Your search keyword '"Sardis MF"' showing total 15 results

1. A role for the Gram-negative outer membrane in bacterial shape determination.

Author

Fivenson EM, Rohs PDA, Vettiger A, Sardis MF, Torres G, Forchoh A, and Bernhardt TG

Subjects

Cell Membrane, Cytoskeleton, Cell Cycle, Escherichia coli genetics, Peptidoglycan, Lipopolysaccharides, Cell Wall

Abstract

The cell envelope of Gram-negative bacteria consists of three distinct layers: the cytoplasmic membrane, a cell wall made of peptidoglycan (PG), and an asymmetric outer membrane (OM) composed of phospholipid in the inner leaflet and lipopolysaccharide (LPS) glycolipid in the outer leaflet. The PG layer has long been thought to be the major structural component of the envelope protecting cells from osmotic lysis and providing them with their characteristic shape. In recent years, the OM has also been shown to be a load-bearing layer of the cell surface that fortifies cells against internal turgor pressure. However, whether the OM also plays a role in morphogenesis has remained unclear. Here, we report that changes in LPS synthesis or modification predicted to strengthen the OM can suppress the growth and shape defects of Escherichia coli mutants with reduced activity in a conserved PG synthesis machine called the Rod complex (elongasome) that is responsible for cell elongation and shape determination. Evidence is presented that OM fortification in the shape mutants restores the ability of MreB cytoskeletal filaments to properly orient the synthesis of new cell wall material by the Rod complex. Our results are therefore consistent with a role for the OM in the propagation of rod shape during growth in addition to its well-known function as a diffusion barrier promoting the intrinsic antibiotic resistance of Gram-negative bacteria.

Published

2023

2. A role for the Gram-negative outer membrane in bacterial shape determination.

Author

Fivenson EM, Rohs PDA, Vettiger A, Sardis MF, Torres G, Forchoh A, and Bernhardt TG

Abstract

The cell envelope of Gram-negative bacteria consists of three distinct layers: the cytoplasmic membrane, a cell wall made of peptidoglycan (PG), and an asymmetric outer membrane (OM) composed of phospholipid in the inner leaflet and lipopolysaccharide (LPS) glycolipid in the outer leaflet. The PG layer has long been thought to be the major structural component of the envelope protecting cells from osmotic lysis and providing them with their characteristic shape. In recent years, the OM has also been shown to be a load-bearing layer of the cell surface that fortifies cells against internal turgor pressure. However, whether the OM also plays a role in morphogenesis has remained unclear. Here, we report that changes in LPS synthesis or modification predicted to strengthen the OM can suppress the growth and shape defects of Escherichia coli mutants with reduced activity in a conserved PG synthesis machine called the Rod system (elongasome) that is responsible for cell elongation and shape determination. Evidence is presented that OM fortification in the shape mutants restores the ability of MreB cytoskeletal filaments to properly orient the synthesis of new cell wall material by the Rod system. Our results are therefore consistent with a role for the OM in the propagation of rod shape during growth in addition to its well-known function as a diffusion barrier promoting the intrinsic antibiotic resistance of Gram-negative bacteria., Significance: The cell wall has traditionally been thought to be the main structural determinant of the bacterial cell envelope that resists internal turgor and determines cell shape. However, the outer membrane (OM) has recently been shown to contribute to the mechanical strength of Gram-negative bacterial envelopes. Here, we demonstrate that changes to OM composition predicted to increase its load bearing capacity rescue the growth and shape defects of Escherichia coli mutants defective in the major cell wall synthesis machinery that determines rod shape. Our results therefore reveal a previously unappreciated role for the OM in bacterial shape determination in addition to its well-known function as a diffusion barrier that protects Gram-negative bacteria from external insults like antibiotics.

Published

2023

3. Preproteins couple the intrinsic dynamics of SecA to its ATPase cycle to translocate via a catch and release mechanism.

