Morphological, Histochemical and Biochemical Features of Cultivated Rhodiola rosea (Altai Mountains Ecotype).

The study analyzed the content and localization of phenolic compounds, in particular phenylpropanoids, of Rodiola rosea plants of Altai Mountains ecotype during the introduction period of 2-4 years in the conditions of the forest-steppe zone of Western Siberia. The plant material for the introduction experiment was obtained by in vitro method. HPLC was used to identify 11 phenolic compounds, including gallic acid, rosarin, rosavin, rosin, cinnamyl alcohol, rhodiosin, rhodionin, and kaempferol. The highest content of phenylpropenoids was found in rhizomes of the 4-year-old R. rosea plants: 1.02% rosarin, 2.64% rosavin, 1.05% rosin, 3.39% cinnamyl alcohol. Analysis of the phenylpropanoid profile showed that the predominant component in all the studied samples was cinnamyl alcohol (up to 58%). Histochemical studies identified phenolic substances in the rhizomes and roots of R. rosea, which are localized in parenchymal and vascular tissues. It was revealed that the total rhizome biomass exceeded that of the root, and by the 4th year of introduction, it was approximately 2-fold greater in dry weight. The study showed high biosynthetic potential and biological productivity of the studied R. rosea ecotype upon introduction.

Understanding the molecular basis of the high oxygen affinity variant human hemoglobin Coimbra.

Human hemoglobin (Hb) Coimbra (ßAsp99Glu) is one of the seven ßAsp99 Hb variants described to date. All ßAsp99 substitutions result in increased affinity for O2 and decreased heme-heme cooperativity and their carriers are clinically characterized by erythrocytocis, caused by tissue hypoxia. Since ßAsp99 plays an important role in the allosteric α1ß2 interface and the mutation in Hb Coimbra only represents the insertion of a CH2 group in this interface, the present study of Hb Coimbra is important for a better understanding of the global impact of small modifications in this allosteric interface. We carried out functional, kinetic and dynamic characterization of this hemoglobin, focusing on the interpretation of these results in the context of a growth of the position 99 side chain length in the α1ß2 interface. Oxygen affinity was evaluated by measuring p50 values in distinct pHs (Bohr effect), and the heme-heme cooperativity was analyzed by determining the Hill coefficient (n), in addition to the effect of the allosteric effectors inositol hexaphosphate (IHP) and 2,3-bisphosphoglyceric acid (2,3-BPG). Computer simulations revealed a stabilization of the R state in the Coimbra variant with respect to the wild type, and consistently, the T-to-R quaternary transition was observed on the nanosecond time scale of classical molecular dynamics simulations.

Binding of the substrate UDP-glucuronic acid induces conformational changes in the xanthan gum glucuronosyltransferase.

GumK is a membrane-associated glucuronosyltransferase of Xanthomonas campestris that is involved in xanthan gum biosynthesis. GumK belongs to the inverting GT-B superfamily and catalyzes the transfer of a glucuronic acid (GlcA) residue from uridine diphosphate (UDP)-GlcA (UDP-GlcA) to a lipid-PP-trisaccharide embedded in the membrane of the bacteria. The structure of GumK was previously described in its apo- and UDP-bound forms, with no significant conformational differences being observed. Here, we study the behavior of GumK toward its donor substrate UDP-GlcA. Turbidity measurements revealed that the interaction of GumK with UDP-GlcA produces aggregation of protein molecules under specific conditions. Moreover, limited proteolysis assays demonstrated protection of enzymatic digestion when UDP-GlcA is present, and this protection is promoted by substrate binding. Circular dichroism spectroscopy also revealed changes in the GumK tertiary structure after UDP-GlcA addition. According to the obtained emission fluorescence results, we suggest the possibility of exposure of hydrophobic residues upon UDP-GlcA binding. We present in silico-built models of GumK complexed with UDP-GlcA as well as its analogs UDP-glucose and UDP-galacturonic acid. Through molecular dynamics simulations, we also show that a relative movement between the domains appears to be specific and to be triggered by UDP-GlcA. The results presented here strongly suggest that GumK undergoes a conformational change upon donor substrate binding, likely bringing the two Rossmann fold domains closer together and triggering a change in the N-terminal domain, with consequent generation of the acceptor substrate binding site.

Molecular mechanism of myoglobin autoxidation: insights from computer simulations.

Myoglobin (Mb) and hemoglobin have the biological ability to carry/store oxygen (O2), a property which requires its heme iron atom to be in the ferrous--Fe(II)--state. However, the thermodynamically stable state in the presence of O2 is Fe(III) and thus the oxidation rate of a globin is a critical parameter related to its function. Mb has been extensively studied and many mutants have been characterized regarding its oxygen mediated oxidation (i.e., autoxidation) rates. Site directed mutants in residues 29 (B10), which shapes the distal cavity, and 64 (E7), the well-known histidine gate, have been shown to display a wide range of autoxidation rate constants. In this work, we have thoroughly studied the mechanism underlying the autoxidation process by means of state-of-the-art computer simulation methodologies, using Mb and site directed mutants as benchmark cases. Our results explain the observed autoxidation rate tendencies in different variants of Mb, L29F < wt < L29A = H64Q < H64F < H64A, and shed light on several aspects of the reaction at the atomic level. First, water access to the distal pocket is a key event and the observed acid catalysis relies on HisE7 protonation and opening of the His gate to allow water access, rather than protonation of the oxy heme itself. Our results also suggest that the basic mechanism, i.e., superoxide displacement by hydroxide anion, is energetically more feasible. Finally, we confirmed that distal hydrogen bonds protect the oxy complex from autoxidation.