Functional mapping of the surface of Escherichia coli ribose-binding protein: mutations that affect chemotaxis and transport.

Ribose-binding protein is a bifunctional soluble receptor found in the periplasm of Escherichia coli. Interaction of liganded binding protein with the ribose high affinity transport complex results in the transfer of ribose across the cytoplasmic membrane. Alternatively, interaction of liganded binding protein with a chemotactic signal transducer, Trg, initiates taxis toward ribose. We have generated a functional map of the surface of ribose-binding protein by creating and analyzing directed mutations of exposed residues. Residues in an area on the cleft side of the molecule including both domains have effects on transport. A portion of the area involved in transport is also essential to chemotactic function. On the opposite face of the protein, mutations in residues near the hinge are shown to affect chemotaxis specifically.     

Promoter engineering to optimize recombinant periplasmic Fab′ fragment production in Escherichia coli

Fab’ fragments have become an established class of biotherapeutic over the last two decades. Likewise, developments in synthetic biology are providing ever more powerful techniques for designing bacterial genes, gene networks and entire genomes that can be used to improve industrial performance of cells used for production of biotherapeutics. We have previously observed significant leakage of an exogenous therapeutic Fab’ fragment into the growth medium during high cell density cultivation of an Escherichia coli production strain. In this study we sought to apply a promoter engineering strategy to address the issue of Fab’ fragment leakage and its consequent bioprocess challenges. We used site directed mutagenesis to convert the P_tac promoter, present in the plasmid, pTTOD‐A33 Fab’, to a P_tic promoter which has been shown by others to direct expression at a 35% reduced rate compared to P_tac. We characterized the resultant production trains in which either P_tic or P_tac promoters direct Fab’ fragment expression. The P_tic promoter strain showed a 25?30% reduction in Fab’ expression relative to the original P_tac strain. Reduced Fab’ leakage and increased viability over the course of a fed‐batch fermentation were also observed for the P_tic promoter strain. We conclude that cell design steps such as the P_tac to P_tic promoter conversion reported here, can yield significant process benefit and understanding with respect to periplasmic Fab’ fragment production. It remains an open question as to whether the influence of transgene expression on periplasmic retention is mediated by global metabolic burden effects or periplasm overcapacity. © 2016 American Institute of Chemical Engineers Biotechnol. Prog., 32:840–847, 2016     

Functional significance of a periplasmic Mn-superoxide dismutase from Aeromonas hydrophila

AIMS: A better understanding of the role of superoxide dismutases (SODs) from Aeromonas hydrophila and particularly the Mn-SOD which shares a peculiar localization within the bacterial periplasm and is only detected during the stationary phase of growth. METHODS AND RESULTS: A. hydrophila ATCC 7966 can express two distinct SODs: an Fe-SOD and an Mn-SOD. Using insertional mutagenesis, an Mn-SOD-deficient mutant was isolated. After growth of this mutant under conditions leading to the expression of an Mn-SOD, only the Fe-SOD could be detected in nondenaturing PAGE. Study of its response to the oxidative stress showed that the Mn-SOD was not implicated in the protection against intracellular superoxide but defended the bacterial cells against environmental superoxide. CONCLUSIONS: By protecting the bacteria against external superoxide, the role of the Mn-SOD from A. hydrophila is equivalent to that of the Cu/Zn-SOD from the well-studied Escherichia coli. SIGNIFICANCE AND IMPACT OF THE STUDY: The function of this Mn-SOD is in agreement with its periplasmic localization and may confer an advantage on the bacteria such as a virulence factor in cases of pathogenicity.     

The crystal structure of TrxA(CACA): Insights into the formation of a [2Fe-2S] iron-sulfur cluster in an Escherichia coli thioredoxin mutant

Escherichia coli thioredoxin is a small monomeric protein that reduces disulfide bonds in cytoplasmic proteins. Two cysteine residues present in a conserved CGPC motif are essential for this activity. Recently, we identified mutations of this motif that changed thioredoxin into a homodimer bridged by a [2Fe-2S] iron-sulfur cluster. When exported to the periplasm, these thioredoxin mutants could restore disulfide bond formation in strains lacking the entire periplasmic oxidative pathway. Essential for the assembly of the iron-sulfur was an additional cysteine that replaced the proline at position three of the CGPC motif. We solved the crystalline structure at 2.3 Angstroms for one of these variants, TrxA(CACA). The mutant protein crystallized as a dimer in which the iron-sulfur cluster is replaced by two intermolecular disulfide bonds. The catalytic site, which forms the dimer interface, crystallized in two different conformations. In one of them, the replacement of the CGPC motif by CACA has a dramatic effect on the structure and causes the unraveling of an extended alpha-helix. In both conformations, the second cysteine residue of the CACA motif is surface-exposed, which contrasts with wildtype thioredoxin where the second cysteine of the CXXC motif is buried. This exposure of a pair of vicinal cysteine residues apparently allows thioredoxin to acquire an iron-sulfur cofactor at its active site, and thus a new activity and mechanism of action.     

