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Query: UMLS:C0027960 (
mole
)
21,279
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The extracellular hemoglobin of Lumbricus terrestris (3900 kDa) consists of at least six different polypeptide chains: I through IV (16-19 kDa), V (31 kDa) and IV (37 kDa) (Vinogradov, S.N., Shlom, J.M., Hall, B.C., Kapp, O.H. and Mizukami, H. (1977) Biochim. Biophys. Acta 492, 136-155). SDS-polyacrylamide gel electrophoresis of the unreduced hemoglobin shows that chains II, III and IV form a disulfide-bonded 50 kDa subunit. This subunit was isolated by gel filtration of the hemoglobin on Sephacryl S-200 (a) at neutral pH in 0.1% SDS and (b) in 0.1 M sodium acetate buffer (pH 4.0); in the latter case it retains heme. The 50 kDa subunit obtained by method (b) was reduced and subjected to chromatofocusing on
PBE
94 column: the elution pattern obtained with Polybuffer 74 (pH 4.5) and monitored at 280 nm, consisted of three peaks A, B and C; peaks A and B but not C, had absorbance at 410 nm. SDS-polyacrylamide gel electrophoresis showed that peaks A, B and C corresponded to chains II, IV and III, respectively. Amino acid analyses and N-terminal sequence determinations identified chain II as the whose primary structure had been determined (Garlick, R. and Riggs, A. (1982) J. Biol. Chem. 257, 9005-9015). Carbohydrate analysis of the native hemoglobin shows it to contain 2.0 +/- 0.5% carbohydrate consisting of mannose and N-acetylglucosamine in a
mole
ratio of about 9:1. The carbohydrate content of the 50 kDa subunit is 1.8 +/- 0.5%; it consists of mannose and N-acetylglucosamine in the same ratio and it appears to be associated with chain IV. Rabbit polyclonal antisera to 50 kDa subunit, prepared by method (a), and to the native hemoglobin were shown to cross-react with the hemoglobin and the 50 kDa subunit, respectively, by immunodiffusion. One of eight mouse monoclonal antibodies directed against the native hemoglobin reacted strongly with the 50 kDa subunit prepared by methods (a) and (b) in an enzyme-linked immunosorbent assay (ELISA). Another monoclonal antibody reacted strongly with the 50 kDa subunit obtained by method (b). Neither of the two hybridomas exhibited a strong reaction with any of the three constituent chains of the 50 kDa subunit. These results suggest that the unusual disulfide-bonded 50 kDa subunit, consisting of three myoglobin-like polypeptide chains of which only two have heme, is an integral part of the native Lumbricus hemoglobin molecule.
...
PMID:A disulfide-bonded trimer of myoglobin-like chains is the principal subunit of the extracellular hemoglobin of Lumbricus terrestris. 308 Oct 31
The reaction of equimolar NO with the 16 electron molecule RuHCl(CO)L(2) (L = P(i)Pr(3)) proceeds, via a radical adduct RuHCl(CO)(NO) L(2), onward to form RuCl(NO)(CO)L(2) (X-ray structure determination) and RuHCl(HNO)(CO)L(2), in a 1:1
mole
ratio. The HNO ligand, bound by N and trans to hydride, is rapidly degraded by excess NO. The osmium complex behaves analogously, but the adduct has a higher formation constant, permitting determination of its IR spectrum; both MHCl(CO)(NO)L(2) radicals are characterized by EPR spectroscopy, and DFT calculations on the Ru system show it to have a "half-bent" Ru-N-O unit with the spin density mainly on nitrogen. DFT (
PBE
) energies rule out certain possible mechanistic steps for forming the two products. A survey of the literature leads to the hypothesis that NO should generally be considered as a (neutral) Lewis base (2-electron donor) when it binds to a 16 electron complex which is resistant to oxidation or reduction, and that the resulting N-centered radical has a M-N-O angle of approximately 140 degrees, which distinguishes it from NO(-) (bent at <140 degrees ) and from NO(+) (>170 degrees ).
...
PMID:Reactivity of the hydrido/nitrosyl radical MHCl(NO)(CO)(P(i)Pr(3))(2), M = Ru, Os. 1470 87
We use density functional theory calculations with van der Waals corrections to study the role of dispersive interactions on the structure and binding of CO(2) within two distinct metal-organic frameworks (MOFs): Mg-MOF74 and Ca-BTT. For both classes of MOFs, we report calculations with standard gradient-corrected (
PBE
) and five van der Waals density functionals (vdW-DFs), also comparing with semiempirical pairwise corrections. The vdW-DFs explored here yield a large spread in CO(2)-MOF binding energies, about 50% (around 20 kJ/mol), depending on the choice of exchange functional, which is significantly larger than our computed zero-point energies and thermal contributions (around 5 kJ/mol). However, two specific vdW-DFs result in excellent agreement with experiments within a few kilojoules per
mole
, at a reduced computational cost compared to quantum chemistry or many-body approaches. For Mg-MOF74,
PBE
underestimates adsorption enthalpies by about 50%, but enthalpies computed with vdW-DF, PBE+D2, and vdW-DF2 (40.5, 38.5, and 37.4 kJ/mol, respectively) compare extremely well with the experimental value of 40 kJ/mol. vdW-DF and vdW-DF2 CO(2)-MOF bond lengths are in the best agreement with experiments, while vdW-C09(x) results in the best agreement with lattice parameters. On the basis of the similar behavior of the reduced density gradients around CO(2) for the two MOFs studied, comparable results can be expected for CO(2) adsorption in BTT-type MOFs. Our work demonstrates for this broad class of molecular adsorbate-periodic MOF systems that parameter-free and computationally efficient vdW-DF and vdW-DF2 approaches can predict adsorption enthalpies with chemical accuracy.
...
PMID:CO2 capture by metal-organic frameworks with van der Waals density functionals. 2251 21
