Daniel Kahne

The Bacterial Cell Envelope

The bacteria cell envelope is a complex multilayered structure that serves to protect these organisms from their unpredictable and often hostile environment. The cell envelopes of most bacteria fall into one of two major groups. Gram-negative bacteria are surrounded by a thin peptidoglycan cell wall, which itself is surrounded by an outer membrane containing lipopolysaccharide. Gram-positive bacteria lack an outer membrane but are surrounded by layers of peptidoglycan many times thicker than is found in the gram-negatives. Threading through these layers of peptidoglycan are long anionic polymers, called teichoic acids. The composition and organization of these envelope layers and recent insights into the mechanisms of cell envelope assembly are discussed.

Identification of a multicomponent complex required for outer membrane biogenesis in Escherichia coli

Gram-negative bacteria have an outer membrane (OM) that functions as a barrier to protect the cell from toxic compounds such as antibiotics and detergents. The OM is a highly asymmetric bilayer composed of phospholipids, glycolipids, and proteins. Assembly of this essential organelle occurs outside the cytoplasm in an environment that lacks obvious energy sources such as ATP, and the mechanisms involved are poorly understood. We describe the identification of a multiprotein complex required for the assembly of proteins in the OM of Escherichia coli. We also demonstrate genetic interactions between genes encoding components of this protein assembly complex and imp, which encodes a protein involved in the assembly of lipopolysaccharides (LPS) in the OM. These genetic interactions suggest a role for YfgL, one of the lipoprotein components of the protein assembly complex, in a homeostatic control mechanism that coordinates the overall OM assembly process.

Advances in understanding bacterial outer-membrane biogenesis.

The outer membrane of Gram-negative bacteria such as Escherichia coli serves as a protective barrier that controls the influx and efflux of solutes. This allows the bacteria to inhabit several different, and often hostile, environments. The assembly of the E. coli outer membrane has been difficult to study using traditional genetic and biochemical methods, and how all its components reach the outer membrane after being synthesized in the cytoplasm and cytoplasmic membrane, how they are assembled in an environment that is devoid of an obvious energy source, and how assembly proceeds without disrupting the integrity of this essential cellular structure are all fundamental questions that remain unanswered. Here, we review the new approaches that have led to the recent discovery of components of the machinery involved in the biogenesis of this distinctive cellular organelle.

Parallel Synthesis and Screening of a Solid Phase Carbohydrate Library

A solid phase carbohydrate library was synthesized and screened against Bauhinia purpurea lectin. The library, which contains approximately 1300 di- and trisaccharides, was synthesized with chemical encoding on TentaGel resin so that each bead contained a single carbohydrate. Two ligands that bind more tightly to the lectin than Gal-β-1,3-GalNAc (the known ligand) have been identified. The strategy outlined can be used to identify carbohydrate-based ligands for any receptor; however, because the derivatized beads mimic the polyvalent presentation of cell surface carbohydrates, the screen may prove especially valuable for discovering new compounds that bind to proteins participating in cell adhesion.

Lipoprotein SmpA is a component of the YaeT complex that assembles outer membrane proteins in Escherichia coli

A major role of the outer membrane (OM) of Gram-negative bacteria is to provide a protective permeability barrier for the cell, and proper maintenance of the OM is required for cellular viability. OM biogenesis requires the coordinated assembly of constituent lipids and proteins via dedicated OM assembly machineries. We have previously shown that, in Escherichia coli, the multicomponent YaeT complex is responsible for the assembly of OM β-barrel proteins (OMPs). This complex contains the OMP YaeT and three OM lipoproteins. Here, we report another component of the YaeT complex, the OM lipoprotein small protein A (SmpA). Strains carrying loss-of-function mutations in smpA are viable but exhibit defects in OMP assembly. Biochemical experiments show that SmpA is involved in maintaining complex stability. Taken together, these experiments establish an important role for SmpA in both the structure and function of the YaeT complex.

β-Barrel Membrane Protein Assembly by the Bam Complex

β-barrel membrane proteins perform important functions in the outer membranes (OMs) of Gram-negative bacteria and of the mitochondria and chloroplasts of eukaryotes. The protein complexes that assemble these proteins in their respective membranes have been identified and shown to contain a component that has been conserved from bacteria to humans. β-barrel proteins are handled differently from α-helical membrane proteins in the cell in order to efficiently transport them to their final locations in unfolded but folding-competent states. The mechanism by which the assembly complex then binds, folds, and inserts β-barrels into the membrane is not well understood, but recent structural, biochemical, and genetic studies have begun to elucidate elements of how the complex provides a facilitated pathway for β-barrel assembly. Ultimately, studies of the mechanism of β-barrel assembly and comparison to the better-understood process of α-helical membrane protein assembly will reveal whether there are general principles that guide the folding and insertion of all membrane proteins.

