Transmembrane transport of peptidoglycan precursors across model and bacterial membranes (original) (raw)
Related papers
Journal of Biological Chemistry, 2003
The mechanism by which phospholipids are transported across biogenic membranes, such as the bacterial cytoplasmic membrane, is unknown. We hypothesized that this process is mediated by the presence of the membrane-spanning segments of inner membrane proteins, rather than by dedicated flippases. In support of the hypothesis, it was demonstrated that transmembrane ␣-helical peptides, mimicking the membrane-spanning segments, mediate flop of 2-6-(7-nitro-2,1,3-benzoxadiazol-4-yl) aminocaproyl C 6 -NBD)-phospholipids (Kol, M. A., de Kroon, A. I., Rijkers, D. T., Killian, J. A., and de Kruijff, B. (2001) Biochemistry 40, 10500 -10506). Here the dithionite reduction assay was used to measure transbilayer equilibration of C 6 -NBD-phospholipids in proteoliposomes, composed of Escherichia coli phospholipids and a subset of bacterial membrane proteins. It is shown that two well characterized integral proteins of the bacterial cytoplasmic membrane, leader peptidase and the potassium channel KcsA, induce phospholipid translocation, most likely by their transmembrane domains. In contrast, the ATP-binding cassette transporter from the E. coli inner membrane MsbA, a putative lipid flippase, did not mediate phospholipid translocation, irrespective of the presence of ATP. OmpT, an outer membrane protein from E. coli, did not facilitate flop either, demonstrating specificity of protein-mediated phospholipid translocation. The results are discussed in the light of phospholipid transport across the E. coli inner membrane.
Biochimica Et Biophysica Acta-biomembranes, 1996
In this study we have investigated the transmembrane movement of short chain fluorescently labeled phospholipids across the inner membrane of Escherichiu coli. Exogenously added C,-NBD-labeled phospholipids rapidly flip across the inner membrane of E. coli, as was shown by a dithionite reduction assay applied to inverted inner membrane vesicles (IIMV) isolated from wild type E. coli cells. The rate of transmembrane movement of the phospholipid probes incorporated into IIMV is temperature dependent, and shows no phospholipid head group specificity. C,-NBD-labeled phospholipids translocate across the membrane of IIMV incubated at 37°C with a r,,, of 7 min. After the incorporation into IIMV C,-NBD-PG is partially converted to CL by CL-synthase. If IIMV are pretreated with proteinase K the conversion of this fluorescent probe to C,-NBD-CL is not observed anymore, suggesting that the catalytic domain of CL-synthase is at the cytoplasmic site of the plasma membrane of E. coli. Newly synthesized C,-NBD-CL also flips across the inner membrane although at a slower rate than the other phospholipid probes. The transmembrane movement occurs in both directions and is not influenced by treatment of the IIMV with a sulfhydryl reagent or a proteinase, nor by the presence of ATP, or a ApH across the membrane of the IIMV. However, the transmembrane movement of the C,-NBD-labeled phospholipid probes is not observed in LUVETs (large unilamellar vesicles made by extrusion technique) prepared of wild type E. coli lipids, indicating that the rapid transmembrane movement of phospholipids across the inner membrane of E. coli is a protein-mediated process.
Identification of FtsW as a transporter of lipid-linked cell wall precursors across the membrane
The EMBO Journal, 2011
Bacterial cell growth necessitates synthesis of peptidoglycan. Assembly of this major constituent of the bacterial cell wall is a multistep process starting in the cytoplasm and ending in the exterior cell surface. The intracellular part of the pathway results in the production of the membraneanchored cell wall precursor, Lipid II. After synthesis this lipid intermediate is translocated across the cell membrane. The translocation (flipping) step of Lipid II was demonstrated to require a specific protein (flippase). Here, we show that the integral membrane protein FtsW, an essential protein of the bacterial division machinery, is a transporter of the lipid-linked peptidoglycan precursors across the cytoplasmic membrane. Using Escherichia coli membrane vesicles we found that transport of Lipid II requires the presence of FtsW, and purified FtsW induced the transbilayer movement of Lipid II in model membranes. This study provides the first biochemical evidence for the involvement of an essential protein in the transport of lipid-linked cell wall precursors across biogenic membranes.
The Journal of biological chemistry, 1994
The involvement of phosphatidylglycerol in the SecA-independent translocation of M13 procoat in Escherichia coli was demonstrated. Processing of procoat to mature coat protein was retarded when the level of phosphatidylglycerol was reduced. In vitro translocation experiments using inner membrane vesicles isolated from a strain with inducible synthesis of phosphatidylglycerol, showed that translocation of procoat and of a SecA-dependent procoat analog was proportional to the content of phosphatidylglycerol. Moreover, introduction of phosphatidylglycerol by means of a lipid transfer method into phosphatidylglycerol-depleted inner membrane vesicles, efficiently restored procoat translocation. The phosphatidylglycerol dependence in both the SecA-dependent and -independent translocation pathway indicates that phosphatidylglycerol plays a dual role in translocation. We suggest that besides membrane binding of SecA this lipid has a direct interaction with the M13 procoat in translocation a...
