha-isolated strain of G. xylinus in science
  • Using our discovered plasmids, created a genetic toolbox consisting of 40 genes for G. xylinus engineering and expressed them in the ATCC 53582 and Kombucha-isolated strains
  • Developed a set of new and improved protocols for efficient genetic engineering of G. xylinus ATCC 53582 and our Kombucha-isolated strains
  • In summary, turned G. xylinus ATCC 53582 and KI strains into new model organisms and developed the necessary tools to create a powerful platform for the synthesis of new cellulose-based biomaterials and water filters

Introduction

Due to its high productivity, G. xylinus is the main species used for the production of bacterial cellulose based products. These range from superior wound dressings, artificial blood vessels, scaffolds for tissue engineering, high-quality speaker membranes, stronger paper, nata de coco and many others (Keshk 2014) .

G. xylinus has been the subject of the majority of studies into production of bacterial cellulose. However, research into G. xylinus has primarily focused on the effects of different culture conditions (such as composition of growth media, aeration and agitation) on cellulose productivity, productivity of different strains and different post-processing methods. Few attempts have been made to improve cellulose productivity or the physical properties of cellulose through genetic engineering (but see Chien 2006). Consequently most of the genetic engineering methods and tools available for model organisms, such as E.coli, have not been developed for G. xylinus. These tools must first be developed, in order to begin serious efforts to genetically engineer G. xylinus strains capable of producing novel biomaterials, more cellulose, and at a lower cost.

Aims

In addition to the lack of tools, the continuous cellulose production of G. xylinus introduces further problems for genetic engineering, as it results in a low growth rate (the division time of G. xylinus is 4 hours, which is 8 times slower than that of E. coli), formation of spontaneous cellulose non-producing mutants in agitated culture (detrimental for the engineering of high-producing strains) and difficulties in performing procedures such as transformation, plasmid DNA extraction, etc. due to the physically interfering cellulose pellicle.

Furthermore, although the highest cellulose-producing strain G. xylinus ATCC 53582 has been used in several studies, the genome sequence of this strain is still unknown, making it impossible to carry out targeted engineering of chromosomal genes, which is vital to achieve increased productivity.

We aim to solve all of these problems, by completing three major projects: sequencing the genomes of ATCC53582 and Kombucha-isolated strain and creating a large toolbox for G. xylinus genetic. We then aim to use these tools to increase and control cellulose productivity and create new biomaterials with wide-ranging properties, by incorporating proteins with different functions into the cellulose matrix (see Functionalisation).

Genome sequencing

Although genome sequencing has become widely available due to the improvements in next-generation sequencing, even with smaller bacterial genomes (the genome of G. xylinus is approximately 3.5Mbp in size), genome sequencing is still unavailable for small to mid-sized research groups due to high costs. We performed a survey of prices offered by all commercially available service providers using the Illumina MiSeq next-generation sequencing platform (which is the most cost-effective method for bacterial genome sequencing) in Europe, and found that the average costs of fully sequencing a 3.5Mbp genome (which includes library preparation, sequencing, bioinformatics and gap filling) is approximately £3000. In order to be able to sequence the genome with the limited budget available to our team, we did not use a commercial sequencing service, and decided to perform the full sequencing cycle ourselves, despite having no previous experience in genome sequencing. We created the gDNA library using Illumina Nextera kit, by modifying the original Illumina protocol to be amenable for small sample number (see gDNA library preparation protocol). During gDNA library preparation, we discovered that cellulose production of G.xylinus resulted in the presence of a persistent contaminant in DNA preparation, which persisted even after four consecutive DNA purification methods. This contamination interfered with effective library preparation, retarding the project several weeks, and ultimately prompted us to create a new and specific protocol for G.xylinus DNA extraction (see G.xylinus DNA extraction). We performed the sequencing run (multiplexed sequencing of ATCC 53582 and KI in single run, paired-end 250bp reads using standard flow cell) on the Illumina MiSeq present at Imperial College’s Genomics Laboratory. Despite problems with gDNA library preparation, the sequencing yielded good results (9063619 reads with 98.71% reads identified). We completed the genome assembly with the support of Imperial Bioinformatics Support service using their in-house assembly pipeline.