YfiO stabilizes the YaeT complex and is essential for outer membrane protein assembly in Escherichia coli.

Recent advances in the study of bacterial membranes have led to the identification of a multicomponent YaeT complex in the outer membrane (OM) of Gram‐negative bacteria that is involved in the targeting and folding of β‐barrel outer membrane proteins (OMPs). In Escherichia coli, this complex consists of an essential OMP, YaeT, and three OM lipoproteins, YfgL, NlpB and YfiO. YfiO is the only essential lipoprotein component of the complex. We show that this lipoprotein is required for the proper assembly and/or targeting of OMPs to the OM but not the assembly of lipopolysaccharides (LPS). Depletion of YfiO causes similar phenotypes as does the depletion of YaeT, and we conclude that YfiO plays a critical role in YaeT‐mediated OMP folding. We demonstrate that YfiO and YfgL directly interact with YaeT in vitro, while NlpB interacts directly with YfiO. Genetic analysis verifies the importance of YfiO and its interactions with NlpB in maintaining the functional integrity of the YaeT complex.

Reconstitution of Outer Membrane Protein Assembly from Purified Components

Bring Out the β-Barrel The assembly of β-barrel membrane proteins, which are found in the outer membrane of Gram-negative bacteria and in the mitochondria and chloroplasts of eukaryotes, is poorly understood. Now Hagan et al. (p. 890, published online 8 April; see the Perspective by Stroud et al.) describe the development of a reconstituted system that recapitulates the process of assembly of β-barrel membrane proteins by the Escherichia coli Bam complex. The assembly of a protein substrate required the purified five-protein Bam complex and several subcomplexes and a chaperone, but did not require an external input of energy. Assembly of a β-barrel membrane protein in a cell-free system does not require added energy. β-barrel membrane proteins in Gram-negative bacteria, mitochondria, and chloroplasts are assembled by highly conserved multi-protein complexes. The mechanism by which these molecular machines fold and insert their substrates is poorly understood. It has not been possible to dissect the folding and insertion pathway because the process has not been reproduced in a biochemical system. We purified the components that fold and insert Escherichia coli outer membrane proteins and reconstituted β-barrel protein assembly in proteoliposomes using the enzymatic activity of a protein substrate to report on its folding state. The assembly of this protein occurred without an energy source but required a soluble chaperone in addition to the multi-protein assembly complex.

Transport of lipopolysaccharide across the cell envelope: the long road of discovery

Intracellular lipid transport is poorly understood. Genetic studies to identify lipid-transport factors are complicated by the essentiality of many lipids, whereas biochemical and cell biology approaches aiming to determine localization and mechanisms of lipid transport are often challenged by the lack of adequate technology. Here, we review the epic history of how different approaches, technological advances and ingenuity contributed to the recent discovery of a multi-protein pathway that transports lipopolysaccharide across the envelope of Gram-negative bacteria.

Identification of two inner-membrane proteins required for the transport of lipopolysaccharide to the outer membrane of Escherichia coli

The outer membrane (OM) of most Gram-negative bacteria contains lipopolysaccharide (LPS) in the outer leaflet. LPS, or endotoxin, is a molecule of important biological activities. In the host, LPS elicits a potent immune response, while in the bacterium, it plays a crucial role by establishing a barrier to limit entry of hydrophobic molecules. Before LPS is assembled at the OM, it must be synthesized at the inner membrane (IM) and transported across the aqueous periplasmic compartment. Much is known about the biosynthesis of LPS but, until recently, little was known about its transport and assembly. We applied a reductionist bioinformatic approach that takes advantage of the small size of the proteome of the Gram-negative endosymbiont Blochmannia floridanus to search for novel factors involved in OM biogenesis. This led to the discovery of two essential Escherichia coli IM proteins of unknown function, YjgP and YjgQ, which are required for the transport of LPS to the cell surface. We propose that these two proteins, which we have renamed LptF and LptG, respectively, are the missing transmembrane components of the ABC transporter that, together with LptB, functions to extract LPS from the IM en route to the OM.