Colicin Ia

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Colicin Ia is a type of Colicin, a bacteriocin made by E. coli which acts against other nearby E. coli to kill them by forming a voltage-dependent channel in the inner membrane of the cells that it targets.

Synthesis and releaseSynthesis and release

Colicin Ia is a 69kDa protein encoded on a high molecular weight plasmid[1] that is induced by the SOS system during stress[2]. The gene is tightly linked to its specific Colicin Immunity Protein, Iia, to protect the colicinogenic cell from the cytotoxic activity of the colicin[3]. The gene goes not encode a lysis protein, like Colicin V for its release from the cell, instead it uses export proteins already present to push itself out of the cell and not destroy it.

Mechanism of uptakeMechanism of uptake

Structure showing the receptor binding domain of ColIa bound to its 70kDa outer membrane receptor (PDB entry 2hdi)

Drag the structure with the mouse to rotate

The flexible[4] N terminus of ColIa is responsible for binding to the colicin I receptor (Cir), which is a TonB-dependent transporter. Its normal function on E. coli is binding and transporting Fe3+ across the outer membrane, but is parasitized by colicins for their transport and entry. When ColIa binds to Cir it results in a big conformational change, resulting in Cir being open and exposed extracellularly, with the ColIa R-domain positioned directly above it, bound at approximately 45o to the membrane. This results in the T and C domains remaining far above the membrane and away from the receptor. If Cir is indeed the molecule that transports ColIa across the membrane, this conformational change is that that would be required for penetration by the colicin[5].

The entry mechanism for ColIa into the periplasm after receptor binding is still unclear. The pair of α helices that separate the T and C domains from the R domain was suggested to allow ColIa to span the membrane, with the R domain being left outside the cell. The C domain is the only one expected to pass across the inner membrane and enter the cytoplasm[6]. Alternatively the 45o angle made with the membrane may allow the ColIa to search the surrounding regions for a co-transporter or other method of entry to the cell. For killing by ColIa to be successful, Cir requires a functional TonB box sequence, as does ColIa, which implies that an interaction with TonB is required for uptake of ColIa[7].

ColIa has been shown to transport cargo proteins on its N terminus across the lipid bilayer when it penetrates the target cell. This transport uses the voltage across the bilayer to bring the folded proteins across the membrane[8].

Killing ActivitiesKilling Activities

The Pore Formation domain, once it has translocated across the periplasmic space, inserts into the inner membrane of the target E. coli and forms a voltage-dependent ion channel that opens at a positive potential and closes at a negative potential, and conduct cations and anions[9]. ColIa transfers a region of itself containing 4 α helices across the membrane as part of its gating[10].

The structural and mechanical sides of the pore formation by ColIa is an enigma; structurally there isn't enough protein to form such a pore, and mechanically the gating involves the transmembrane movement of a large portion of the protein, but it is unclear how this senses the voltage or forms the pore.

ReferencesReferences

  1. Waters VL, Crosa JH. Colicin V virulence plasmids. Microbiol Rev. 1991 Sep;55(3):437-50. PMID:1943995
  2. Mankovich JA, Hsu CH, Konisky J. DNA and amino acid sequence analysis of structural and immunity genes of colicins Ia and Ib. J Bacteriol. 1986 Oct;168(1):228-36. PMID:3531169
  3. Braun V, Patzer SI, Hantke K. Ton-dependent colicins and microcins: modular design and evolution. Biochimie. 2002 May-Jun;84(5-6):365-80. PMID:12423780
  4. Macdonald CJ, Tozawa K, Collins ES, Penfold CN, James R, Kleanthous C, Clayden NJ, Moore GR. Characterisation of a mobile protein-binding epitope in the translocation domain of colicin E9. J Biomol NMR. 2004 Sep;30(1):81-96. PMID:15452437 doi:10.1023/B:JNMR.0000042963.71790.19
  5. Buchanan SK, Lukacik P, Grizot S, Ghirlando R, Ali MM, Barnard TJ, Jakes KS, Kienker PK, Esser L. Structure of colicin I receptor bound to the R-domain of colicin Ia: implications for protein import. EMBO J. 2007 May 16;26(10):2594-604. Epub 2007 Apr 26. PMID:17464289
  6. Stroud RM, Reiling K, Wiener M, Freymann D. Ion-channel-forming colicins. Curr Opin Struct Biol. 1998 Aug;8(4):525-33. PMID:9729746
  7. Buchanan SK, Lukacik P, Grizot S, Ghirlando R, Ali MM, Barnard TJ, Jakes KS, Kienker PK, Esser L. Structure of colicin I receptor bound to the R-domain of colicin Ia: implications for protein import. EMBO J. 2007 May 16;26(10):2594-604. Epub 2007 Apr 26. PMID:17464289
  8. Slatin SL, Nardi A, Jakes KS, Baty D, Duche D. Translocation of a functional protein by a voltage-dependent ion channel. Proc Natl Acad Sci U S A. 2002 Feb 5;99(3):1286-91. PMID:11830660 doi:10.1073/pnas.022480199
  9. Schein SJ, Kagan BL, Finkelstein A. Colicin K acts by forming voltage-dependent channels in phospholipid bilayer membranes. Nature. 1978 Nov 9;276(5684):159-63. PMID:740032
  10. Slatin SL, Duche D, Kienker PK, Baty D. Gating movements of colicin A and colicin Ia are different. J Membr Biol. 2004 Nov;202(2):73-83. PMID:15702371 doi:10.1007/s00232-004-0720-9

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