The construction of a mutant Escherichia coli strain which cannot synthesize phosphatidylethanolamine provides a tool to study the involvement of non-bilayer lipids in membrane function. This strain produces phosphatidylglycerol and cardiolipin (CL) as major membrane constituents and requires millimolar concentrations of divalent cations for growth. In this strain, the lipid phase behaviour is tightly regulated by adjustment of the level of CL which favours a nonbilayer organization in the presence of specific divalent cations. We have used an in vitro system of inverted membrane vesicles to study the involvement of nonbilayer lipids in protein translocation in the secretion pathway. In this system, protein translocation is very low in the absence of divalent cations but can be enhanced by inclusion of Mg2+, Ca2+ or Sr2+ but not by Ba2> which is unable to sustain growth of the mutant strain and cannot induce a non-bilayer phase in E.coli CL dispersions. Alternatively, translocation in cation depleted vesicles could be increased by incorporation of the non-bilayer lipid DOPE (18:1) but not by DMPE (14:0) or DOPC (18:1), both of which are bilayer lipids under physiological conditions. We conclude that non-bilayer lipids are essential for efficient protein transport across the plasma membrane of E.coli.
Topology and transport of membrane lipids in bacteria
Biochimica Et Biophysica Acta-reviews on Biomembranes, 2000
The last two decades have witnessed a break-through in identifying and understanding the functions of both the proteins and lipids of bacterial membranes. This development was parallelled by increasing insights into the biogenesis, topology, transport and sorting of membrane proteins. However, progress in research on the membrane distribution and transport of lipids in bacteria has been slow in that period. The development of novel biochemical in vitro approaches and recent genetic studies have increased our understanding of these subjects. The aim of this review is to present an overview of the current knowledge of the distribution and transport of lipids in both Gram-positive and Gram-negative bacteria. Special attention is paid to recently obtained results, which are expected to inspire further research to finally unravel these poorly understood phenomena. ß 0304-4157 / 00 / $^see front matter ß 2000 Elsevier Science B.V. All rights reserved. PII: S 0 3 0 4 -4 1 5 7 ( 9 9 ) 0 0 0 1 4 -3
The EMBO Journal
The construction of a mutant Escherichia coli strain which cannot synthesize phosphatidylethanolamine provides a tool to study the involvement of non-bilayer lipids in membrane function. This strain produces phosphatidylglycerol and cardiolipin (CL) as major membrane constituents and requires millimolar concentrations of divalent cations for growth. In this strain, the lipid phase behaviour is tightly regulated by adjustment of the level of CL which favours a nonbilayer organization in the presence of specific divalent cations. We have used an in vitro system of inverted membrane vesicles to study the involvement of nonbilayer lipids in protein translocation in the secretion pathway. In this system, protein translocation is very low in the absence of divalent cations but can be enhanced by inclusion of Mg2+, Ca2+ or Sr2+ but not by Ba2> which is unable to sustain growth of the mutant strain and cannot induce a non-bilayer phase in E.coli CL dispersions. Alternatively, translocation in cation depleted vesicles could be increased by incorporation of the non-bilayer lipid DOPE (18:1) but not by DMPE (14:0) or DOPC (18:1), both of which are bilayer lipids under physiological conditions. We conclude that non-bilayer lipids are essential for efficient protein transport across the plasma membrane of E.coli.
Journal of Biological Chemistry, 2009
The morphology and curvature of biological bilayers are determined by the packing shapes and interactions of their participant molecules. Bacteria, except photosynthetic groups, usually lack intracellular membrane organelles. Strong overexpression in Escherichia coli of a foreign monotopic glycosyltransferase (named monoglycosyldiacylglycerol synthase), synthesizing a nonbilayer-prone glucolipid, induced massive formation of membrane vesicles in the cytoplasm. Vesicle assemblies were visualized in cytoplasmic zones by fluorescence microscopy. These have a very low buoyant density, substantially different from inner membranes, with a lipid content of >60% (w/w). Cryo-transmission electron microscopy revealed cells to be filled with membrane vesicles of various sizes and shapes, which when released were mostly spherical (diameter ≈100 nm). The protein repertoire was similar in vesicle and inner membranes and dominated by the glycosyltransferase. Membrane polar lipid composition was similar too, including the foreign glucolipid. A related glycosyltransferase and an inactive monoglycosyldiacylglycerol synthase mutant also yielded membrane vesicles, but without glucolipid synthesis, strongly indicating that vesiculation is induced by the protein itself. The high capacity for membrane vesicle formation seems inherent in the glycosyltransferase structure, and it depends on the following: (i) lateral expansion of the inner monolayer by interface binding of many molecules; (ii) membrane expansion through stimulation of phospholipid synthesis, by electrostatic binding and sequestration of anionic lipids; (iii) bilayer bending by the packing shape of excess nonbilayer-prone phospholipid or glucolipid; and (iv) potentially also the shape or penetration profile of the glycosyltransferase binding surface. These features seem to apply to several other proteins able to achieve an analogous membrane expansion.
Specificity of the transport of Lipid II by FtsW in Escherichia coli
Journal of Biological Chemistry, 2014
The mechanism of FtsW-mediated Lipid II transport across the bacterial cytoplasmic membrane is unknown. Results: Transmembrane segment 4 and particularly two charged residues are required for the transport of Lipid II as well as a maximal size of the substrate. Conclusion: Lipid II is specifically transported possibly through a porelike structure. Significance: Elucidating how FtsW acts is crucial for understanding how lipid flippases function in general.