Author

Krishnamurthy S, Sardis MF, Eleftheriadis N, Chatzi KE, Smit JH, Karathanou K, Gouridis G, Portaliou AG, Bondar AN, Karamanou S, and Economou A

Subjects

Bacterial Proteins metabolism, Cell Membrane metabolism, Escherichia coli metabolism, Protein Conformation, Protein Sorting Signals physiology, SEC Translocation Channels metabolism, Adenosine Triphosphatases metabolism, Biological Transport physiology, Escherichia coli Proteins metabolism, Membrane Transport Proteins metabolism, SecA Proteins metabolism

Abstract

Protein machines undergo conformational motions to interact with and manipulate polymeric substrates. The Sec translocase promiscuously recognizes, becomes activated, and secretes >500 non-folded preprotein clients across bacterial cytoplasmic membranes. Here, we reveal that the intrinsic dynamics of the translocase ATPase, SecA, and of preproteins combine to achieve translocation. SecA possesses an intrinsically dynamic preprotein clamp attached to an equally dynamic ATPase motor. Alternating motor conformations are finely controlled by the γ-phosphate of ATP, while ADP causes motor stalling, independently of clamp motions. Functional preproteins physically bridge these independent dynamics. Their signal peptides promote clamp closing; their mature domain overcomes the rate-limiting ADP release. While repeated ATP cycles shift the motor between unique states, multiple conformationally frustrated prongs in the clamp repeatedly "catch and release" trapped preprotein segments until translocation completion. This universal mechanism allows any preprotein to promiscuously recognize the translocase, usurp its intrinsic dynamics, and become secreted., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2022 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2022

4. The LpoA activator is required to stimulate the peptidoglycan polymerase activity of its cognate cell wall synthase PBP1a.

Author

Sardis MF, Bohrhunter JL, Greene NG, and Bernhardt TG

Subjects

Bacterial Outer Membrane Proteins genetics, Cross-Linking Reagents metabolism, Escherichia coli Proteins genetics, Lipoproteins genetics, Penicillin-Binding Proteins genetics, Peptidoglycan Glycosyltransferase genetics, Bacterial Outer Membrane Proteins metabolism, Cell Wall enzymology, Cross-Linking Reagents chemistry, Escherichia coli enzymology, Escherichia coli Proteins metabolism, Lipoproteins metabolism, Penicillin-Binding Proteins metabolism, Peptidoglycan metabolism, Peptidoglycan Glycosyltransferase metabolism

Abstract

A cell wall made of the heteropolymer peptidoglycan (PG) surrounds most bacterial cells. This essential surface layer is required to prevent lysis from internal osmotic pressure. The class A penicillin-binding proteins (aPBPs) play key roles in building the PG network. These bifunctional enzymes possess both PG glycosyltransferase (PGT) and transpeptidase (TP) activity to polymerize the wall glycans and cross-link them, respectively. In Escherichia coli and other gram-negative bacteria, aPBP function is dependent on outer membrane lipoproteins. The lipoprotein LpoA activates PBP1a and LpoB promotes PBP1b activity. In a purified system, the major effect of LpoA on PBP1a is TP stimulation. However, the relevance of this activation to the cellular function of LpoA has remained unclear. To better understand why PBP1a requires LpoA for its activity in cells, we identified variants of PBP1a from E. coli and Pseudomonas aeruginosa that function in the absence of the lipoprotein. The changes resulting in LpoA bypass map to the PGT domain and the linker region between the two catalytic domains. Purification of the E. coli variants showed that they are hyperactivated for PGT but not TP activity. Furthermore, in vivo analysis found that LpoA is necessary for the glycan synthesis activity of PBP1a in cells. Thus, our results reveal that LpoA exerts a much greater control over the cellular activity of PBP1a than previously appreciated. It not only modulates PG cross-linking but is also required for its cognate synthase to make PG glycans in the first place., Competing Interests: The authors declare no competing interest., (Copyright © 2021 the Author(s). Published by PNAS.)

