15 research outputs found
Crystal packing of Bmlp6.
No full text<p>The asymmetric unit of Bmlp6 (shown with unit cell outline) is composed of five protein molecules, A–E, represented by different colors.</p
Alignment of sequences corresponding to Bmlp6.
No full text<p>Amino acid sequence alignment of Bmlp6 (UniProt: A7LIK7; NCBI-Protein: NP_001095198), PBMHPC-23 (UniProt: P09338), PBMHPC-12 (UniPtot: P09335) and Bmlp6_SilkDB (SilkDB: BGIBMGA004457) calculated in ClustalW (<a href="http://www.ebi.ac.uk/Tools/msa/clustalw2/" target="_blank">http://www.ebi.ac.uk/Tools/msa/clustalw2/</a>). The alignment is colored according to identity (dark blue) and similarity (light blue) using Jalview (<a href="http://www.jalview.org/" target="_blank">http://www.jalview.org/</a>) <a href="http://www.plosone.org/article/info:doi/10.1371/journal.pone.0108761#pone.0108761-Waterhouse1" target="_blank">[60]</a>. The evident sequencing error at the C-terminus of Bmlp6_SilkDB (highlighted in dark red, starting from position 194) has been disregarded in sequence similarity calculations. The only discrepancy between Bmlp6 (UniProt: A7LIK7) and the amino acid sequence determined by X-ray crystallography is indicated by white font, at position 217. The N-terminal sequence of Bmlp6 established by Edman degradation is boxed. The displayed sequences correspond to mature proteins without signal peptides.</p
Electrostatic surface potential of Bmlp6, Bmlp7 and Bmlp3 at pH 6.5.
No full text<p>Electrostatic surface potential of Bmlp6, Bmlp7 and Bmlp3 was calculated using the <i>APBS</i> algorithm <a href="http://www.plosone.org/article/info:doi/10.1371/journal.pone.0108761#pone.0108761-Baker1" target="_blank">[52]</a> and the <i>PDB2PQR</i> program <a href="http://www.plosone.org/article/info:doi/10.1371/journal.pone.0108761#pone.0108761-Dolinsky1" target="_blank">[53]</a>, <a href="http://www.plosone.org/article/info:doi/10.1371/journal.pone.0108761#pone.0108761-Dolinsky2" target="_blank">[54]</a> at pH 6.5, which is the physiological pH of silkworm hemolymph. The protein surfaces are shown in the same orientation, in two different views for each protein. The positive and negative charges are colored blue and red, respectively, according to the scale. The <i>APBS</i> writes out the electrostatic potential in dimensionless units of k<sub>b</sub>Te<sub>c</sub><sup>−1</sup> where k<sub>b</sub> is Boltzmann's constant, T is the temperature of calculation and e<sub>c</sub> is the charge of an electron <a href="http://www.plosone.org/article/info:doi/10.1371/journal.pone.0108761#pone.0108761-Baker1" target="_blank">[52]</a>.</p
Electron density maps of Bmlp6.
No full text<p>(A, B) <i>Fo-Fc</i> and <i>2Fo-Fc</i> electron density maps (contour 5.0 σ and 1.0 σ, respectively), unequivocally demonstrate that residue 217 of Bmlp6 (green) is not Tyr but Asn. (C) <i>2Fo-Fc</i> electron density map (contour 1.0 σ) of a loop (residues 161–170) containing disulfide bridge is presented to illustrate that electron density maps were of a very good quality also at the loop regions. For both fragments the molecule A was arbitrary chosen.</p
Diffraction data collection and refinement statistics.
No full texta<p>Values in parentheses are for the highest resolution shell.</p>b<p><i>R<sub>merge</sub></i> = ∑<sub>h</sub>∑<sub>j</sub> | I<sub>hj</sub> - h> |/∑<sub>h</sub>∑<sub>j</sub> I<sub>hj</sub>, where I<sub>hj</sub> is the intensity of observation j of reflection h.</p>c<p><i>R<sub>work</sub></i> = ∑<sub>h</sub> | | F<sub>o</sub>| - | F<sub>c</sub>| |/∑<sub>h</sub> | F<sub>o</sub>| for all reflections, where F<sub>o</sub> and F<sub>c</sub> are observed and calculated structure factors, respectively. <i>R<sub>free</sub></i> is calculated analogously for the test reflections, randomly selected and excluded from the refinement.</p><p>Diffraction data collection and refinement statistics.</p
Potential binding sites of Bmlp3 and Bmlp6.
No full text<p>Potential binding sites of Bmlp3 (blue/pink) and of Bmlp6 (green/yellow) were marked as No. 1–4 and Po.1–2, respectively. Two different views of Bmlp6 are shown to present both cavities.</p
Potential binding sites of the Bmlp6 protein.
No full text<p>Potential binding sites of the Bmlp6 protein.</p
Structural comparison of Bmlp3-p21, Bmlp3-c2 and Bmlp7.
No full text<p>The structures of Bmlp3-p21 (chain A), Bmlp3-c2 (chains A and B) and Bmlp7 (chain A) were Cα-superposed using COOT <a href="http://www.plosone.org/article/info:doi/10.1371/journal.pone.0061303#pone.0061303-Emsley1" target="_blank">[28]</a>, <a href="http://www.plosone.org/article/info:doi/10.1371/journal.pone.0061303#pone.0061303-Emsley2" target="_blank">[29]</a>. The main deviations are found in the CTD domain, in loop conformation. The most flexible loop and the N-terminus are encircled.</p
Crystal packing of Bmlp3-p21 and Bmlp3-c2.
No full text<p>Four protein molecules (shades of blue) are present in the asymmetric unit of Bmlp3-p21 (A), whereas the asymmetric unit of Bmlp3-c2 (B) contains a dimeric assembly (red and pink). Symmetry-related molecules are shown in gray.</p
Biophysical parameters for the Bmlp3 and Bmlp7 proteins calculated using ProtParam (http://web.expasy.org/protparam/).
No full text<p>Biophysical parameters for the Bmlp3 and Bmlp7 proteins calculated using ProtParam (<a href="http://web.expasy.org/protparam/" target="_blank">http://web.expasy.org/protparam/</a>).</p
