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<article>Our copper accumulation system works in two ways. We prevent the export of Cu(I) by knocking out the native <i>E. coli</i> copper export <i>cus</i> operon. In addition we identified genes involved in copper uptake, <i>hmtA</i>, <i>oprC</i>, <i>copC</i> and <i>copD</i>, and cloned them into <i> E. coli</i>. This combined system provides and represents an highly efficient and specific accumulation system for copper ions. | <article>Our copper accumulation system works in two ways. We prevent the export of Cu(I) by knocking out the native <i>E. coli</i> copper export <i>cus</i> operon. In addition we identified genes involved in copper uptake, <i>hmtA</i>, <i>oprC</i>, <i>copC</i> and <i>copD</i>, and cloned them into <i> E. coli</i>. This combined system provides and represents an highly efficient and specific accumulation system for copper ions. | ||
</article> | </article> | ||
− | <h2>The results of the accumulation experiments can be found <a href="https://2018.igem.org/Team:Bielefeld-CeBiTec/Accumulation_Results">here</a>. | + | <h2>The results of the accumulation experiments can be found <a href="https://2018.igem.org/Team:Bielefeld-CeBiTec/Accumulation_Results">here</a>.</h2> |
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− | + | <b>Arnesano, F., Banci, L., Bertini, I., & Thompsett, A. R. (2002).</b> Solution structure of CopC: a cupredoxin-like protein involved in copper homeostasis. <i>Structure</i>, <i>10</i>(10), 1337-1347.<br/> | |
<b>Bagai, I., Rensing, C., Blackburn, N. J., & McEvoy, M. M. (2008).</b> Direct metal transfer between periplasmic proteins identifies a bacterial copper chaperone. <i>Biochemistry</i>, <i>47</i>(44), 11408-11414.</br> | <b>Bagai, I., Rensing, C., Blackburn, N. J., & McEvoy, M. M. (2008).</b> Direct metal transfer between periplasmic proteins identifies a bacterial copper chaperone. <i>Biochemistry</i>, <i>47</i>(44), 11408-11414.</br> |
Latest revision as of 21:34, 2 December 2018
Accumulation
Short Summary
Introduction
Since copper is toxic to all types of cells (Ladomersky & Petris, 2015), the existence of transporters for the active and selective uptake of copper ions may initially come as a surprise, but copper also carries out important functions in many cells. As a cofactor for many different enzymes such as superoxide dismutase it is primarily involved in electron transfer, dioxygen transport and activation (Solomon et al., 2014). Accordingly, there must be natural absorption mechanisms for the trace element both into the periplasm and the cytoplasm. Nevertheless, as non-bonded, dissolved copper in particular is very toxic, there are efficient export systems in E. coli to keep a tightly controlled copper homeostasis and remove excess copper from the cell (Rensing & Grass, 2003). In order to create an efficient accumulation system for copper ions, highly selective uptake systems must be expressed on the one hand and existing export systems must be suppressed on the other.
Preventing Copper Export
We constructed a knock out mutant of E. coli DH5α using CRISPR/Cas9 to remove the whole cus operon ultimately prohibiting Cu(I) export. Consequently Cu(I) ions can not leave the periplasmic space. Subsequently the oxidization of Cu(I) to Cu(II) occurs spontaneously in the oxidative environment of aerobically grown cultures and is catalyzed by multicopper oxidase CueO which is native to E. coli (Outten et al., 2001).
Copper Import
As comparable uptake system are not known in E. coli (Rensing & Grass, 2003) we identified the outer membrane porin OprC from Pseudomonas aeruginosa as a good candidate for this purpose (Yoneyama & Nakae, 2001). OprC belongs to the superfamily of TonB-dependent receptors to which TonB binds as a signal protein (Postle & Good, 1983). It was shown that OprC allows the selective uptake of Cu(I/II) into the periplasmic space whilst other toxic ions like Ag(I) and Hg(II) are not imported (Yoneyama & Nakae, 1996, Quintana, Novoa-Aponte & Argüello, 2017). For our project we used a OprC homolog of P. brassicacearum 3Re2-7 (strain not pulished yet, for more information please contact Prof. Dr. Alfred Pühler) with 71% protein identity to avoid working with an organism from risk group two.
In order to further increase the intracellular concentration of copper ions, the P-type ATPase HmtA from P. aeruginosa can be used. It actively transports copper ions across the cytoplasmic membrane into the cytoplasm (Lewinsohn, Lee & Rees, 2009). As with oprC the homolog from the non-pathogenic P. brassicacearum 3Re2-7 with a protein identity of 80% was used. HmtA expression was found to lead to acute hypersensitivity for Cu(II) and Zn(II), which is a result of Cu(II)/Zn(II) uptake consequently leading to increased intracellular concentrations of these metal ions (Lewinsohn, Lee & Rees, 2009). Uptake of other cations into the cytoplasm like toxic Ag(I) and Cd(II) ions is not facilitated by hmtA expression (Lewinson, Lee & Rees, 2009). As hmtA expression depends on the extracellular Zn(II) concentration and Zn(II) is transported as well as Cu(II) by HmtA (Pederick et al., 2015), it can be assumed that HmtA is a zinc importer which also transports copper ions due to the similarity in size and charge of Zn(II) and Cu(II) ions.