Published

2021

5. Long-Lived Folding Intermediates Predominate the Targeting-Competent Secretome.

Author

Tsirigotaki A, Chatzi KE, Koukaki M, De Geyter J, Portaliou AG, Orfanoudaki G, Sardis MF, Trelle MB, Jørgensen TJD, Karamanou S, and Economou A

Subjects

Hydrophobic and Hydrophilic Interactions, Models, Molecular, Protein Domains, Protein Folding, Protein Transport, Proteins metabolism, Protein Sorting Signals, Proteins chemistry

Abstract

Secretory preproteins carry signal peptides fused amino-terminally to mature domains. They are post-translationally targeted to cross the plasma membrane in non-folded states with the help of translocases, and fold only at their final destinations. The mechanism of this process of postponed folding is unknown, but is generally attributed to signal peptides and chaperones. We herein demonstrate that, during targeting, most mature domains maintain loosely packed folding intermediates. These largely soluble states are signal peptide independent and essential for translocase recognition. These intermediates are promoted by mature domain features: residue composition, elevated disorder, and reduced hydrophobicity. Consequently, a mature domain folds slower than its cytoplasmic structural homolog. Some mature domains could not evolve stable, loose intermediates, and hence depend on signal peptides for slow folding to the detriment of solubility. These unique features of secretory proteins impact our understanding of protein trafficking, folding, and aggregation, and thus place them in a distinct class., (Copyright © 2018 Elsevier Ltd. All rights reserved.)

Published

2018

6. Preprotein Conformational Dynamics Drive Bivalent Translocase Docking and Secretion.

Author

Sardis MF, Tsirigotaki A, Chatzi KE, Portaliou AG, Gouridis G, Karamanou S, and Economou A

Subjects

Adenosine Triphosphatases genetics, Adenosine Triphosphatases metabolism, Bacterial Proteins genetics, Bacterial Proteins metabolism, Binding Sites, Protein Binding, SEC Translocation Channels genetics, SEC Translocation Channels metabolism, SecA Proteins, Adenosine Triphosphatases chemistry, Bacterial Proteins chemistry, Molecular Docking Simulation, SEC Translocation Channels chemistry

Abstract

Most bacterial secretory proteins destined beyond the plasma membrane are secreted post-translationally by the Sec translocase. In the first step of translocation, preproteins are targeted for binding to their 2-site receptor SecA, the peripheral ATPase subunit of the translocase. We now reveal that secretory preproteins use a dual-key mechanism to bridge the signal peptide and mature domain receptor sites and cooperatively enhance their affinities. Docking of targeting-competent mature domains requires that their extensive disorder is finely tuned. This is achieved through amino-terminal mature domain regions acting as conformational rheostats. By being linked to the rheostats, signal peptides regulate long-range preprotein disorder. Concomitant conformational changes in SecA sterically adapt its two receptor sites to optimally recognize hundreds of dissimilar preproteins. This novel intramolecular conformational crosstalk in the preprotein chains and the dynamic interaction with their receptor are mechanistically coupled to preprotein engagement in the translocase and essential for secretion., (Copyright © 2017 Elsevier Ltd. All rights reserved.)

Published

2017

7. Preprotein mature domains contain translocase targeting signals that are essential for secretion.

Author

Chatzi KE, Sardis MF, Tsirigotaki A, Koukaki M, Šoštarić N, Konijnenberg A, Sobott F, Kalodimos CG, Karamanou S, and Economou A

Subjects

Escherichia coli cytology, Protein Domains, SecA Proteins, Adenosine Triphosphatases metabolism, Bacterial Proteins metabolism, Escherichia coli metabolism, Escherichia coli Proteins chemistry, Escherichia coli Proteins metabolism, Protein Sorting Signals, SEC Translocation Channels metabolism

