Enhancement of vitamin E production in sunflower cell cultures

The most biologically active component of vitamin E, -tocopherol, is synthesized in its most effective stereoisomeric form only by photosynthetic organisms. Using sunflower cell cultures, a suitable in vitro production system of natural -tocopherol was established. The most efficient medium was found to be MS basal medium with naphthaleneacetic acid and 6-benzylaminopurine with the addition of casaminoacids and myo-inositol. Culture feeding experiments using biosynthetic precursors showed that -tocopherol production improved by 30% when homogentisic acid was used. Interestingly, time-course experiments with sunflower suspension cultures showed a possible increase of 78% in -tocopherol production when using cultures of longer subculture intervals. Compared to the starting plant tissue, an overall 100% increase of -tocopherol was reached by these sunflower cell cultures.     

Effect of cell passage and density on protein kinase G expression and activation in vascular smooth muscle cells

It has been shown that rat aortic smooth muscle cells (AoSMCs) lost PKG-I expression when propagated repetitively or grown at low densities. Conversely, AoSMCs isolated from PKG-I deficient mice are indistinguishable from those isolated from normal mice in morphology and growth characteristics. In this study, human AoSMCs were grown from passage 9 (p9) to passage 15 (p15) and rat AoSMCs were isolated and cultured from p1 through p15. Western blotting and immunofluorescence microscopy showed little difference in PKG-I expression among different passages. Next, rat AoSMCs of p4 were grown and harvested at different cell densities. Western blotting again showed little difference among cells seeded or harvested at different densities. To test the effect of cell passage on PKG-I activation, rat AoSMCs of p4 and p11 were treated with cGMP and analyzed by Western blotting for phosphorylated vasodilator-stimulated phosphoprotein (P-VASP). The results showed that p4 had higher level of PKG-I activation than p11.     

Toxicity of two type II ribosome-inactivating proteins (cinnamomin and ricin) to domestic silkworm larvae

Cinnamomin and ricin are two type II ribosome-inactivating proteins. They exhibited a different toxicity to domestic silkworm (Bombyx mori) larvae by oral feeding bioassay. The LC50 of ricin to the silkworm larvae at third instar was much lower than that of cinnamomin. When the isolated 80S ribosome from domestic silkworm pupae was treated separately with the reduced cinnamomin or the reduced ricin, a specific RNA fragment (R-fragment) was produced as characterized by 8 M urea-denatured polyacrylamide gel (3.5%) electrophoresis. The purified A-chains of both cinnamomin and ricin showed a slightly different RNA N-glycosidase activity to the domestic silkworm pupal ribosome. It was proposed that the difference of their toxicity to domestic silkworm larvae was not related to their A-chains but to the properties of their B-chains. It was also found that the vomit obtained from the midgut of domestic silkworm larvae could hydrolyze these two proteins apparently to a similar extent.     

The effect of Smallanthus sonchifolius leaf extracts on rat hepatic metabolism

Smallanthus sonchifolius (yacon), originating from South America, has become popular in Japan and in New Zealand for its tubers which contain beta-1,2-oligofructans as the main saccharides. The plant is also successfully cultivated in Central Europe in the Czech Republic in particular. Its aerial part is used in Japan and in Brazil as a component in medicinal teas; while aqueous leaf extracts have been studied for their hypoglycemic activity in normal and diabetic rats. We have already demonstrated the high content of phenolic compounds in yacon leaf extracts and their in vitro antioxidant activity. In this paper, we present the effects of two organic fractions and two aqueous extracts from the leaves of S. sonchifolius on rat hepatocyte viability, on oxidative damage induced by tert-butyl hydroperoxide (t-BH) and allyl alcohol (AA), and on glucose metabolism and their insulin-like effect on the expression of cytochrome P450 (CYP) mRNA. All the extracts tested exhibited strong protective effect against oxidative damage to rat hepatocyte primary cultures in concentrations ranging from 1 to 1000 microg/ml, reduced hepatic glucose production via gluconeogenesis and glycogenolysis at 1000 microg/ml. Moreover, the effects of the organic fractions (200 and 250 microg/ml) and to a lesser extent, the tea infusion (500 microg/ml) on rat CYP2B and CYP2E mRNA expression, were comparable to those observed with insulin. The combination of radical scavenging, cytoprotective and anti-hyperglycemic activity predetermine S. sonchifolius leaves for use in prevention and treatment of chronic diseases involving oxidative stress, particularly diabetes.     