Another transportation system is copCD from the copABCD operon for copper homeostasis in Pseudomonas syringae pv. tomato. This operon encodes for a precise regulation system of intracellular Cu(II) concentration (Lawton et al., 2016). The two genes copC and copD exist in various forms like in a copABCD operon, standing alone as a copCD operon or even build up CopCD fusion proteins (Arnesano et al., 2002, Lawton et al., 2016) and their function is not fully understood yet. One proposed function is the uptake of Cu(II) ions into the cytoplasm (Cha & Cooksey, 1993). CopC is a putative metallochaperone and exists in different forms with one or two copper binding sites (Lawton et al., 2016) and CopD is a inner membrane protein that is presumably able to pump Cu(II) into the cell. We identified both genes in the genome of P. brassicacearum 3Re2-7 and transferred them into E. coli to increase the uptake of Cu(II) and accumulate intracellular copper.
Conclusion
The results of the accumulation experiments can be found here.
Arnesano, F., Banci, L., Bertini, I., & Thompsett, A. R. (2002). Solution structure of CopC: a cupredoxin-like protein involved in copper homeostasis. Structure, 10(10), 1337-1347.
Bagai, I., Rensing, C., Blackburn, N. J., & McEvoy, M. M. (2008). Direct metal transfer between periplasmic proteins identifies a bacterial copper chaperone. Biochemistry, 47(44), 11408-11414. Cha, J. S., & Cooksey, D. A. (1993). Copper hypersensitivity and uptake in Pseudomonas syringae containing cloned components of the copper resistance operon. Applied and environmental microbiology, 59(5), 1671-1674. Delmar, J. A., Su, C. C., & Edward, W. Y. (2013). Structural mechanisms of heavy-metal extrusion by the Cus efflux system. Biometals, 26(4), 593-607. Franke, S., Grass, G., Rensing, C., & Nies, D. H. (2003). Molecular analysis of the copper-transporting efflux system CusCFBA of Escherichia coli. Journal of bacteriology, 185(13), 3804-3812. Gudipaty, S. A., Larsen, A. S., Rensing, C., & McEvoy, M. M. (2012). Regulation of Cu (I)/Ag (I) efflux genes in Escherichia coli by the sensor kinase CusS. FEMS microbiology letters, 330(1), 30-37. Ladomersky, E., & Petris, M. J. (2015). Copper tolerance and virulence in bacteria. Metallomics, 7(6), 957-964. Lawton, T. J., Kenney, G. E., Hurley, J. D., & Rosenzweig, A. C. (2016). The CopC family: structural and bioinformatic insights into a diverse group of periplasmic copper binding proteins. Biochemistry, 55(15), 2278-2290. Lewinson, O., Lee, A. T., & Rees, D. C. (2009). A P-type ATPase importer that discriminates between essential and toxic transition metals. Proceedings of the National Academy of Sciences, 106(12), 4677-4682. McDevitt, C. A. (2015). ZnuA and zinc homeostasis in Pseudomonas aeruginosa. Scientific reports, 5, 13139. Munson, G. P., Lam, D. L., Outten, F. W., & O'Halloran, T. V. (2000). Identification of a copper-responsive two-component system on the chromosome of Escherichia coli K-12. Journal of Bacteriology, 182(20), 5864-5871. Outten, F. W., Huffman, D. L., Hale, J. A., & O'Halloran, T. V. (2001). The independent cue and cusSystems confer copper tolerance during aerobic and anaerobic growth inEscherichia coli. Journal of Biological Chemistry, 276(33), 30670-30677. Pederick, V. G., Eijkelkamp, B. A., Begg, S. L., Ween, M. P., McAllister, L. J., Paton, J. C., & McDevitt, C. A. (2015). ZnuA and zinc homeostasis in Pseudomonas aeruginosa. Scientific reports, 5, 13139. Postle, K., & Good, R. F. (1983). DNA sequence of the Escherichia coli tonB gene. Proceedings of the National Academy of Sciences, 80(17), 5235-5239. Quintana, J., Novoa-Aponte, L., & Argüello, J. M. (2017). Copper homeostasis networks in the bacterium Pseudomonas aeruginosa. Journal of Biological Chemistry, jbc-M117. Rensing, C., & Grass, G. (2003). Escherichia coli mechanisms of copper homeostasis in a changing environment. FEMS microbiology reviews, 27(2-3), 197-213. Solomon, E. I., Heppner, D. E., Johnston, E. M., Ginsbach, J. W., Cirera, J., Qayyum, M., ... & Tian, L. (2014). Copper active sites in biology. Chemical reviews, 114(7), 3659-3853. Tseng, T. T., Gratwick, K. S., Kollman, J., Park, D., Nies, D. H., Goffeau, A., & Saier Jr, M. H. (1999). The RND permease superfamily: an ancient, ubiquitous and diverse family that includes human disease and development proteins. Journal of molecular microbiology and biotechnology, 1(1), 107-125. Xiao, M., Zhu, X., Fan, F., Xu, H., Tang, J., Qin, Y., ... & Zhang, X. (2017). Osmotolerance in Escherichia coli is improved by activation of copper efflux genes or supplementation with sulfur containing amino acids. Applied and environmental microbiology, AEM-03050. Yoneyama, H., & Nakae, T. (1996). Protein C (OprC) of the outer membrane of Pseudomonas aeruginosa is a copper-regulated channel protein. Microbiology, 142(8), 2137-2144.