Abstract

Secretory proteins are only temporary cytoplasmic residents. They are typically synthesized as pre proteins, carrying signal peptides N-terminally fused to their mature domains. In bacteria secretion largely occurs posttranslationally through the membrane-embedded SecA-SecYEG translocase. Upon crossing the plasma membrane, signal peptides are cleaved off and mature domains reach their destinations and fold. Targeting to the translocase is mediated by signal peptides. The role of mature domains in targeting and secretion is unclear. We now reveal that mature domains harbor their own independent targeting signals (mature domain targeting signals [MTSs]). These are multiple, degenerate, interchangeable, linear or 3D hydrophobic stretches that become available because of the unstructured states of targeting-competent preproteins. Their receptor site on the cytoplasmic face of the SecYEG-bound SecA is also of hydrophobic nature and is located adjacent to the signal peptide cleft. Both the preprotein MTSs and their receptor site on SecA are essential for protein secretion. Evidently, mature domains have their own previously unsuspected distinct roles in preprotein targeting and secretion., (© 2017 Chatzi et al.)

Published

2017

8. Rapid label-free quantitative analysis of the E. coli BL21(DE3) inner membrane proteome.

Author

Papanastasiou M, Orfanoudaki G, Kountourakis N, Koukaki M, Sardis MF, Aivaliotis M, Tsolis KC, Karamanou S, and Economou A

Subjects

Chromatography, Liquid, Escherichia coli cytology, Proteolysis, Proteomics, Tandem Mass Spectrometry, Escherichia coli chemistry, Escherichia coli Proteins analysis, Proteome analysis

Abstract

Biological membranes define cells and cellular compartments and are essential in regulating bidirectional flow of chemicals and signals. Characterizing their protein content therefore is required to determine their function, nevertheless, the comprehensive determination of membrane-embedded sub-proteomes remains challenging. Here, we experimentally characterized the inner membrane proteome (IMP) of the model organism E. coli BL21(DE3). We took advantage of the recent extensive re-annotation of the theoretical E. coli IMP regarding the sub-cellular localization of all its proteins. Using surface proteolysis of IMVs with variable chemical treatments followed by nanoLC-MS/MS analysis, we experimentally identified ∼45% of the expressed IMP in wild type E. coli BL21(DE3) with 242 proteins reported here for the first time. Using modified label-free approaches we quantified 220 IM proteins. Finally, we compared protein levels between wild type cells and those over-synthesizing the membrane-embedded translocation channel SecYEG proteins. We propose that this proteomics pipeline will be generally applicable to the determination of IMP from other bacteria., (© 2015 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2016

9. Identification of small-molecule inhibitors against SecA by structure-based virtual ligand screening.

Author

De Waelheyns E, Segers K, Sardis MF, Anné J, Nicolaes GA, and Economou A

Subjects

Ligands, Membrane Transport Proteins, SEC Translocation Channels, SecA Proteins, Adenosine Triphosphatases antagonists & inhibitors, Anti-Bacterial Agents pharmacology, Bacterial Proteins antagonists & inhibitors, Drug Evaluation, Preclinical

Abstract

The rapid rise of antibiotic-resistant bacteria is one of the major concerns in modern medicine. Therefore, to treat bacterial infections, there is an urgent need for new antibacterials-preferably directed against alternative bacterial targets. One such potential target is the preprotein translocation motor SecA. SecA is a peripheral membrane ATPase and a key component of the Sec secretion pathway, the major route for bacterial protein export across or into the cytoplasmic membrane. As SecA is essential for bacterial viability, ubiquitous and highly conserved in bacteria, but not present in eukaryotic cells, it represents an attractive antibacterial target. Using an in silico approach, we have defined several potentially druggable and conserved pockets on the surface of SecA. We show that three of these potentially druggable sites are important for SecA function. A starting collection of ~500 000 commercially available small-molecules was virtually screened against a predicted druggable pocket in the preprotein-binding domain of Escherichia coli SecA using a multi-step virtual ligand screening protocol. The 1040 top-scoring molecules were tested in vitro for inhibition of the translocation ATPase activity of E. coli SecA. Five inhibitors of the translocation ATPase, and not of basal or membrane ATPase, were identified with IC50 values <65 μm. The most potent inhibitor showed an IC50 of 24 μm. The antimicrobial activity was determined for the five most potent SecA inhibitors. Two compounds were found to possess weak antibacterial activity (IC50 ~198 μm) against E. coli, whereas some compounds showed moderate antibacterial activity (IC50 ~100 μm) against Staphylococcus aureus.

