Lipid II explained

Lipid II is a precursor molecule in the synthesis of the cell wall of bacteria. It is a peptidoglycan, which is amphipathic and named for its bactoprenol hydrocarbon chain, which acts as a lipid anchor, embedding itself in the bacterial cell membrane. Lipid II must translocate across the cell membrane to deliver and incorporate its disaccharide-pentapeptide "building block" into the peptidoglycan mesh. Lipid II is the target of several antibiotics.

A number of analogous compounds are produced via a similar pathway in some bacteria, giving rise to cell wall modifications. See EC 2.4.1.227 for more information.[1]

Synthesis

In peptidoglycan biosynthetic pathway

Lipid II is the final intermediate in peptidoglycan synthesis. It is formed when the MurG transferase catalyzes addition of N-acetylglucosamine (GlcNAc) to Lipid I, resulting in a complete disaccharide-pentapeptide monomer with a bactoprenol-pyrophosphate anchor. This occurs on the inside of the cytoplasmic membrane, where the bactoprenol chain is embedded in the inner leaflet of the bilayer. Lipid II is then transported across the membrane by a flippase, to expose the disaccharide-pentapeptide monomer, which is the pentapeptide stem consisting of L-Ala-γ-D-Glu-m-DAP-D-Ala-D-Ala between GlcNAc and N-acetylmuramic acid (MurNAc), for polymerization and cross-linking into peptidoglycan. The remaining bactoprenol-pyrophosphate is then recycled to the interior of the membrane. Lipid II has been referred to as the "shuttle carrier" of peptidoglycan "building blocks'.[2]

The essential MurJ flippase that translocates lipid II across the cytoplasmic membrane was only published in July 2014, after decades of searching.[3] The discovery remains somewhat controversial as assay results are conflicting; FtsW (EC 2.4.1.129) was proposed as an alternative, with evidence strongly favoring the MurJ side since 2019.[4]

Artificial production

A method for artificial production of lipid II has been described. For synthesis of lipid II from UDP-MurNAc pentapeptide and undecaprenol, the enzymes MraY, MurG, and undecaprenol kinase can be used.[5] Synthetic Lipid II analogues are used in experiments studying how it interacts with and binds molecules.[6] Significant quantities of the important peptidoglycan precursor have also be isolated, following accumulation in bacterial cells.[7]

Functions

Polymers of lipid II form a linear glycan chain. This reaction is catalyzed by the glycosyltransferases of family 51 (GT51). Transpeptidases cross link the chains and form a net-like peptidoglycan macromolecule. The resulting glycopeptide is an essential part of the envelope of many bacteria. Lipid II was estimated to exist at a concentration of less than 2000 molecules per bacterial cell.[8]

Lipid II biosynthesis is functional and essential even in organisms without a cell wall like Chlamydia and Wolbachia. It has been hypothesized that maintaining lipid II biosynthesis reflects its role in prokaryotic cell division.[9] In the discovery and mechanism of assembly of pili in gram positive bacteria Lipid II has been implicated as a crucial structural molecule. It anchors the pili during or after polymerization of the pilus components.[10]

Antibiotics

Since Lipid II must be flipped outside the cytoplasmic membrane before incorporation of its disaccharide-peptide unit into peptidoglycan, it is a relatively accessible target for antibiotics. These antibiotics fight bacteria by either directly inhibiting the peptidoglycan synthesis, or by binding to lipid II to form destructive pores in the cytoplasmic membrane.[11] Examples of antibiotics that target Lipid II include:

Binding

The D-Ala-D-Ala terminus is used by glycopeptide antibiotic vancomycin to inhibit lipid I- and lipid II-consuming peptidoglycan synthesis; in vancomycin-resistant strains vancomycin cannot bind, because a crucial hydrogen bond is lost. Oritavancin also uses the D-Ala-D-Ala terminus, but in addition it uses the crossbridge and D-iso-glutamine in position 2 of the lipid II stem peptide, as present in a number of Gram-positive pathogens, like staphylococci and enterococci. The increased binding of oritavancin through amidation of lipid II can compensate for the loss of a crucial hydrogen bond in vancomycin-resistant strains,[14]

Lantibiotics recognize lipid-II by its pyrophosphate.[2]

Lipid II interacts with human alpha defensins, a class of antimicrobial peptides, such as Defensin, alpha 1. The latter has been used to describe and predict binding of synthetic low-molecular weight compounds created as possible therapeutic agents in treating of Gram-positive infections.[15]

Penicillin-binding protein 4 exchanges d-amino acids into Lipid II (and Lipid I), acting as a transpeptidase in vitro.[16]

