Team:UQ-Australia/Project

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Mercury sequestration using a Multicomponent Operon and Bioprecipitation using P.syringae

Project Abstract

Microbes such as Escherichia coli and Cuprivadis metallidurans have an endogenous multicomponent mercury (Hg2+) uptake and reduction operon, under the control of a metal responsive transcription factor, MerR. By utilising elements of this pathway, with a novel recovery mechanism, mercury can be accumulated intracellularly and efficiently removed from the environment. The presence of mercury activates MerR, driving the expression of Antigen 43 (Ag43), a self-adhering surface protein. Coupling a mercury sensitive promoter to the expression of Ag43 enables cells to accumulate mercury then aggregate in solution.


P. syringae is a ubiquitous airborne bacterium which expresses a unique protein, InaZ. This protein acts as a scaffold for ice nucleation, inducing precipitation. Optimal growth of P. syringae occurs at 22oC. By introducing five heat-shock genes, the tolerance range will be increased to better suit the Australian climate. This modification has the potential to increase the availability of Australia’s most precious resource; water.

Bioaccumulation (Mercury) Project

Project Outline

Escherichia coli.

Water contamination is a key environmental issue for many countries around the world, both developed and developing. In Queensland, Australia we have a particular problem with Mercury (Hg2+) contamination of water supplies around the major mining town of Mt Isa, and also from Airforce bases. After searching through the iGEM projects from previous years, the arsenic detection system inspired us. As the UQ 09' team, we wish to take this idea one step further and completely remove the offending heavy metal from water systems.

To do this we will be utilizing a strain of Escherichia coli, with their already established mercury uptake, reduction and efflux system and making a few modifications. One of our aims is to couple the detection of Mercury to the expression of a native bacterial protein, Antigen 43 (AG43). This protein, when expressed, causes the bacteria to stick to one another. As the bacteria aggregate in clumps, they will fall to the bottom of the sample. Our idea is for the bacteria to take up the mercury, activating Ag43 expression, resulting in aggregation, and the Mercury-filled bacteria will fall to the bottom leaving clean water.

There are a number of parts that we hope to add to the registry. The first is Ag43 as a protein coding sequence and the MerR promoter sequence. We will also add the completed mercury uptake and aggregation system as an operon.

Project Background

Many bacteria carry heavy metal resistance systems, either encoded on a plasmid or within their genome. For example, the bacterium Cupriavidis metallidurans, first isolated from a sludge tank contaminated with high levels of heavy metals, contains genes which encode for reistance systems to Ag(I), Cd(II), Co(II), Cr(IV), Hg(II), Ni(II), Pb(II), and Zn(II) [http://jb.asm.org/cgi/content/full/189/20/7417?view=long&pmid=17675385]. These systems commonly contain a metal transporter, a metal binding protein, a reduction mechanism, and a metal responsive promoter. In the case of Hg(II), the currently accepted general system is outlined below. [http://www.sciencedirect.com.ezproxy.library.uq.edu.au/science?_ob=ArticleURL&_udi=B6T37-48GFVCN-1&_user=331728&_rdoc=1&_fmt=&_orig=search&_sort=d&_docanchor=&view=c&_acct=C000016898&_version=1&_urlVersion=0&_userid=331728&md5=6382dc0a7b36b391d954a54651c2ff72]

UQ-Figure1.JPG

This system facilitates the transportation of Hg(II) into the cell, where MerA acts a reductase, producing Hg(0), which then diffuses out of the cell. However, our project focuses on the accumulation of mercury within the cell, so many elements of this pathway are unsuitable for our purpose. We envisage a system of two plasmids, one containing mercury resistance genes (mer genes).

Plasmid 1

This plasmid will allow for the transport of Hg(II) into the cell, where the protein metallothionien aids in intracellular accumulation. Once Hg(II) enters the cell, it activates MerR, a transcriptional regulator. When active, MerR will initiate the transcription of Antigen43 (Ag43).

Plasmid 2
A. DNA twisted conformation and transcription unable to occur B.Conformational change in MerR when Hg binds - transcription goes ahead C. Hypothetical situation in which MerD (in the endogenous system) binds preferentially to stop transcription [http://www.ncbi.nlm.nih.gov/pubmed/12829265 (4)].

Ag43 is a surface expressed autotransporter [http://jb.asm.org/cgi/content/full/182/17/4789?view=long&pmid=10940019]. This means all the information for suface targeting of the plasma membrane is contained within the protein. Since Ag43 is a native protein to E. Coli (specifically K12 strain), it must first be removed from the genome, then re-inserted as a plasmid so that its expression can be controlled. We were able to obtain a flu- E. coli strain, kindly donated by Associate Professor Mark Schembri from the University of Queensland. When two E. coli cells express Ag43, they aggregate together. Once enough of these cells aggregate, they will fall to the bottom of solution. This autoaggregation can be easily measured using a spectrophotometer.

UQ-Figure4.JPG

Methods

Culture Techniques

Transformation

Electroporation
Heat-shock

Picking Colonies

Positive colonies were picked from plates, and cultured in 3mL of either LB broth or S.O.C media, supplemented with the appropriate antibiotic. These cultures were incubated overnight at 37deg C in a shaking incubator.

Miniprep

3mL of overnight culture was pelleted, and processed using an Invitrogen PureLinkQuick Plasmid Miniprep Kit. Product was Nanodropped to determine concentration, then stored at -20deg C.

