| Literature DB >> 29559664 |
Sean D Workman1, Liam J Worrall1, Natalie C J Strynadka2.
Abstract
Undecaprenyl pyrophosphate phosphatase (UppP) is an integral membrane protein that recycles theEntities:
Mesh:
Substances:
Year: 2018 PMID: 29559664 PMCID: PMC5861054 DOI: 10.1038/s41467-018-03547-8
Source DB: PubMed Journal: Nat Commun ISSN: 2041-1723 Impact factor: 14.919
Data collection and refinement statistics
| EtHgPO4 UppP | Native UppP | |
|---|---|---|
|
| ||
| Space group | ||
| Cell dimensions | ||
| 111.19, 146.84, 40.20 | 110.05, 146.19, 40.23 | |
| α, β, γ (°) | 90, 90, 90 | 90, 90, 90 |
| Wavelength | 1.0057 | 0.9795 |
| Resolution (Å) | 40.20–3.00 (3.11–3.00) | 44.56–2.00 (2.07–2.00) |
| 0.1663 (0.942) | 0.1083 (1.434) | |
| 14.38 (2.91) | 8.11 (1.25) | |
| Completeness (%) | 99.70 (99.28) | 95.58 (69.75) |
| Redundancy | 12.1 (11.9) | 5.7 (4.0) |
|
| ||
| Resolution (Å) | 44.56–2.00 (2.07–2.00) | |
| No. reflections | 21,713 | |
| 0.22/0.25 | ||
| No. atoms | ||
| Protein | 2080 | |
| Ligand/ion | 145 | |
| Water | 44 | |
| Protein | 44.78 | |
| Ligand/ion | 67.20 | |
| Water | 41.54 | |
| R.m.s deviations | ||
| Bond lengths (Å) | 0.006 | |
| Bond angles (°) | 1.02 |
Values in parentheses are for highest-resolution shell
Fig. 1The crystal structure of EcUppP at 2.0 Å resolution. a Cartoon representation of EcUppP dimer with one monomer-colored rainbow from the N- (blue) to C-terminal (red). Aromatic and positively charged residues at the membrane interface shown as stick and highlight orientation with respect to the inner membrane (shown as gray bars). Two monoolein lipids at the dimer interface shown as stick. b Ninety-degree rotation from a viewed from periplasm. Colored as a and helices numbered. Twofold pseudosymmetry axis parallel to the plane of the membrane shown as gray dotted line. c Electrostatic surface potential of UppP monomer. Orientations as in a and b, respectively. Dotted circles indicate location of periplasmic substrate-binding cleft. d Secondary structure topology highlighting interlocked inverted repeat
Fig. 2The EcUppP substrate-binding pocket. a Clipped view of the EcUppP substrate-binding pocket from a periplasmic viewpoint showing the electronegative funnel and deep hydrophobic channel leading into the positively charge basin formed by the antiparallel inverted reentrant helices defining the active site. An observed monoolein lipid is shown in stick with the polar headgroup bound in the active site pocket and lipid tail exiting the cleft along the hydrophobic channel. b Magnified view of the EcUppP active site with key catalytic residues shown in stick. Two modeled active site waters are shown as cyan and green spheres representing the proposed catalytic water and a putative cation-binding site, respectively. c His30 forms structural hydrogen bonds with the backbones amides of Val25 and Ser26, as well as the hydroxyl oxygen of Tyr260. d Arg261 is buried at the membrane midplane (also see Supplementary Fig. 6) and forms a hydrogen-bonding network that links both reentrant loops (RE Loop 1/2) through the backbone amides of Pro24, Gly171, and F172, in addition to α5 through the backbone amide of Leu126
Fig. 3Conservation of EcUppP catalytic core. a EcUppP structure colored according to sequence conservation from low (cyan) to high (maroon). Highly conserved residues cluster near the catalytic core of the protein. Monoolein displayed in transparent gray. b Top-down view of the active site, showing the highly conserved nature of residues implicated in catalysis (E17, E21, S27, and R174) and maintenance of the reentrant loop architecture (S26, S173, and S175). c Magnification of strictly conserved proline residues that facilitate the bending of α4a and α8 to create the cleft that gives access to the active site
Fig. 4Modeling of C55-PP in the EcUppP active site a. Overlay of the C55-PP pyrophosphate on the observed monoolein headgroup illustrates the coordination of the pyrophosphate by the N termini of α2 and α7. b Overlay of the C55-PP on the observed monoolein headgroup highlighting the interaction network of the key catalytic residues Ser27 (nucleophile), Glu21 (base), Glu17 (carboxyl–carboxylate pair), Arg174 (coordinates beta-phosphate). c Observed coordination sphere of a bound water we propose may represent a potential binding site for the requisite catalytic cation. The overlaid pyrophosphate would contribute two ligands and a favorable electronegative stabilization to the bound metal. d Overlay of wild-type (blue) and S27A mutant (gray) crystal structures show that the active site architecture is not perturbed by the S27A mutation. To confirm the identity the S27A mutant, the wild-type model was refined against the S27A data and an mFo-DFc map was calculated to show the negative difference peak for the Ser27 side chain hydroxyl (contoured at 3σ)