Proposal for new catalytic roles for two invariant residues in Escherichia coli ribonuclease HI.

Three mutants of Escherichia coli ribonuclease HI, in which an invariant acidic residue Asp134 was replaced, were crystallized, and their three-dimensional structures were determined by X-ray crystallography. The D134A mutant is completely inactive, whereas the other two mutants, D134H and D134N, retain 59 and 90% activities relative to the wild-type, respectively. The overall structures of these three mutant proteins are identical with that of the wild-type enzyme, except for local conformational changes of the flexible loops. The ribonuclease H family has a common active site, which is composed of four invariant acidic residues (Asp10, Glu48, Asp70 and Asp134 in E.coli ribonuclease HI), and their relative positions in the mutants, even including the side-chain atoms, are almost the same as those in the wild-type. The positions of the delta-polar atoms at residue 134 in the wild-type, as well as D134H and D134N, coincide well with each other. They are located near the imidazole side chain of His124, which is assumed to participate in the catalytic reaction, in addition to the four invariant acidic residues. Combined with the pH profiles of the enzymatic activities of the two other mutants, H124A and H124A/D134N, the crystallographic results allow us to propose a new catalytic mechanism of ribonuclease H, which includes the roles for Asp134 and His124.

Membrane topology and site-specific mutagenesis of Pseudomonas aeruginosa porin OprD.

Pseudomonas aeruginosa OprD is a 420-amino-acid protein that facilitates the uptake of basic amino acids, imipenem and gluconate across the outer membrane. OprD was the first specific porin that could be aligned with members of the non-specific porin super-family. Utilizing multiple alignments in conjugation with structure predictions and amphipathicity calculations, an OprD-topology model was proposed. Sixteen beta-strands were predicted, connected by short loops at the periplasmic side. The eight external loops were of variable length but tended to be much longer than the periplasmic ones. Polymerase chain reaction (PCR)-based site-specific mutagenesis was performed to delete separately short stretches (4-8 amino acid residues) from each of the predicted external loops. The mutants with deletions in the predicted external loops L1, L2, L5, L6, L7 and L8 were tolerated in both Escherichia coli and P. aeruginosa. The expressed mutant proteins maintained substantial resistance to trypsin treatment in the context of isolated outer membranes. Proteins with deletions in loops L1, L5, L6, L7 and L8 reconstituted similar imipenem supersusceptibility in a P. aeruginosa OprD:: omega background. The L2-deletion mutant only partially reconstituted super-susceptibility, suggesting that loop L2 is involved in imipenem binding. These data were generally consistent with the topology model.

Structural and functional alterations of a colicin-resistant mutant of OmpF porin from Escherichia coli.

A strain of Escherichia coli, selected on the basis of its resistance to colicin N, reveals distinct structural and functional alterations in unspecific OmpF porin. A single mutation [Gly-119-->Asp (G119D)] was identified in the internal loop L3 that contributes critically to the formation of the construction inside the lumen of the pore. X-ray structure analysis to a resolution of 3.0 A reveals a locally altered peptide backbone, with the side chain of residue Asp-119 protruding into the channel, causing the area of the constriction (7 x 11 A in the wild type) to be subdivided into two intercommunicating subcompartments of 3-4 A in diameter. The functional consequences of this structural modification consist of a reduction of the channel conductance by about one-third, of altered ion selectivity and voltage gating, and of a decrease of permeation rates of various sugars by factors of 2-12. The structural modification of the mutant protein affects neither the beta-barrel structure nor those regions of the molecule that are exposed at the cell surface. Considering the colicin resistance of the mutant, it is inferred that in vivo, colicin N traverses the outer membrane through the porin channel or that the dynamics of the exposed loops are affected in the mutant such that these may impede the binding of the toxin.

Diversity of the P2 protein among nontypeable Haemophilus influenzae isolates.

The genes for outer membrane protein P2 of four nontypeable Haemophilus influenzae strains were cloned and sequenced. The derived amino acid sequences were compared with the outer membrane protein P2 sequence from H. influenzae type b MinnA and the sequences of P2 from three additional nontypeable H. influenzae strains. The sequences were 76 to 94% identical. The sequences had regions with considerable variability separated by regions which were highly conserved. The variable regions mapped to putative surface-exposed loops of the protein.

Membrane-bound form of the pore-forming domain of colicin A. A neutron scattering study.

The ion-channel forming C-terminal fragment of colicin A binds to negatively charged lipid vesicles and provides an example of the insertion of a soluble protein into a lipid bilayer. The soluble structure is known and consists of a ten-helix bundle containing a hydrophobic helical hairpin. This fragment forms a well-defined complex with dimyristoylphosphatidyl-glycerol which is thus amenable to neutron scattering studies. Neutron scattering experiments in the Guinier range (low angles) provided the mass and the stoichiometry of the complex (290,000 (+/- 10,000) M(r), 8.2 (+/- 0.5)), in fair agreement with previous determinations. By varying the neutron scattering length density of the solvent with 2H2O/H2O mixtures and therefore the contrast of the different components, the radial distribution of the protein and of the lipids was determined. Finally, an attempt was made to fit various models to the wider angle scattering data. This study suggests that the pore-forming fragment of colicin A lies mostly at the surface of the membrane, with the lipids arranged in a bilayer organization.

Purification of Aeromonas hydrophila major outer-membrane proteins: N-terminal sequence analysis and channel-forming properties.

Four outer-membrane proteins of Aeromonas hydrophila were purified and their N-terminal sequences and channel-forming properties were determined. Three could be matched with proteins from other species. One was a maltoporin, as its level increased when cells were grown in maltose-containing media, and the channel it formed was blocked by maltose. Another was like OmpF and OmpC of Escherichia coli, except that its channel fluctuated much more rapidly. The third protein, which was produced in low-phosphate medium, exhibited several properties of the general anion porin PhoE. The fourth showed no similarity to any known proteins. It had a unique N-terminus and it formed small sharply-defined cation-selective channels. Two other proteins which corresponded to OmpW of Vibrio cholerae and E. coli OmpA were partly characterized.

The bacterial porin superfamily: sequence alignment and structure prediction.

The porins of Gram-negative bacteria are responsible for the 'molecular sieve' properties of the outer membrane. They form large water-filled channels which allow the diffusion of hydrophilic molecules into the periplasmic space. Owing to the strong hydrophilicity of their amino acid sequence and the nature of their secondary structure (beta strands), conventional hydropathy methods for predicting membrane topology are useless for this class of protein. The large number of available porin amino acid sequences was exploited to improve the accuracy of the prediction in combination with tools detecting amphipathicity of secondary structure. Using the constraints of beta-sheet structure these porins are predicted to contain 16 membrane-spanning strands, 14 of which are common to the two (enteric and the neisserial) porin subfamilies.