Published

2015

10. SecA-mediated targeting and translocation of secretory proteins.

Author

Chatzi KE, Sardis MF, Economou A, and Karamanou S

Subjects

Adenosine Triphosphatases genetics, Bacterial Proteins genetics, Cell Membrane metabolism, Escherichia coli metabolism, Escherichia coli Proteins genetics, Membrane Transport Proteins genetics, Molecular Motor Proteins metabolism, Protein Binding, SEC Translocation Channels, SecA Proteins, Adenosine Triphosphatases metabolism, Bacterial Proteins metabolism, Escherichia coli Proteins metabolism, Membrane Transport Proteins metabolism, Protein Transport genetics

Abstract

More than 30 years of research have revealed that the dynamic nanomotor SecA is a central player in bacterial protein secretion. SecA associates with the SecYEG channel and transports polypeptides post-translationally to the trans side of the cytoplasmic membrane. It comprises a helicase-like ATPase core coupled to two domains that provide specificity for preprotein translocation. Apart from SecYEG, SecA associates with multiple ligands like ribosomes, nucleotides, lipids, chaperones and preproteins. It exerts its essential contribution in two phases. First, SecA, alone or in concert with chaperones, helps mediate the targeting of the secretory proteins from the ribosome to the membrane. Next, at the membrane it converts chemical energy to mechanical work and translocates preproteins through the SecYEG channel. SecA is a highly dynamic enzyme, it exploits disorder-order kinetics, swiveling and dissociation of domains and dimer to monomer transformations that are tightly coupled with its catalytic function. Preprotein signal sequences and mature domains exploit these dynamics to manipulate the nanomotor and thus achieve their export at the expense of metabolic energy. This article is part of a Special Issue entitled: Protein trafficking and secretion in bacteria. Guest Editors: Anastassios Economou and Ross Dalbey., (Copyright © 2014 Elsevier B.V. All rights reserved.)

Published

2014

11. Quaternary dynamics of the SecA motor drive translocase catalysis.

Author

Gouridis G, Karamanou S, Sardis MF, Schärer MA, Capitani G, and Economou A

Subjects

Adenosine Triphosphate metabolism, Catalysis, Dimerization, Escherichia coli genetics, Escherichia coli metabolism, Hydrolysis, Mutation, Protein Binding, Protein Conformation, Protein Subunits genetics, Protein Subunits metabolism, Protein Transport, SEC Translocation Channels, SecA Proteins, Adenosine Triphosphatases genetics, Adenosine Triphosphatases metabolism, Bacterial Proteins genetics, Bacterial Proteins metabolism, Membrane Transport Proteins genetics, Membrane Transport Proteins metabolism

Abstract

Most secretory preproteins exit bacterial cells through the protein translocase, comprising the SecYEG channel and the dimeric peripheral ATPase motor SecA. Energetic coupling to work remains elusive. We now demonstrate that translocation is driven by unusually dynamic quaternary changes in SecA. The dimer occupies several successive states with distinct protomer arrangements. SecA docks on SecYEG as a dimer and becomes functionally asymmetric. Docking occurs via only one protomer. The second protomer allosterically regulates downstream steps. Binding of one preprotein signal peptide to the SecYEG-docked SecA protomer elongates the SecA dimer and triggers the translocase holoenzyme to obtain a lower activation energy conformation. ATP hydrolysis monomerizes the triggered SecA dimer, causing mature chain trapping and processive translocation. This is a unique example of one protein exploiting quaternary dynamics to become a substrate receptor, a "loading clamp," and a "processive motor." This mechanism has widespread implications on protein translocases, chaperones, and motors., (Copyright © 2013 Elsevier Inc. All rights reserved.)