Notes and References

  1. Web site: MetaCyc EC 2.4.1.227 . biocyc.org.
  2. Anton Chugunov. Darya Pyrkova. Dmitry Nolde. Anton Polyansky. Vladimir Pentkovsky. Roman Efremov. Lipid-II forms potential "landing terrain" for lantibiotics in simulated bacterial membrane. Sci. Rep.. Apr 16, 2013. 3. 1678. 10.1038/srep01678. 23588060. 3627190. 2013NatSR...3E1678C.
  3. Lok-To Sham. Emily K. Butler. Matthew D. Lebar. MurJ is the flippase of lipid-linked precursors for peptidoglycan biogenesis. Science . 11 July 2014. 345. 6193. 220–222. 10.1126/science.1254522. etal. 25013077. 4163187. 2014Sci...345..220S.
  4. Web site: TCDB 2.A.66.4.3 . tcdb.org.
  5. Huang LY, Huang SH, Chang YC, Cheng WC, Cheng TJ, Wong CH. Enzymatic synthesis of lipid II and analogues.. Angew Chem Int Ed Engl. 28 July 2014. 53. 31. 8060–5. 10.1002/anie.201402313. 24990652.
  6. New Insights into Nisin's Antibacterial Mechanism Revealed by Binding Studies with Synthetic Lipid II Analogues. . t Hart P, Oppedijk S, Breukink E, Martin NI . Biochemistry . 2016 . 55 . 1 . 232–7 . 10.1021/acs.biochem.5b01173 . 26653142.
  7. Lipid II overproduction allows direct assay of transpeptidase inhibition by b-lactams. . Qiao Y, Srisuknimit V, Rubino F, Schaefer K, Nuiz R, Walker S, Kahne D . Nature Chemical Biology . 2017 . 13 . 7 . 793–798 . 10.1038/nchembio.2388 . 28553948. 5478438 .
  8. Y. van Heijenoort. M. Gomez. M. Derrien. J. Ayala. J. van Heijenoort. Membrane intermediates in the peptidoglycan metabolism of Escherichia coli: possible roles of PBP 1b and PBP 3.. J. Bacteriol.. 1992. 174. 11. 3549–3557. 10.1128/jb.174.11.3549-3557.1992. 1592809. 206040.
  9. Henrichfreise B, Schiefer A, Schneider T . Functional conservation of the lipid II biosynthesis pathway in the cell wall-less bacteria Chlamydia and Wolbachia: why is lipid II needed?. Mol Microbiol. September 2009. 73. 5. 913–23. 10.1111/j.1365-2958.2009.06815.x. 19656295. etal. free.
  10. Pili in Gram-positive pathogens, Nature, vol 4, pg 513
  11. Heijenoort J. Lipid Intermediates in the Biosynthesis of Bacterial Peptidoglycan. Microbiol Mol Biol Rev. 10.1128/MMBR.00016-07. 18063720. December 2007. 71. 4. 620–635. 2168651.
  12. de Kruijff B, van Dam V, Breukink E. Lipid II: A central component in bacterial cell wall synthesis and a target for antibiotics. Prostaglandins Leukot Essent Fatty Acids. 12 November 2008. 19008088. 10.1016/j.plefa.2008.09.020. 79. 3–5. 117–21. 1874/33263. free.
  13. Gerard. Wright. Antibiotics: An irresistible newcomer . . 517. 7535. 7 January 2015 . 25561172. 10.1038/nature14193 . 442–444. 2015Natur.517..442W. 4464402. free.
  14. Münch D, Engels I, Müller A, Reder-Christ K, Falkenstein-Paul H, Bierbaum G, Grein F, Bendas G, Sahl HG, Schneider T. Structural variations of the cell wall precursor lipid II - Influence on binding and activity of the lipoglycopeptide antibiotic oritavancin. Antimicrobial Agents and Chemotherapy. 10.1128/AAC.02663-14. 17 November 2014. 59. 2. 772–781. 25403671. 4335874.
  15. Varney KM, Bonvin AM, Pazgier M. Turning defense into offense: defensin mimetics as novel antibiotics targeting lipid II.. PLOS Pathog. 2013. 9. 11. e1003732. 10.1371/journal.ppat.1003732. 3820767. 24244161. etal . free .
  16. Qiao Y, Lebar MD, Schirner K, Schaefer K, Tsukamoto H, Kahne D, Walker S. Detection of lipid-linked peptidoglycan precursors by exploiting an unexpected transpeptidase reaction.. J Am Chem Soc. 22 October 2014. 136. 42. 14678–81. 10.1021/ja508147s. 25291014. 4210121.