Extension of the transferable aspherical pseudoatom data bank for the comparison of molecular electrostatic potentials in structure–activity studies

Kumar, Prashant; Gruza, Barbara; Bojarowski, Sławomir A.; Dominiak, Paulina M.

doi:10.1107/s2053273319000482

“…Generally, the IAM potential is too positive in both, the electron pair regions and in the covalent bonding regions, and not positive enough in the regions surrounding the polar hydrogen atoms. All the observations are similar to these we already noted among many other organic molecules (Kumar et al, 2019).…”

Section: Models Of Electrostatic Potentialsupporting

confidence: 91%

“…It incorporates the IAM and TAAM models of X-ray or electron scattering factors available in DiSCaMB library (Chodkiewicz et al, 2018) (Cowley et al, 2006) was used. To parametrize TAAM, the newest version (Kumar et al, 2019) of the UBDB databank (Volkov, Li et al, 2004;Dominiak et al, 2007;Jarzembska & Dominiak, 2012) was used together with LSDB (Volkov, Li et al, 2004). The parameters were transferred after first cycles of the IAM refinements done during structure solution step.…”

Section: Structure Refinementmentioning

confidence: 99%

“…Therefore it was possible to build a databank of different types of pseudoatoms and to use the databank to generate a transferable aspherical atom model (TAAM) parameters for any organic molecule, up to and including proteins and nucleic acids. There are three major pseudoatom databanks available at the moment: ELMAM2 (Zarychta et al, 2007;Domagała & Jelsch, 2008;Domagała et al, 2011Domagała et al, , 2012, the Invariom database called GID (Dittrich et al, 2006(Dittrich et al, , 2013 and the University at Buffalo Pseudoatom Databank (UBDB) (Koritsanszky et al, 2002;Volkov, Li et al, 2004;Dominiak et al, 2007;Jarzembska & Dominiak, 2012;Kumar et al, 2019). They differ principally in the sources used to define the pseudoatom parameters and in the method by which atom types are defined.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Refinement of Organic Crystal Structure with Multipolar Electron Scattering Factors

Gruza¹,

Chodkiewicz²,

Krzeszczakowska³

et al. 2019

Preprint

Self Cite

0

View full text Add to dashboard Cite

A revolution in resolution is occurring now in electron microscopy arising from the development of methods for imaging single particles at cryogenic temperatures and obtaining electron diffraction data from nanocrystals of small organic molecules or macromolecules. Near- atomic or even atomic resolution of molecular structures can be achieved. The basis of these methods is the scattering of an electron beam due to the electrostatic potential of the sample. To analyze this high-quality experimental data, it is necessary to use appropriate atomic scattering factors. The independent atomic model (IAM) is commonly used although various more advanced models, already known from X-ray diffraction, can also be applied to enhance the analysis.<br>In this study we present a comparison of IAM and TAAM (Transferable Aspherical Atom Model), the latter with the parameters of the Hansen-Coppens multipole model transferred from the University at Buffalo Databank (UBDB). By this method, TAAM takes into account the fact that atoms in molecules are partially charged and are not spherical. We performed structure refinements on a carbamazepine crystal using electron structure factor amplitudes determined experimentally (Jones et al., 2018) or modeled with theoretical quantum-mechanical methods. The results show the possibilities and limitations of the TAAM method when applied to electron diffraction. Among others, the method clearly improves model fitting statistics, when compared to IAM, and allows for reliable refinement of atomic thermal parameters. The improvements are more pronounced with poorer resolution of diffraction data.<br>

show abstract

“…The electrostatic potential V(r) of a molecule always confirms a significant role in guiding its reactive behavior. For biological as well as organic molecules, MESP gives significant descriptions for such molecules and considered excellent descriptors for their possible interactions [23][24][25][26][27][28][29][30][31].…”

Section: Introductionmentioning

confidence: 99%

Mapping molecular electrostatic potential for heme interacting with nano metal oxides

2020

Biointerface Res Appl Chem

View full text Add to dashboard Cite

Interacting various living components with several materials in the gaseous nanoscale form has been of great concern as they are utilized in different life aspects. This work is conducted to assess the impact of interacting heme molecule, the main constituent of blood hemoglobin, with various common and non-common divalent molecules such as O2, CO2, CO, MgO, CoO, NiO, CuO and ZnO. Calculations are calculated at DFT high theoretical level using B3LYP/SDD method. In addition, molecular electrostatic potential (MESP) maps are constructed. Results demonstrate that interacting heme with proposed various structures lowers their energies reflecting more stability. However, the addition of non-familiar species to heme makes it more stable that may affect its transportation function for O2 and CO2 in the presence of these toxic materials in the gaseous state. The calculated TDM of the various proposed structures indicates that they are all more reactive than heme, since TDM of all of them are larger than that of pure heme. MESP maps show that extreme negative electrostatic regions are concentrated around C=O group of terminal carboxyl groups suggesting electrophilic interactions to take place there while positive regions are found around Fe central atom and on the circumference of all the proposed structures that are occupied by H atoms increasing the probability of nucleophilic reactions in these regions. Therefore, presence of such hazardous materials in the gaseous nanoscale may impact negatively the transportation function of heme.

show abstract

“…Since 2005 we have been involved in the development of the UBDB (Kumar et al, 2019;Jarzembska & Dominiak, 2012;Dominiak et al, 2007). Currently the UBDB contains atom-types occurring in proteins, nucleic acids and many organic molecules.…”

Section: Introductionmentioning

confidence: 99%

Refinement of Organic Crystal Structure with Multipolar Electron Scattering Factors

Gruza¹,

Chodkiewicz²,

Krzeszczakowska³

et al. 2019

Preprint

Self Cite

View full text Add to dashboard Cite

A revolution in resolution is occurring now in electron microscopy arising from the development of methods for imaging single particles at cryogenic temperatures and obtaining electron diffraction data from nanocrystals of small organic molecules or macromolecules. Near- atomic or even atomic resolution of molecular structures can be achieved. The basis of these methods is the scattering of an electron beam due to the electrostatic potential of the sample. To analyze this high-quality experimental data, it is necessary to use appropriate atomic scattering factors. The independent atomic model (IAM) is commonly used although various more advanced models, already known from X-ray diffraction, can also be applied to enhance the analysis.<br>In this study we present a comparison of IAM and TAAM (Transferable Aspherical Atom Model), the latter with the parameters of the Hansen-Coppens multipole model transferred from the University at Buffalo Databank (UBDB). By this method, TAAM takes into account the fact that atoms in molecules are partially charged and are not spherical. We performed structure refinements on a carbamazepine crystal using electron structure factor amplitudes determined experimentally (Jones et al., 2018) or modeled with theoretical quantum-mechanical methods. The results show the possibilities and limitations of the TAAM method when applied to electron diffraction. Among others, the method clearly improves model fitting statistics, when compared to IAM, and allows for reliable refinement of atomic thermal parameters. The improvements are more pronounced with poorer resolution of diffraction data.<br>

show abstract

Extension of the transferable aspherical pseudoatom data bank for the comparison of molecular electrostatic potentials in structure–activity studies

Cited by 37 publications

References 90 publications

Refinement of Organic Crystal Structure with Multipolar Electron Scattering Factors

Refinement of Organic Crystal Structure with Multipolar Electron Scattering Factors

Mapping molecular electrostatic potential for heme interacting with nano metal oxides

Refinement of Organic Crystal Structure with Multipolar Electron Scattering Factors

Contact Info

Product

Resources

About