The genome of G. xylinus ATCC 53582

TEXT AND DATA HERE

The genome of Kombucha-isolated G. xylinus

TEXT AND DATA HERE:

NEW HEADING

TEXT HERE _ Because some E. coli promoters and proteins have been shown to work in Gluconacetobacter or Acetobacter species (Setyawati, 2007; Chien et al., 2006), s to create a toolbox for G.xylinus genetic engineering. .

Creating a genetic toolbox for G. xylinus

Despite the great potential G. xylinus holds for new biomaterial production, very few tools for genetic engineering had been developed so far. Thus, in parallel to sequencing the genomes, we began building a new system in order to equip G.xylinus with all of the necessary tools and to turn the ATCC 53582 and KI strains into systems for genetically engineered biomaterials production. We first characterized ATCC 53582 and KI strains, and created a set of new and improved protocols necessary for their genetic engineering (see G.xylinus protocols). As only a few vectors are available for G. xylinus genetic engineering (this is due to various reasons including patents, materials-transfer agreements, and retired or deceased researchers) we first created a set of new biobrick-compatible plasmid backbones capable of replication both in Gluconacetobacter and E.coli. In order to create the genetic toolkit, we decided to test out and modify already existing Biobricks in the parts registry (rather than creating a set of new parts) in order to retain the already existing familiarity genetic engineers have with these genes and make the toolkit more user-friendly. None of these parts had been used in Gluconacetobacter before however, so it was necessary to determine if they can be used in G.xylinus in the first place. Finally, we used this toolkit to clone Vitreoscilla hemoglobin gene Vhb (which is known to increase cellulose productivity and growth rate of G.xylinus (Chien et al. 2006)) behind a strong Anderson promoter, and express it in G.xylinus ATCC 53582 and G.xylinus KI strains to increase cellulose productivity and decrease its cost.

Characterization of G.xylinus ATCC 53582 and KI strains

Parts: -BBa_K1321305 -BBa_K1321306

Cellulose productivity of G.xylinus ATCC 53582 and KI on HS-glucose

G.xylinus cellulose productivity depends strongly on the carbon feedstocks used. In HS-glucose media grown for 7 days at 30degC standing using 50ml HS medium in 250ml conical flasks (sealed with foam buns), cellulose productivity of the KI strain is approximately one fifth of that of ATCC 53582 strain (see Figure X for comparison of ATCC53582 and KI strains and experimental details). ATCC 53582 strain produces around 0.5-0.6g of pure cellulose after 5 days of incubation in these conditions. As 50ml HS medium contains 1g of glucose, ATCC 53582 strain converts glucose to cellulose with around 50-60% efficiency. However, it seems for KI cellulose productivity, HS-glucose, is not optimal, because in HS-glycerol media and HS-sucrose media the cellulose productivity is increased. Importantly, in HS-sucrose medium, cellulose productivity is higher than that of ATCC 53582, which is of industrial significance due to the high availability and low cost of sucrose (see Feedstocks for G.xylinus KI).

Cellulose productivity on different carbon feedstocks

G.xylinus is commonly grown on HS-glucose. However, it can readily use other carbon feedstocks, including sucrose and glycerol. We have found that ATCC 53582 cellulose productivity is highest when grown on glycerol (see Figure Y.), although the effects of routine culturing of ATCC 53582 on HS-glycerol media are unknown. Suprisingly however, KI strain has a higher cellulose productivity in HS-sucrose than G.xylinus ATCC 53582 (see Figure 2 for comparison of ATCC and KI strains and details of he experiment). This could be due to the niche KI strain has evolved into, as the Kombucha tea contains high concentrations (commonly around 100g/L) of sucrose.

Natural antibiotics resistance of ATCC 53582 and KI strains

Using optimal antibiotics concentrations is critical for selection of transformed cells while not inhibiting the cell growth. G.xylinus ATCC 53582 is not resistant to kanamycin and ampicillin in concentrations normally used for E.coli (50µg/ml and 100µg/ml respectively), however is resistant to chloramphenicol (at 35µg/ml; see Figure 5 for an experiment of ATCC 53582 natural antibiotic concentrations, experimental details, and comparison of ATCC and KI strain). However, when using high cell densities for plating (after transformations), antibiotic -resistant colonies of ATCC 53582 appear at up to 3x concentrations. Thus, the recommended antibiotic concentrations for HS-agar plates are 200µg/ml kanamyicn, 400µg/ml ampicillin and 140µg/ml chloramphenicol.

