Team:Heidelberg/Templates/Delftibactin Results

From 2013.igem.org

Efficient Recycling of Gold from Electronic Waste using Delftibactin

As first, important step in direction of an environmental friendly procedure for recycling gold from gold-containing waste, we wanted to show that the non-ribosomal peptide delftibactin can be used to precipitate gold from gold ion-containing solutions.

We obtained D. acidovorans DSM-39 from the DSMZ and successfully reproduced the paper by Johnsson et al. ( [5]). In our experiments, precipitation on agar plates worked even better than described in the paper as shown in Figure 1. D. acidovorans is capable to precipitate solid gold from gold chloride solution as purple-black nanoparticles. Already at low concentrations of gold chloride, gold nonaparticles are precipitated increasing with concentration of gold chloride in solution (Fig. 2).

<a href="File:Heidelberg_IMAG0449.png">File:Heidelberg_IMAG0449.png</a>| Figure 1:ACM agar plate with D. acidovorans (left) overlaid with 0.2% HAuCl₄ in 0.5% agarose <a href="File:Heidelberg_Goldsequenzen.png">File:Heidelberg_Goldsequenzen.png</a>| Figure 2:Sequences of movie showing gold precipitation in D. acidovorans supernatant using gold concentrations ranging from 0 to 2.55 µg/ml

Using supernatants from the new Delftia acidovorans strain SPH-1, we showed precipitation of gold chloride solution to gold nanoparticles. Furthermore, we melted the purple-black nanoparticles to shiny solid gold as shown in figures 3 to 5.

<a href="File:Heidelberg_IMG_0624.JPG">File:Heidelberg_IMG_0624.JPG</a>| Figure 3: Sparkling gold appearing in the melting pot. <a href="File:Heidelberg_IMG_4059.JPG">File:Heidelberg_IMG_4059.JPG</a>| Figure 4: Final recovered solid gold collected in tube. <a href="File:Heidelberg_P1010724.JPG">File:Heidelberg_P1010724.JPG</a>| Figure 5: Solid gold recovered from nanoparticles in 2 ml tube.

Next, we established purification of Delftibactin using HP20 resins. Additionally, we proved precipitation of gold by the purified Delftibactin (figures 6 and 7) and detected it by Micro-TOF.

<a href="File:Heidelberg_Microtof-Delftia.png" title="wikilink">300px|thumb|right |Fig.8: Micro-TOF result for D. acidovaorans</a>

<a href="File:Heidelberg_IMG">File:Heidelberg_IMG</a> 4367.JPG|Figure 6: Test if purified Delftibactin is able to precipitate gold. From left to right: ACM media, filtered supernatant D. acidovorans, purified Delftibactin <a href="File:Heidelberg_IMG">File:Heidelberg_IMG</a> 4368.JPG| Figure 7: Test if purified Delftibactin (diluted 1:10 in H₂O) is able to precipitate gold. From left to right: water, 1:10 ACM media, 1:10 supernatant D. acidovorans, 1:10 filtered supernatant D. acidovorans, 1:10 purified Delftibactin

An important prerequisite for efficient gold recycling from electronic waste is, undoubtedly, that gold precipitation should occur even if the concentration of the gold ions in solution would be rather low, as this would likely be the case for most gold solutions derived from electronic waste.

Therefore, we used an old, broken CPU and established a protocol for dissolving gold from gold-containing metal waste. We incubated golden CPU pins in aqua regia resulting in a gold-ion containing solution (figures 9 to 11).

<a href="File:Heidelberg_IMG_4085.JPG">File:Heidelberg_IMG_4085.JPG</a>| Figure 9: Pins removed from an old CPU. <a href="File:Heidelberg_IMG_4344.JPG">File:Heidelberg_IMG_4344.JPG</a>| Figure 10: Green solution of dissolved pins. <a href="File:Heidelberg_IMG">File:Heidelberg_IMG</a> 4364.JPG| Figure 11: Gold chloride solution obtained from an old CPU.

Moreover, we showed precipitation of dissolved gold recovered from electronic waste by D. acidovorans.

<a href="File:Heidelberg_IMG_4805.JPG">File:Heidelberg_IMG_4805.JPG</a>| Figure 12: “Dissolved electronic waste” and D. acidovorans. <a href="File:Heidelberg_IMG_4818.JPG">File:Heidelberg_IMG_4818.JPG</a>| Figure 13: “Dissolved electronic waste” on D. acidovorans <a href="File:Heidelberg_IMG">File:Heidelberg_IMG</a> 4828.JPG| Figure 14: Precipitated “dissolved electronic waste” and D. acidovorans

Adding this solution to D. acidovorans agar plates resulted in the formation of solid gold nanoparticles.

