Physiological and biochemical aspects of the acid survival of Listeria monocytogenes

The physiological aspects of the response to acidic conditions and the correlated protein synthesis were studied by using Listeria monocytogenes grown in a chemically defined synthetic medium. This growth was greatly affected by pH of the medium. It decreased when pH declined and was arrested at pH 4. When pH went under 4, the bacteria began to die. If the bacteria had been adapted to an intermediary sublethal pH before imposition of lethal pH stress, they would have resisted better lethal pH. A prolonged treatment at intermediary pH, however, rendered the bacteria more sensitive to subsequent lethal pH. Organic volatile acids exerted a more deleterious effect on L. monocytogenes than inorganic acids at the same stressing pH. The acquired acid tolerance was conserved after several weeks of storage of the adapted bacteria at 4 degrees C. Acid stress and acid adaptation (tolerance) affected the synthesis patterns of bacterial proteins: Many proteins were repressed and several others increased in expression level. These acid-induced proteins were separated by two-dimensional (2D-) electrophoresis and analyzed by a computer-aided 2D-gel analysis system. The results obtained suggested that acid tolerance and acid stress responses require the synthesis of a certain number of shared proteins and that additional acid-induced proteins are needed when the bacteria must face more severe acidic pH.     

Selectivity of lipid-protein interaction with myelin proteolipids PLP and DM-20. A fluorescence anisotropy study

The two main myelin proteolipids, PLP (30 kDa) and DM-20 (25 kDa), differ by an internal deletion in DM-20. The deleted fragment, of 35 amino acids (116-150), corresponds to the major hydrophilic domain of PLP. Fluorescence anisotropy experiments using diphenylhexatriene as a fluorescent probe were performed to detect the phase separation induced by these two proteolipids in multilamellar vesicles of binary composition. We found that in vesicles composed of 30% L-alpha-PS and 70% DPPC, the PLP boundary layer contained about 18 motionally restricted phospholipids, almost exclusively L-alpha-PS. On the contrary, the DM-20 boundary layer contained only 14 to 15 phospholipids, with a composition no different from that of the bulk vesicle. In mixtures of DMPG and DPPC, the selectivity of PLP for the acidic phospholipid DMPG was maintained, but was lower than that observed for L-alpha-PS. We assume that this selectivity of PLP stems mainly from electrostatic interactions between the charged residues of the 116-150 fragment, deleted in DM-20, and the acidic phospholipids. These results suggest that fragment 116-150 may play a specific role in the interaction of PLP with the lipid bilayer of the myelin membrane.     

Isolation and identification of three ecdysteroid conjugates with a C-20 hydroxy group in eggs of locusta migratoria

Three ecdysteroids conjugates with a hydroxy group at C-20 were isolated from developing eggs of Locusta migratoria and identified as 22-phosphate conjugates of 2-deoxy-20-hydroxyecdysone, 20-hydroxyecdysone and 20-hydroxyecdysone acetate.     

Ozone potentiates vitamin E depletion by ultraviolet radiation in the murine stratum corneum

As the outermost layer of the skin, the stratum corneum is exposed to environmental oxidants. To investigate putative synergisms of environmental oxidative stressors in stratum corneum, hairless mice were exposed to ultraviolet radiation (UV) and ozone (O(3)) alone and in combination. Whereas a significant depletion of alpha-tocopherol was observed after individual exposure to either a 0.5 minimal erythemal dose of UV or 1 ppm O(3) for 2 h, the combination did not increase the effect of UV alone. However, a dose of 0.5 ppm O(3) x 2 h, which had no effect when used alone, significantly enhanced the UV-induced depletion of vitamin E. We conclude that concomitant exposure to low doses of UV and O(3) at levels near those that humans can be exposed to causes additive oxidative stress in the stratum corneum.     

Ginsenoside-Rd from Panax notoginseng enhances astrocyte differentiation from neural stem cells

Neural stem cells cultured as neurospheres were used to assess the effects of P. notoginseng on the production of neurons and glia. The crude saponins (PNS) and ginsenoside-Rd promote the differentiation of neurospheres into astrocytes. Ginsenoside-Rd increases the production of astrocytes in a dose-dependent manner. On the other hand, both PNS and ginsenoside-Rd induce a weak but significant effect by decreasing the number of neurons. The other ginsenosides do not induce any differentiation on both neurons and astrocytes.     

Crystal structure of the tumor-promoter okadaic acid bound to protein phosphatase-1

Protein phosphatase-1 (PP1) plays a key role in dephosphorylation in numerous biological processes such as glycogen metabolism, cell cycle regulation, smooth muscle contraction, and protein synthesis. Microorganisms produce a variety of inhibitors of PP1, which include the microcystin class of inhibitors and okadaic acid, the latter being the major cause of diarrhetic shellfish poisoning and a powerful tumor promoter. We have determined the crystal structure of the molecular complex of okadaic acid bound to PP1 to a resolution of 1.9 A. This structure reveals that the acid binds in a hydrophobic groove adjacent to the active site of the protein and interacts with basic residues within the active site. Okadaic acid exhibits a cyclic structure, which is maintained via an intramolecular hydrogen bond. This is reminiscent of other macrocyclic protein phosphatase inhibitors. The inhibitor-bound enzyme shows very little conformational change when compared with two other PP1 structures, except in the inhibitor-sensitive beta12-beta13 loop region. The selectivity of okadaic acid for protein phosphatases-1 and -2A but not PP-2B (calcineurin) may be reassessed in light of this study.     

DNA binding and nucleotide flipping by the human DNA repair protein AGT

O(6)-alkylguanine-DNA alkyltransferase (AGT), or O(6)-methylguanine-DNA methyltransferase (MGMT), prevents mutations and apoptosis resulting from alkylation damage to guanines. AGT irreversibly transfers the alkyl lesion to an active site cysteine in a stoichiometric, direct damage reversal pathway. AGT expression therefore elicits tumor resistance to alkylating chemotherapies, and AGT inhibitors are in clinical trials. We report here structures of human AGT in complex with double-stranded DNA containing the biological substrate O(6)-methylguanine or crosslinked to the mechanistic inhibitor N(1),O(6)-ethanoxanthosine. The prototypical DNA major groove-binding helix-turn-helix (HTH) motif mediates unprecedented minor groove DNA binding. This binding architecture has advantages for DNA repair and nucleotide flipping, and provides a paradigm for HTH interactions in sequence-independent DNA-binding proteins like RecQ and BRCA2. Structural and biochemical results further support an unpredicted role for Tyr114 in nucleotide flipping through phosphate rotation and an efficient kinetic mechanism for locating alkylated bases.