G.xylinus KI is naturally resistant to kanamycin, ampicillin and chloramphenicol concentrations normally used for E.coli. Also, we have found that the frequency of appearance of antibiotic-resistant colonies is dependent on the number of cells used for plating - with higher cell numbers, resistant colonies can be found on higher antibiotics concentrations. We have found that the KI strain forms antibiotic-resistant colonies up to 6x antibiotic concentrations used for E.coli, thus the recommended amounts of antibiotics for transformations are 350µg/ml kanamycin, 700µg/ml ampicillin or 245µg/ml chloramphenicol.

Plasmid backbones

Figure 1. TEST.

We tested 9 different plasmid backbones previously not known to replicate in G.xylinus - pSEVA311, pSEVA321, pSEVA331, pSEVA341, pSEVA351, pBla-Vhb-122 (from Chien et al. 2006), pBAV1K-T5-sfgfp, pSB1C3 and pBca1020 (part number BBa_J61002) in order to create a set of plasmid backbones with different copy numbers for G.xylinus genetic engineering. We used pBla-Vhb-122 as the positive control, as it has been previously shown to replicate in G.xylinus (see Chien et al. 2006). In order to test for replication, we prepared two different sets of electrocompetent cells from both ATCC 53582 and Ki strains (see Preparing electrocompetent cells) and transformed using 33µl, 50µl and 100µl of electrocompetent cells and 50µg, 200µg and 500µg of DNA (see Transformation of G.xylinus using electroporation). Transformants were plated out on 4 different antibiotic concentrations for each transformation: 0.5x, 1x, 2x and 6x concentrations (this refers to concentrations of antibiotics commonly used for E.coli, which are 50µg/ml kanamycin, 100µg/ml ampicillin and 35µg/ml chloramphenicol). Colonies were then inoculated into HS-cellulase medium and grown for 3 days shaking at 180RPM with appropriate antibiotics, after which plasmid DNA was miniprepped using the QiaPrep Spin Miniprep kit, according to manufacturer's instructions. Miniprepped DNA was then used as a template for PCR to determine plasmid-containing colonies. Primers used for PCR had been previously verified with pure plasmid DNA. DNA sequence of successfully amplified plasmids were confirmed by Sanger sequencing.

We discovered that 5 out of the 9 tested plasmids - pSEVA321, pSEVA331, pSEVA351, pBAV1K and pBla-Vhb-122 (as the positive control)- were capable of replication in both G.xylinus KI and ATCC 53583 (See figure X). No positive results were obtained for other plasmids, indicating that the rest can not replicate in G.xylinus, or were not transformed due to other reasons. We converted pSEVA321 and pSEVA331 into a biobrick-compatible format by inserting the biobrick prefix and suffix in place of the original multiple cloning site using PCR with mutagenic primers and are currently in the process of converting pSEVA351 and pBla-Vhb-122 (converting them into biobrick format has required more time, as they contain several forbidden restriction enzyme sites requiring multiple steps of mutagenesis). pBAV1K was already engineered to be biobrick compatible by their authors. We have also verified replication of all of these plasmids in E.coli. Thus, we have determine 5 new plasmid backbones that can act as shuttle vectors for G.xylinus genetic engineering:

Anderson promoters

We aim to increase cellulose productivity by inserting the Vitreoscilla hemoglobin gene into G. xylinus and finding the optimum expression level by expressing Vitreoscilla hemoglobin behind different Anderson promoters. (Vitreoscilla haemoglobin was shown to increase cellulose productivity and growth rate by Chien 2006).

Inducible promoters

We aim to increase cellulose productivity by inserting the Vitreoscilla hemoglobin gene into G. xylinus and finding the optimum expression level by expressing Vitreoscilla hemoglobin behind different Anderson promoters. (Vitreoscilla haemoglobin was shown to increase cellulose productivity and growth rate by Chien 2006).