Taken together, we have successfully established a method enabling the recycling of pure gold from electronic waste using delftibactin produced by D. acidovorans.
Although the recycling was been working efficiently in our hands, the approach of using the natural D. acidovorans bacterial strain for delftibactin production on a larger scale has several disadvantages:

: a) D. acidovorans are relatively slow in growth (colony formation on plates occurs after 2-3 days) : b) Efficient production of delftibactin requires the strain to be grown in ACM media, which is rather expensive compared to typical E. coli growth media, making the procedure less economic

Therefore, we wanted to engineer an E. coli strain producing delftibactin in high yields, thereby circumventing the abovementioned limitations. To this end, we first had to develop a thorough cloning strategy which would allow us to clone all necessary genes encoding the delftibactin-producing non-ribosomal peptide synthetases and polyketide synthetases from the del cluster (about 50 kb in total) and express them in E. coli alongside with the MethylMalonyl-CoA pathway providing one of the basic substrates in this pathway not naturally present in E. coli.

Amplification of the Del Cluster Genes

<img src="Heidelberg_Delftibactin_Intro.png" title="fig:Fig.15: Overview on cloning strategy for the introduction of the delftibactin production pathway in E. coli." alt="Fig.15: Overview on cloning strategy for the introduction of the delftibactin production pathway in E. coli." /> The first step towards introducing the Delftibactin expression pathway into E. coli was the amplification of the Del-cluster encoded on the genome of Delftia acidovorans. To this end, we designed Gibson primers and amplified the genes of the non-ribosomal peptide synthetase and the polyketide synthase (PKS) pathway as well as of additional proteins, which were predicted to be necessary for the production of Delftibactin [5] . In the first weeks, PCRs were successfully established and optimized. At the same time, a separate plasmid was created encoding the PPTase from Bacillus subtilis, the MethylMalonyl-CoA pathway and a permeability device [BBa_I746200][1](http://parts.igem.org/wiki/index.php?title=Part:BBa_I746200) for the export of the synthesized delftibactin NRP. Additionally, low-copy plasmids from the partsregistry <a href="http://parts.igem.org/Main_Page">2</a> were successfully transformed and amplified using corresponding Gibson primers in order to generate the destination backbone fragments for the assembly.

Details of our cloning strategy are shown in figure 15. Notably, the three plasmids we wanted to assemble are huge (23, 32 and 10 kbp in size) and was further complicated due to the high GC content and presence of repetitive elements in Del genes.

Gibson Assembly & Transformation

Assembly of plasmids above 20 kb in size and composed of multiple different fragments is challenging when using conventional restriction-enzyme based cloning. Thus, we have used the Gibson Assembly method <a href="https://2010.igem.org/Team:Cambridge/Gibson/Protocol"></a>, which was introduced to the iGEM community by Cambridge in iGEM 2010 as powerful alternative to such common cloning procedures. The assembled constructs of up to 32 kbp in size were transformed into E. coli via electroporation. Correct assemblies of the fragments was tested by analytical restriction digests. The exemplary restriction digest shown above (Fig. 16) confirmed the correct assembly of the three desired constructs as it shows the expected band pattern expected from in silico digestion. Clones (6 and 9) contained the plasmid that encodes for the Methylmalonyl-CoA pathway (Fig. 16a). The obtained DNA sequences were sent in for sequencing over the Gibson-assembled regions for confirmation. <a href="http://www.mwg-biotech.com/">3</a>,<a href="http://www.gatc-biotech.com/de/index/.html"></a> The sequencing confirmed the accuracy of the sequence.

The successful generation of DelRest plasmid was proven by different enzymatic restriction digests (Fig. 16b) and also attested by the sequencing. The sequence was compared with the available D. acidovorans SPH1 reference sequence of the Del cluster obtained from NCBI <a href="http://tools.neb.com/">4</a> (For further information please visit our labjournal). This shows, that Gibson assembly is a suitable cloning approach for rapid assembly of large NRPS and PKS expression constructs.

Analytical restriction digest of DelH (Fig.16c) also gave rise to a number of positive clones. However, in contrary to the two successfully assembled and sequenced plasmids discussed above, the sequencing results derived from all DelH clones showed various mutations, which were mostly located within the region of the first DelH forward primer. Most of these mutations were deletions present at the very beginning of the DelH coding region. Interestingly, one specific deletion in the DNA sequence was found consistently in several independent clones. As we did not have any clone without mutations, we proceeded with the a DelH clone (termed C5), as this clone did not have any bp deletion but only harbored a minor base-pair substitution (leading to conversion of the DelH Alanine at position 10 to Threonine). Some exemplary sequences are listed below (Tab. 1) of Delftia acidovorans and two observed mutations in different DelH clones.

‘’Tab.1 DelH 5’ sequence, in which most mutations were observed. The ATG start codon is depicted in bold. The table shows the sequence comparison between the DelH reference strand of D. acidovorans and two different exemplary E. coli clones transformed with the plasmid pHM04 (assembled DelH expression vector). The second line shows the accumulated deletion and the third line shows the clone containing ‘only’ single base pair substitution. Deletions appeared quite frequently while a substitution was only found in a single clone C5. The substitution changes the corresponding Alanine codon to Threonine.’’