Published

2013

12. The Escherichia coli peripheral inner membrane proteome.

Author

Papanastasiou M, Orfanoudaki G, Koukaki M, Kountourakis N, Sardis MF, Aivaliotis M, Karamanou S, and Economou A

Subjects

Chromatography, Liquid, Membrane Proteins analysis, Nanotechnology methods, Tandem Mass Spectrometry, Cell Membrane metabolism, Escherichia coli metabolism, Escherichia coli Proteins analysis, Proteome analysis, Proteomics methods

Abstract

Biological membranes are essential for cell viability. Their functional characteristics strongly depend on their protein content, which consists of transmembrane (integral) and peripherally associated membrane proteins. Both integral and peripheral inner membrane proteins mediate a plethora of biological processes. Whereas transmembrane proteins have characteristic hydrophobic stretches and can be predicted using bioinformatics approaches, peripheral inner membrane proteins are hydrophilic, exist in equilibria with soluble pools, and carry no discernible membrane targeting signals. We experimentally determined the cytoplasmic peripheral inner membrane proteome of the model organism Escherichia coli using a multidisciplinary approach. Initially, we extensively re-annotated the theoretical proteome regarding subcellular localization using literature searches, manual curation, and multi-combinatorial bioinformatics searches of the available databases. Next we used sequential biochemical fractionations coupled to direct identification of individual proteins and protein complexes using high resolution mass spectrometry. We determined that the proposed cytoplasmic peripheral inner membrane proteome occupies a previously unsuspected ∼19% of the basic E. coli BL21(DE3) proteome, and the detected peripheral inner membrane proteome occupies ∼25% of the estimated expressed proteome of this cell grown in LB medium to mid-log phase. This value might increase when fleeting interactions, not studied here, are taken into account. Several proteins previously regarded as exclusively cytoplasmic bind membranes avidly. Many of these proteins are organized in functional or/and structural oligomeric complexes that bind to the membrane with multiple interactions. Identified proteins cover the full spectrum of biological activities, and more than half of them are essential. Our data suggest that the cytoplasmic proteome displays remarkably dynamic and extensive communication with biological membrane surfaces that we are only beginning to decipher.

Published

2013

13. Breaking on through to the other side: protein export through the bacterial Sec system.

Author

Chatzi KE, Sardis MF, Karamanou S, and Economou A

Subjects

Animals, Humans, Protein Transport physiology, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Cell Membrane metabolism, Cell Membrane microbiology

Abstract

More than one-third of cellular proteomes traffic into and across membranes. Bacteria have invented several sophisticated secretion systems that guide various proteins to extracytoplasmic locations and in some cases inject them directly into hosts. Of these, the Sec system is ubiquitous, essential and by far the best understood. Secretory polypeptides are sorted from cytoplasmic ones initially due to characteristic signal peptides. Then they are targeted to the plasma membrane by chaperones/pilots. The translocase, a dynamic nanomachine, lies at the centre of this process and acts as a protein-conducting channel with a unique property; allowing both forward transfer of secretory proteins but also lateral release into the lipid bilayer with high fidelity and efficiency. This process, tightly orchestrated at the expense of energy, ensures fundamental cell processes such as membrane biogenesis, cell division, motility, nutrient uptake and environmental sensing. In the present review, we examine this fascinating process, summarizing current knowledge on the structure, function and mechanics of the Sec pathway.

Published

2013

14. Using nanoelectrospray ion mobility spectrometry (GEMMA) to determine the size and relative molecular mass of proteins and protein assemblies: a comparison with MALLS and QELS.

