| Literature DB >> 24531462 |
Vadim Rimsa1, Thomas C Eadsforth1, Robbie P Joosten2, William N Hunter1.
Abstract
A potential cytosolic metallocarboxypeptidase fromEntities:
Keywords: carboxypeptidases; metalloproteins; refinement; specificity; zinc enzymes
Mesh:
Substances:
Year: 2014 PMID: 24531462 PMCID: PMC3940198 DOI: 10.1107/S1399004713026801
Source DB: PubMed Journal: Acta Crystallogr D Biol Crystallogr ISSN: 0907-4449
Figure 1Investigating the quaternary structure of BcCCP. A gel-filtration chromatogram for BcCCP is displayed on the left. The protein eluted with an apparent molecular mass of 140 kDa as calculated from a previously determined calibration curve. Native PAGE analysis of purified BcCCP is shown on the right. The 4–16% native PAGE (Novex) gel shows protein (lane 1) and molecular-mass standards (lane 2; labelled in kDa).
Crystallographic statistics
Values in parentheses are for the highest resolution shell.
| Space group |
|
| Unit-cell parameters (Å) |
|
| Resolution (Å) | 40–1.90 (2.00–1.90) |
| No. of reflections recorded | 516512 (74589) |
| Unique reflections | 124234 (17924) |
| Completeness (%) | 99.9 (100.0) |
| Multiplicity | 4.2 (4.2) |
| 〈 | 8.4 (2.7) |
| Wilson | 13.3 |
| Radiation source and beamline | ID23-2, ESRF |
| Wavelength (Å) | 0.873 |
| Residues | |
| Subunit | 2–156, 159–383 |
| Subunit | 2–318, 320–384 |
| Subunit | 2–156, 159–314, 320–384 |
| Subunit | 1–315, 320–384 |
| No. of waters | 1062 |
| No. of glycerol molecules | 9 |
| No. of ethylene glycol molecules | 7 |
| No. of PEG molecules | 1 |
| No. of Cl− ions | 3 |
| No. of Zn2+ ions | 4 |
| No. of acetate ions | 4 |
|
| 13.0 (48.4) |
|
| 16.4/20.5 |
| Mean | |
| Subunits | 6.7 |
| Ligands and waters | 26.2 |
| Cruickshank DPI | 0.13 |
| Ramachandran plot | |
| Most favoured (%) | 96.9 |
| Additional allowed (%) | 2.9 |
| Outliers (%) | 0.2 |
| Deviations from ideal values | |
| R.m.s.d., bond lengths (Å) | 0.01 |
| R.m.s. | 0.56 |
| R.m.s.d., bond angles (°) | 1.14 |
| R.m.s. | 0.62 |
R merge = , where I (hkl) is the intensity of the ith measurement of reflection hkl and 〈I(hkl)〉 is the mean value of I (hkl) for all i measurements.
R work = , where F obs is the observed structure factor and F calc is the calculated structure factor.
R free is the same as R work except calculated with a subset (5%) of data that were excluded from refinement calculations.
Diffraction-component precision index (Cruickshank, 1999 ▶).
Chen et al. (2010 ▶).
Engh & Huber (1991 ▶).
Figure 2SEC–MALS analysis of BcCCP. The horizontal blue line corresponds to the calculated mass of BcCCP, which was determined to be 174 kDa. The theoretical mass of a monomer is 45.3 kDa; thus SEC–MALS indicates the presence of a tetramer.
Figure 3The tetramer of BcCCP. The protein is displayed as a semi-transparent van der Waals surface over the ribbon cartoon. Subunits are labelled A (yellow), B (green), C (cyan) and D (blue). Asterisks mark the positions of disordered loops.
Figure 4The interfaces between subunits A and B (a) and subunits A and C (b) in the tetramer. The secondary-structure elements which contain residues contributing to tetramer formation are labelled. The N- and C-termini are labelled and the disordered loops are marked with asterisks. The dashed line points to the N-terminal end, which is located at the back and is not visible in the cartoon.
Figure 5(a) The secondary and tertiary structure of BcCCP. A ribbon diagram of subunit A showing α-helices coloured magenta and β-strands coloured orange, with Zn2+ depicted as a grey sphere. The N- and C-terminal positions are labelled, as are the α-helices and β-strands. A small section of a loop (residues 157 and 158, marked with black asterisks), as well as the first and last residues at the N- and C-termini, are absent from the model owing to disorder. (b) The primary and secondary structure of BcCCP. Residues that are strictly or highly conserved in BcCCP, BmCCP, SdCCP, PaCCP and CeCCPP-6 are shown on black and grey backgrounds, respectively. Three residues that coordinate Zn2+ are marked with yellow stars. The three motifs of the N-terminal domain which are conserved in CCP members are enclosed by green boxes.
Figure 6Stereoview Cα trace showing the superposition of BcCCP (black) with bovine CP-A (red; PDB entry 6cpa). The α6–α7 loop of BcCCP is drawn in cyan. The active-site Zn2+ is shown as a grey sphere and a loop that remains disordered in BcCCP is marked with two asterisks.
Figure 7The conserved Asn-Pro-Asp-Gly motif. The left panel shows the residues in stick representation and selected hydrogen-bonding interactions as dashed black lines. The Asn-Pro-Asp-Gly residues are shown in cyan. The right panel shows a ribbon diagram of a subunit to indicate the position of this motif with respect to the overall fold.
Figure 8Three motifs common to the CCP family: motif I (marine), motif II (orange) and motif III (purple). The active-site Zn2+ is shown as a grey sphere and the three conserved motifs of the N-terminal domain that are found in all M14D family members are shown in marine and are labelled accordingly.
Figure 9The active-site cavity of BcCCP. The protein is depicted as a semi-transparent van der Waals surface over the ribbon cartoon. The surface is coloured according to atom type: C, white; O, red; N, blue. Zn2+ is shown as a grey sphere. Key contributors to the formation of the active site and the S1′ pocket are labelled.
Figure 10The active site and Zn2+ coordination in BcCCP. Selected residues in the active site and acetate are displayed and coloured as follows: C, white (yellow for acetate); O, red; N, blue. The 2F o − F c electron-density map is shown for acetate, where F o represents the observed structure factors and F c represents the calculated structure factors. The map is depicted at the 1σ level (cyan chicken wire). The cation and a water ligand are shown as spheres coloured grey and marine, respectively. Zinc coordination is shown by black continuous lines; blue dashed lines represent hydrogen-bonding interactions.
Figure 11A comparison of the BcCCP and bovine CP-A active sites. The coordinates of CP-A were those of PDB entry 6cpa and the figure is based on the superposition shown in Fig. 2 ▶. Residue side chains are depicted as sticks with atomic positions coloured red for O, blue for N and green for C for bovine CP-A or all in cyan for BcCCP. The Cα atom of Gly253 of CP-A is shown as a small black sphere. The catalytic cations are shown as overlapping grey spheres.
Figure 12The flexible α6–α7 loop. The BcCCP and BmCCP (PDB entry 3k2k) subunit structures are overlaid and the Cα trace for residues 315–326 is shown in green and blue, respectively. The side chains of Lys319 and Tyr320 are shown as sticks.