Relationships between amino acid sequence and backbone torsion angle preferences

Statistical averages and correlations for backbone torsion angles of chymotrypsin inhibitor 2 are calculated by using the Rotational Isomeric States model of chain statistics. Statistical weights of torsional states of phipsi pairs, needed for the statistics of the full chain, are obtained in two different ways: 1) by using knowledge-based pairwise dependent phipsi energy maps from Protein Data Bank (PDB) and 2) by collecting torsion angle data from a large number of random coil configurations of an all-atom protein model with volume exclusion. Results obtained by using PDB data show strong correlations between adjacent torsion angle pairs belonging to both the same and different residues. These correlations favor the choice of the native-state torsion angles, and they are strongly context dependent, determined by the specific amino acid sequence of the protein. Excluded volume or steric clashes, only, do not introduce context-dependent phipsi correlations into the chain that would affect the choice of native-state torsional angles.     

Role of protein in the primary step of the photoreaction of yellow protein

We show the unexpectedly important role of the protein environment in the primary step of the photoreaction of the yellow protein after light illumination. The driving force of the trans-to-cis isomerization reaction was analyzed by a computational method. The force was separated into two different components: the term due to the protein-chromophore interaction and the intrinsic term of the chromophore itself. As a result, we found that the contribution from the interaction term was much greater than that coming from the intrinsic term. This accounts for the efficiency of the isomerization reaction in the protein environment in contrast to that in solution environments. We then analyzed the relaxation process of the chromophore on the excited-state energy surface and compared the process in the protein environment and that in a vacuum. Based on this analysis, we found that the bond-selectivity of the isomerization reaction also comes from the interaction between the chromophore and the protein environment.     

Functional interaction of 13 yeast SCF complexes with a set of yeast E2 enzymes in vitro

SCF complexes are multi-subunit ubiquitin ligases that, in concert with the E1 and E2 ubiquitination enzymes, catalyze the ubiquination of specific target proteins. Only three yeast SCFs have been reconstituted and characterized to date; each of these ubiquitinates its target protein with the E2 Cdc34. We have reconstituted and purified 1 known and 12 novel yeast SCF complexes, and explored the ability of these complexes to function with 5 different purified E2 enzymes; Ubc1, Cdc34, Ubc4, Ubc8 and Ubc11. We have found that the ubiquitination of Sic1 by the reconstituted SCF(Cdc4) complex was specifically catalyzed by two of the five E2 enzymes tested in vitro; Cdc34 and Ubc4. We also show that at least eight of the purified SCF complexes clearly ubiquitinated their F-box proteins in vitro, lending support for a regulatory mechanism in which F-box proteins catalyze their own destruction. The autoubiquitination of each F-box was in some cases catalyzed only by Cdc34, and in other cases preferentially catalyzed by Ubc4. Ubc4 thus interacts with multiple SCFs in vitro, and the interactions among SCF and E2 components of the ubiquitination machinery may allow further diversification of the roles of SCFs in vivo.     

The cis-Pro touch-turn: a rare motif preferred at functional sites

A new motif of three-dimensional (3D) protein structure is described, called the cis-Pro touch-turn. In this four-residue, three-peptide motif, the central peptide is cis. Residue 2, which precedes the proline, has phi, psi values either in the "prePro region" of the Ramachandran plot near -130 degrees, 75 degrees or in the Lalpha region near +60 degrees, +60 degrees. The Calpha(1)-Calpha(4) distance is 4-5 A and the two flanking peptides lie parallel to one another, making van der Waals contact rather than a hydrogen bond. Apparently, this arrangement is locally unfavorable and therefore rare, usually occurring only if needed for biological function. Of the 12 examples in a 500-protein database, cis-Pro touch-turns are found at the catalytic sites of pectate lyase, Ni-Fe hydrogenase, glucoamylase, xylanase, and opine dehydrogenase and at the primary binding sites of ribonuclease H, type I DNA polymerase, ribotoxin, and phage gene 3 protein. In each of these protein families, the touch-turns serve different roles; their functional importance is supported by conservation and mutagenesis data. In analyzing the conservation patterns of these 3D motifs, new methods for in-depth quality evaluation of the structural bioinformatic data are employed to distinguish between significant exceptions and errors