Molecular Dynamics Simulations of the Periplasmic Ferric-hydroxamate Binding Protein FhuD

FhuD is a periplasmic binding protein (PBP) that, under iron-limiting conditions, transports various hydroxamate-type siderophores from the outer membrane receptor (FhuA) to the inner membrane ATP-binding cassette transporter (FhuBC). Unlike many other PBPs, FhuD possesses two independently folded domains that are connected by an α-helix rather than two or three central β-strands. Crystal structures of FhuD with and without bound gallichrome have provided some insight into the mechanism of siderophore binding as well as suggested a potential mechanism for FhuD binding to FhuB. Since the α-helix connecting the two domains imposes greater rigidity on the structure relative to the β-strands in other ‘classical’ PBPs, these structures reveal no large conformational change upon binding a hydroxamate-type siderophore. Therefore, it is difficult to explain how the inner membrane transporter FhuB can distinguish between ferrichrome-bound and ferrichrome-free FhuD. In the current study, we have employed a 30 ns molecular dynamics simulation of FhuD with its bound siderophore removed to explore the dynamic behavior of FhuD in the substrate-free state. The MD simulation suggests that FhuD is somewhat dynamic with a C-terminal domain closure of 6° upon release of its siderophore. This relatively large motion suggests differences that would allow FhuB to distinguish between ferrichrome-bound and ferrichrome-free FhuD.     

Crystal structure of a defective folding protein

Maltose-binding protein (MBP or MalE) of Escherichia coli is the periplasmic receptor of the maltose transport system. MalE31, a defective folding mutant of MalE carrying sequence changes Gly 32-->Asp and Ile 33-->Pro, is either degraded or forms inclusion bodies following its export to the periplasmic compartment. We have shown previously that overexpression of FkpA, a heat-shock periplasmic peptidyl-prolyl isomerase with chaperone activity, suppresses MalE31 misfolding. Here, we have exploited this property to characterize the maltose transport activity of MalE31 in whole cells. MalE31 displays defective transport behavior, even though it retains maltose-binding activity comparable with that of the wild-type protein. Because the mutated residues are in a region on the surface of MalE not identified previously as important for maltose transport, we have solved the crystal structure of MalE31 in the maltose-bound state in order to characterize the effects of these changes. The structure was determined by molecular replacement methods and refined to 1.85 A resolution. The conformation of MalE31 closely resembles that of wild-type MalE, with very small displacements of the mutated residues located in the loop connecting the first alpha-helix to the first beta-strand. The structural and functional characterization provides experimental evidence that MalE31 can attain a wild-type folded conformation, and suggest that the mutated sites are probably involved in the interactions with the membrane components of the maltose transport system.     

Structure and Function of the Escherichia coli Tol-Pal Stator Protein TolR

TolR is a 15-kDa inner membrane protein subunit of the Tol-Pal complex in Gram-negative bacteria, and its function is poorly understood. Tol-Pal is recruited to cell division sites where it is involved in maintaining the integrity of the outer membrane. TolR is related to MotB, the peptidoglycan (PG)-binding stator protein from the flagellum, suggesting it might serve a similar role in Tol-Pal. The only structure thus far reported for TolR is of the periplasmic domain from Haemophilus influenzae in which N- and C-terminal residues had been deleted (TolR(62–133), Escherichia coli numbering). H. influenzae TolR(62–133) is a symmetrical dimer with a large deep cleft at the dimer interface. Here, we present the 1.7-Å crystal structure of the intact periplasmic domain of E. coli TolR (TolR(36–142)). E. coli TolR(36–142) is also dimeric, but the architecture of the dimer is radically different from that of TolR(62–133) due to the intertwining of its N and C termini. TolR monomers are rotated ∼180° relative to each other as a result of this strand swapping, obliterating the putative PG-binding groove seen in TolR(62–133). We found that removal of the strand-swapped regions (TolR(60–133)) exposes cryptic PG binding activity that is absent in the full-length domain. We conclude that to function as a stator in the Tol-Pal complex dimeric TolR must undergo large scale structural remodeling reminiscent of that proposed for MotB, where the N- and C-terminal sequences unfold in order for the protein to both reach and bind the PG layer ∼90 Å away from the inner membrane.     

The hitchhiker's guide to the periplasm: Unexpected molecular interactions of polymyxin B1 in E. coli

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Macromolecular crowding in the Escherichia coli periplasm maintains alpha-synuclein disorder

The natively disordered protein alpha-synuclein is the primary component of Lewy bodies, the cellular hallmark of Parkinson's disease. Most studies of this protein are performed in dilute solution, but its biologically relevant role is performed in the crowded environment inside cells. We addressed the effects of macromolecular crowding on alpha-synuclein by combining NMR data acquired in living Escherichia coli with in vitro NMR data. The crowded environment in the E.coli periplasm prevents a conformational change that is detected at 35 degrees C in dilute solution. This change is associated with an increase in hydrodynamic radius and the formation of secondary structure in the N-terminal 100 amino acid residues. By preventing this temperature-induced conformational change, crowding in the E.coli periplasm stabilizes the disordered monomer. We obtain the same stabilization in vitro upon crowding alpha-synuclein with 300 g/l of bovine serum albumin, indicating that crowding alone is sufficient to stabilize the disordered, monomeric protein. Two disease-associated variants (A30P and A53T) behave in the same way in both dilute solution and in the E.coli periplasm. These data reveal the importance of approaching the effects of macromolecular crowding on a case-by-case basis. Additionally, our work shows that discrete structured protein conformations may not be achieved by alpha-synuclein inside cells, implicating the commonly overlooked aspect of macromolecular crowding as a possible factor in the etiology of Parkinson's disease.