Bagai, I., Rensing, C., Blackburn, N. J., & McEvoy, M. M. (2008). Direct metal transfer between periplasmic proteins identifies a bacterial copper chaperone. Biochemistry, 47(44), 11408-11414. Cha, J. S., & Cooksey, D. A. (1993). Copper hypersensitivity and uptake in Pseudomonas syringae containing cloned components of the copper resistance operon. Applied and environmental microbiology, 59(5), 1671-1674. Delmar, J. A., Su, C. C., & Edward, W. Y. (2013). Structural mechanisms of heavy-metal extrusion by the Cus efflux system. Biometals, 26(4), 593-607. Franke, S., Grass, G., Rensing, C., & Nies, D. H. (2003). Molecular analysis of the copper-transporting efflux system CusCFBA of Escherichia coli. Journal of bacteriology, 185(13), 3804-3812. Gudipaty, S. A., Larsen, A. S., Rensing, C., & McEvoy, M. M. (2012). Regulation of Cu (I)/Ag (I) efflux genes in Escherichia coli by the sensor kinase CusS. FEMS microbiology letters, 330(1), 30-37. Ladomersky, E., & Petris, M. J. (2015). Copper tolerance and virulence in bacteria. Metallomics, 7(6), 957-964. Lawton, T. J., Kenney, G. E., Hurley, J. D., & Rosenzweig, A. C. (2016). The CopC family: structural and bioinformatic insights into a diverse group of periplasmic copper binding proteins. Biochemistry, 55(15), 2278-2290. Lewinson, O., Lee, A. T., & Rees, D. C. (2009). A P-type ATPase importer that discriminates between essential and toxic transition metals. Proceedings of the National Academy of Sciences, 106(12), 4677-4682. McDevitt, C. A. (2015). ZnuA and zinc homeostasis in Pseudomonas aeruginosa. Scientific reports, 5, 13139. Munson, G. P., Lam, D. L., Outten, F. W., & O'Halloran, T. V. (2000). Identification of a copper-responsive two-component system on the chromosome of Escherichia coli K-12. Journal of Bacteriology, 182(20), 5864-5871. Outten, F. W., Huffman, D. L., Hale, J. A., & O'Halloran, T. V. (2001). The independent cue and cusSystems confer copper tolerance during aerobic and anaerobic growth inEscherichia coli. Journal of Biological Chemistry, 276(33), 30670-30677. Pederick, V. G., Eijkelkamp, B. A., Begg, S. L., Ween, M. P., McAllister, L. J., Paton, J. C., & McDevitt, C. A. (2015). ZnuA and zinc homeostasis in Pseudomonas aeruginosa. Scientific reports, 5, 13139. Postle, K., & Good, R. F. (1983). DNA sequence of the Escherichia coli tonB gene. Proceedings of the National Academy of Sciences, 80(17), 5235-5239. Quintana, J., Novoa-Aponte, L., & Argüello, J. M. (2017). Copper homeostasis networks in the bacterium Pseudomonas aeruginosa. Journal of Biological Chemistry, jbc-M117. Rensing, C., & Grass, G. (2003). Escherichia coli mechanisms of copper homeostasis in a changing environment. FEMS microbiology reviews, 27(2-3), 197-213. Solomon, E. I., Heppner, D. E., Johnston, E. M., Ginsbach, J. W., Cirera, J., Qayyum, M., ... & Tian, L. (2014). Copper active sites in biology. Chemical reviews, 114(7), 3659-3853. Tseng, T. T., Gratwick, K. S., Kollman, J., Park, D., Nies, D. H., Goffeau, A., & Saier Jr, M. H. (1999). The RND permease superfamily: an ancient, ubiquitous and diverse family that includes human disease and development proteins. Journal of molecular microbiology and biotechnology, 1(1), 107-125. Xiao, M., Zhu, X., Fan, F., Xu, H., Tang, J., Qin, Y., ... & Zhang, X. (2017). Osmotolerance in Escherichia coli is improved by activation of copper efflux genes or supplementation with sulfur containing amino acids. Applied and environmental microbiology, AEM-03050. Yoneyama, H., & Nakae, T. (1996). Protein C (OprC) of the outer membrane of Pseudomonas aeruginosa is a copper-regulated channel protein. Microbiology, 142(8), 2137-2144.