research papers
Complete and highly redundant data sets were collected at different wavelengths between 0.80 and 2.65 Å for a total of ten different protein and DNA model systems. The magnitude of the anomalous signal-to-noise ratio as assessed by the quotient Ranom/Rr.i.m. was found to be influenced by the data-collection wavelength and the nature of the anomalously scattering substructure. By utilizing simple empirical correlations, for instance between the estimated ΔF/F and the expected Ranom or the data-collection wavelength and the expected Rr.i.m., the wavelength at which the highest anomalous signal-to-noise ratio can be expected could be estimated even before the experiment. Almost independent of the nature of the anomalously scattering substructure and provided that no elemental X-ray absorption edge is nearby, this optimal wavelength is 2.1 Å.
Supporting information
Portable Document Format (PDF) file https://doi.org/10.1107/S0907444905021475/dz5049sup1.pdf |
PDB references: ConA-Xe, 2a7a, r2a7asf; adaptin-Xe, 2a7b, r2a7bsf; PPE-Xe, 2a7c, r2a7csf; HEL-Xe, 2a7d, r2a7dsf; DNA, 2a7e, r2a7esf; HEL, 2a7f, r2a7fsf; thermolysin, 2a7g, r2a7gsf; trypsin, 2a7h, r2a7hsf; thaumatin, 2a7i, r2a7isf; PPE-Ca, 2a7j, r2a7jsf