Due to the fact that E. coli seemed to somehow selected for mutated DelH clones, we hypothesize that expression of DelH in absence of the other proteins might be toxic for the cells. This would explain why E. coli selects for mutated, none functional, truncated DelH proteins. The same phenomenon of frequent mutations in presumably positive clones was also observed when we started cloning of the permeability device used in the pIK8 construct. The sequenced plasmids showed an unusually high accumulation of mutations compared to other constructs. In case of the methylmalonyl-CoA plasmid (pIK8), the problem was solved by the usage of a weak promoter and a weak ribosome binding site from the partsregistry for driving the expression of the permeability device. Based on this knowledge, DelH is currently being re-assembled into a new backbone (pSB6A1) [<a href="http://parts.igem.org/Part">http://parts.igem.org/Part</a>:.pSB6A1?title=Part:pSB6A1 ] containing a weak promoter BBa_J23114 <a href="http://parts.igem.org/Part:BBa_J23114"></a> and the ribosome binding site BBa_B0032<a href="http://parts.igem.org/Part:BBa_B0032"></a>. While the new plasmid is constructed, the following experiments were performed with the C5 clone as we hypothesized, that pHM04 construct #C5 bearing the single nucleotide exchange at position 28 might still show expression of functional DelH when transformed into E. coli (the corresponding amino acid exchange is located at the N-terminus).

Therefore, we transformed all three plasmids, namely the pHM04 #C5 (encoding DelH), the DelRest plasmid (encoding all other del genes despite delH) and the pIK8 construct (bearing the MethylMalonyl-CoA pathway, the Sfp PPTase and the permeability device expression cassette) into E. coli DH10ß and E. coliBL21 DE3 in parallel. This should lead to E. coli cells producing delftibactin and secreting it into the media.

Expression of the Delftibactin NRPSs & Associated Genes

We carried out experiments to test whether our constructs enable expression of the delftibactin NRPS/PKS pathway in E. coli.

<img src="Heidelberg_SDS-PAGES.png" title="fig:Fig.17: SDS-Page of a) E. coli DH10ß DelRest D8w and b) E. coli BL21 DE3 and E. coli BL21 DE3 containing DelH C5" alt="Fig.17: SDS-Page of a) E. coli DH10ß DelRest D8w and b) E. coli BL21 DE3 and E. coli BL21 DE3 containing DelH C5" /> For expression of DelH and DelRest, we conducted SDS-PAGE followed by Coomassie stainig. As negative controls we used untransformed cells and cells transformed only with the original plasmid backbones. The proteins DelE, DelG and DelH are significantly larger than any protein that is expressed by our host E. coli. Therefore, the expression of the introduced genes was clearly visible on the SDS-PAGE (Fig. 17). Even though the expression was weak, as we have expected for such a large proteins, clear distinct bands at the expected size of DelE and DelG were detected for the clone transformed with the DelRest plasmid and a band at the size of DelH for the clone transformed with the DelH plasmid. As the promoter in front of DelE and DelG controls the expression of DelA, DelB, DelC, DelD and DelF, too, one can assume simultaneous expression of these Del proteins.

<img src="Heidelberg_Bacitracin.png" title="fig:Figure 18: Left: TOP10-pIK8.6, right: TOP10-pIK8.1 (negative control) counterclockwise, starting top right: 8 µl, 4 µl, 2 µl, 1 µl bacitracin" alt="Figure 18: Left: TOP10-pIK8.6, right: TOP10-pIK8.1 (negative control) counterclockwise, starting top right: 8 µl, 4 µl, 2 µl, 1 µl bacitracin" /> Furthermore, the expression of the PPTase was verified by performing an IndC activity assay. The indigoidine synthetase IndC activity is dependent on the presence of a functional PPTase which is needed for synthesis of the blue pigment indigoidine. Co-transformation of the corresponding plasmid pIK8 (enabling Sfp PPTase expression) with an IndC indigoidine synthetase expression construct lacking a PPTase expression cassette. The transformed E. coli grew very slowly and developed the expected blue phenotype. From these results, we can clearly conclude that the PPTase on pIK8 is functionally expressed (note: decelerated growth kinetics of E. coli results from the metabolic burden that is caused by the synthesis of the indigoidine).

For proving that E. coli also produces the permeability device, which is needed for export ofDelftibactin out of the cells, a Hemmhof agar diffusion test with bactracin was performed. Bacitracin is a very large antibiotic which is usually not able to diffuse across the cell membrane passively. Absent growth upon application of bacitracin of bacteria containing the plasmid while in the control cells without the device were not affected by the antibiotic (Fig. 18) confirms expression of the transporter.

In conclusion, we successfully expressed the recombinant Delftibactin NRPS/ PKS pathway as well as the required Methylmalonyl-CoA pathway, the PPTase and permeability device in E. coli.

We furthermore showed, that it is not only possible to assemble large plasmids (in sum these were about 64 kpb in total size in our case) and transform them into E. coli, but showed successful expression of large NRPS/PKS modules in our host strain.