Author

Kapellios EA, Karamanou S, Sardis MF, Aivaliotis M, Economou A, and Pergantis SA

Subjects

Chromatography, Gel, Electrophoresis, Ions, Lasers, Light, Models, Molecular, Molecular Weight, Escherichia coli Proteins chemistry, Multiprotein Complexes chemistry, Proteins chemistry, Spectrometry, Mass, Electrospray Ionization methods

Abstract

The determination of protein assembly size and relative molecular mass is currently of great importance in biochemical analysis. In particular, the technique of nanoelectrospray (nES) with a gas-phase electrophoretic mobility molecular analyzer (GEMMA) has received increased attention for such measurements. However, in order for the GEMMA technique to gain broader acceptance in protein analysis, it must be further evaluated and compared with other established bioanalytical techniques. In the present study, nES-GEMMA was evaluated for the analysis of a set of protein and protein complexes involved in the Sec and the bacterial type III secretion pathway of enteropathogenic Escherichia coli bacteria. The same set of proteins, isolated and purified using standard biochemical protocols, were also analyzed using multi-angle laser light scattering (MALLS) and quasi-elastic light scattering (QELS), following size exclusion chromatography. This allowed for direct comparisons between the three techniques. It was found that nES-GEMMA, in comparison to the more established MALLS and QELS techniques, offers several complementary advantages. It requires considerably less amount of material, i.e., nanogram vs. milligram amounts, and time per sample analysis, i.e., few minutes vs. tens of minutes. Whereas the determined size and relative molecular mass are similar between the compared methods, the electrophoretic diameters determined using nES-GEMMA seem to be systematically smaller compared to the hydrodynamic diameter derived by QELS. Some of the GEMMA technique disadvantages include its narrow dynamic range, limited by the fact that at elevated protein concentrations there is increased potential for the occurrence of nES-induced oligomers. Thus, it is preferred to analyze dilute protein solutions because non-specific oligomers are less likely to occur whereas biospecific oligomers remain detected. To further understand the formation of nES-oligomers, the effect of buffer concentration on their formation was evaluated. Also, nES-GEMMA is not compatible with all the buffers commonly used with MALLS and QELS. Overall, however, the nES-GEMMA technique shows promise as a high-throughput proteomics/protein structure tool.

Published

2011

15. SecA: a tale of two protomers.

Author

Sardis MF and Economou A

Subjects

Adenosine Triphosphatases metabolism, Archaeal Proteins metabolism, Bacterial Proteins metabolism, Membrane Transport Proteins metabolism, Models, Molecular, Molecular Sequence Data, Protein Multimerization, Protein Subunits metabolism, SEC Translocation Channels, SecA Proteins, Adenosine Triphosphatases chemistry, Archaeal Proteins chemistry, Bacterial Proteins chemistry, Eukaryota enzymology, Membrane Transport Proteins chemistry, Protein Structure, Quaternary, Protein Subunits chemistry

Abstract

Bacteria, Archaea and Eukaryotes have evolved a plethora of mechanisms to translocate proteins across their various membranes. The bacterial Sec pathway is ubiquitous and essential for cell viability and is used by most proteins destined for the inner membrane, the periplasm or beyond. In bacteria, Sec system components include the heterotrimers SecY/SecE/SecG and SecD/SecF/YajC and the peripherally associated ATPase motor SecA. SecA in solution is mainly dimeric. Unexpectedly, structures of SecA dimers from different or even the same bacterium do not have a consistent dimerization interface. Analysis of the functional assembled translocase complexes blurs the picture even further as the functional quaternary state of the SecYEG channel is also disputed. Several experimental approaches tried to define the oligomeric state of SecA during preprotein 'pushing' through SecYEG. One high-resolution SecA-SecYEG complex has been visualized. This snapshot might be a step closer to the actual translocating machinery. Nevertheless, because of the use of detergent, the true quartenary state of the translocase might have been disturbed. Hence, even after this and other studies, several issues remain puzzling. New approaches must be combined with current tools to gain insight into the functionally relevant quartenary states of SecA and SecYEG during preprotein translocation.

Published

2010