Glycerol Stock

Glycerol stock solution of the E.coli strand used was created by initially grown the original sample strand on an agrose gel plate overnight. Colonies grown overnight were then picked and placed into Lb solution containing ampicillin to remove unwanted strand of the bacteria, and grown overnight at 37 deg C on the shaker. The cells were formed into a pellet and resuspended in a 50:50 glycerol and Lb stock solution mixture. Cells were then stored for later use in a -80 deg C frezzer.

Digestions

Samples contained a mixture of water, buffer plasmid of appropriate enzyme. Samples were incubated at 37deg C with NEB or Promega restriction enzymes for at least 3 hours to ensure complete digestion. Samples were then ran on a 1% gel to determine the band size and if the digest had occured.

Agarose Gel

DNA grade agarose powder was mixed into 1x TAE and heated until fully dissolved to create either a 1% or 2% gel depending on the experimental parameters. The heated mixure is then poured into a mold and allowed to set. Gels were post-stained using Ethidium Bromide, then visualized with a UV transilluminator. All gels were run with an appropriate ladder depending on the size of the fragments.

In-gel extraction

Bands were excised with a scalpel blade viewed using a UV box removing all of the band with as little of the agarose from the gel. These pieces were then placed into pre-weighed eppendorf tubes and re-weighed after to determine the mass of the excised piece of agarose. In-gel extraction was performed as per protocol from Invitrogen Purelink Gel Extraction Kit. Product was Nanodropped to the determine concentration.

De-phosphorylation

Vector was incubated with Promega Shrimp Alkaline Phosphatase at 37deg C overnight.

Ligation

Insert and de-phosphorylated vector were incubated at room temperature with NEB T4 DNA ligase for at least one hour before transformation.

Sequencing

Whole plasmid samples with appropriate primers were submitted to the Australian Genome Research Facility within the University of Queensland for sequencing.

Results

Samples of E. coli MS427 containing either pBAD (empty vector) or pKKJ143 (Ag43+) were kindly donated by Associate Professor Mark Schembri, of The University of Queensland. Cultures were grown in 2mL were

Standard 21 transformations/resitriction checking. At least two gel photos.

Ag43 with restriction site synthesis (PCR). One gel, primer sequences.

Standard 23 transformations/restriction checking. One gel. Sequences with proposed cut sites.

Growth and extraction of mer plasmids Run on gel?

Sequencing of mer genes Primer sequences, proposed sequence. Sequencing data?

Add restriction sites through PCR. Gel picture, primer sequences.

Digest our genes, digest vectors. Picture? Think I cut the gel .... use nanodrop concentrations?

De-phosphorylate Method

Ligate Method

Transform (x2) Positive colonies!

Digest Gel picture

Send off!

Sequence Being done.

Conclusions

Standard 21 isn't standard 21!

Standard 23 is all good.

MerT part is correct.

References

[1] Monchy, S., Benotmane, M. A., Janssen, P., Vallaeys, T., Taghavi, S., van der Lelie, D. and Mergeay, M. (2007). Plasmids pMOL28 and pMOL30 of Cupriavidus metallidurans are specialized in the maximal viable response to heavy metals. J Bacteriol 189, 7417-25.

[2] Barkay, T., Miller, S. M. and Summers, A. O. (2003). Bacterial mercury resistance from atoms to ecosystems. FEMS Microbiol Rev 27, 355-84.

[3] Kjaergaard, K., M. A. Schembri, et al. (2000). Antigen 43 from Escherichia coli induces inter- and intraspecies cell aggregation and changes in colony morphology of Pseudomonas fluorescens. J Bacteriol 182(17): 4789-96.

Bioprecipitation using P.syringae

Project Description

P. syringae

The arid climate of Australia has become notorious for causing widespread problems for agricultural industries. That is, the scarcity of water hinders the production of crops and livestock, as well as forcing restrictions of daily water usage for households. Team UQ Australia aims to solve this problem through the use of a bio-precipitation technique, thus increasing the availability of our most precious resource.

Pseudomonas syringae is a common bacterium, primarily found in colder climates (optimally at 22°C), and is well known for its biological ice nucleation properties, i.e. the formation of rain/snow. This bacteria expresses an ice nucleation protein on its outer membrane (InaZ). InaZ acts as a scaffold for the formation of the ice crystals, this directly assists in the formation of clouds and speeds up the rain cycle. However, the bacteria are unable to survive in environmental temperatures above 28°C. The ideal growing temperatures for syringae are 22°C - 26°C. By introducing heat shock proteins (DnaK, DnaJ, GroEL, and GroES) through plasmid insertion, UQ Australia aims to increase the optimal growth temperature available to P.syringae, thereby allowing bio-precipitation to occur in warmer (and drought stricken) climates. Although syringae already has this proteins encoded within the genome, they are not expressed at levels similar to bacteria which grow at higher temperatures.

The heat shock proteins form two systems. GroEL and GroES form one dimer which acts as a chaperon. Together these proteins assists in lowering the mis-folding of proteins. At higher temperatures proteins become unstable and mis-fold at a higher rate.

Ideally, UQ Australia will be contributing a number of parts to the registry. Firstly, a plasmid with DnaK, DnaJ, as well as an upstream promoter will drive the expression of these two genes. Secondly, an additional plasmid will carry the genes for GroEL and GroES, also complemented by an upstream promoter to drive gene expression.

P. syringae and the rain cycle


Method

By taking measurements during the life cycle of P. syringae it should show a shift in the maximal growth peak. Over a 14 hour growth period absorbance readings were taken of the transformed bacteria.