Chromoproteins

We aim to increase cellulose productivity by inserting the Vitreoscilla hemoglobin gene into G. xylinus and finding the optimum expression level by expressing Vitreoscilla hemoglobin behind different Anderson promoters. (Vitreoscilla haemoglobin was shown to increase cellulose productivity and growth rate by Chien 2006).

Engineering

Sequencing the genomes of G. xylinus ATCC 53582 and Kombucha-isolated G. xylinus strains

Although genome sequencing has become widely available due to the improvements in next-generation sequencing, even with smaller bacterial genomes (the genome of G. xylinus is approximately 3.5Mbp in size), genome sequencing is still unavailable for small to mid-sized research groups due to high costs. We performed a survey of prices offered by all commercially available service providers using the Illumina MiSeq next-generation sequencing platform (which is the most cost-effective method for bacterial genome sequencing) in Europe, and found that the average costs of fully sequencing a 3.5Mbp genome (which includes library preparation, sequencing, bioinformatics and gap filling) is approximately £3000.

In order to be able to sequence the genome with the limited budget available to our team, we did not use a commercial sequencing service, and decided to perform the full sequencing cycle ourselves, despite having no previous experience in genome sequencing. We created the gDNA library using Illumina Nextera kit, by modifying the original Illumina protocol to be amenable for small sample number (see gDNA library preparation protocol). During gDNA library preparation, we discovered that cellulose production of G.xylinus resulted in the presence of a persistent contaminant in DNA preparation, which persisted even after four consecutive DNA purification methods. This contamination interfered with effective library preparation, retarding the project several weeks, and ultimately prompted us to create a new and specific protocol for G.xylinus DNA extraction (see G.xylinus DNA extraction). We performed the sequencing run (multiplexed sequencing of ATCC 53582 and KI in single run, paired-end 250bp reads using standard flow cell) on the Illumina MiSeq present at Imperial College’s Genomics Laboratory. Despite problems with gDNA library preparation, the sequencing yielded good results (9063619 reads with 98.71% reads identified). We completed the genome assembly with the support of Imperial Bioinformatics Support service using their in-house assembly pipeline.

Creating a toolbox for Gluconacetobacter genetic engineering

In parallel to sequencing the genome, we began building a large toolbox for G. xylinus genetic engineering. Only a few vectors have been developed for G. xylinus, and most of them were not available for us for various reasons (including patents, materials-transfer agreements, and retired or deceased researchers). For this reason, we first tested out a set of new plasmids, and engineered them to be Biobrick compatible. As some E. coli promoters and proteins have been shown to work in Gluconacetobacter or Acetobacter species (Setyawati, 2007; Chien et al., 2006), and similarly to E.coli, G. xylinus is a Gram- species, we decided to test out and modify already existing Biobricks in the parts registry in G. xylinus. Therefore, the toolkit consists of:

  • New, Biobrick compatible shuttle vectors for Gluconacetobacter and E. coli
    • pSEVA321
    • pSEVA331
    • pSEVA351
    • pBAV1K
  • Characterization and optimization of parts from the Registry, including:
    • Fluorescent proteins, GFP, RFP, YFP, CFP
    • Chromoproteins
    • Vitreoscilla haemoglobin
    • The entire Anderson promoter library
    • Widely used gene expression control proteins AraC and TetR.

Engineering a high cellulose-producing ATCC 53582 strain

We aim to increase cellulose productivity by inserting the Vitreoscilla hemoglobin gene into G. xylinus and finding the optimum expression level by expressing Vitreoscilla hemoglobin behind different Anderson promoters. (Vitreoscilla haemoglobin was shown to increase cellulose productivity and growth rate by Chien 2006).

Results

We have isolated a new strain of Acetobacter from kombucha, and determined its growth rate, cellulose productivity, and natural antibiotic resistance. We have also developed a set of methods for genetic engineering of this strain and have determined five new plasmids capable of replication in this strain. Thus we are the first to genetically engineer it.

We have discovered four new plasmids capable of replication in Acetobacter species - pSEVA321, pSEVA331, pSEVA351 and pBAV1K - both in G.xylinus ATCC 53582 strain, and in the strain we isolated from Kombucha. We have biobricked these plasmids, with the exception of pBAV1K, which had been originally engineered to be biobrick compatible (however, pBAV1K can not be uploaded to parts registry due to binding materials-transfer agreements).

References