Evidence that γ-aminobutyric acid is a major nitrogen source during Cladosporium fulvum infection of tomato

The growth of the biotrophic pathogen Cladosporium fulvum within the tomato (Lycopersicon esculentum Mill.) leaf is restricted to the intercellular space. Previous studies from this laboratory have demonstrated that gamma-aminobutyric acid (GABA) accumulates to millimolar concentrations in the apoplast during a compatible interaction. We decided to further investigate the role of GABA during infection. A gene encoding a required enzyme for GABA metabolism, GABA transaminase (Gat1), was cloned and sequenced from C. fulvum. The predicted protein sequence of Gat1 had high homology to other fungal GABA transaminases, particularly from Aspergillus nidulans. In vitro expression experiments revealed Gat1 to be strongly expressed during fungal growth on both GABA and glutamate whereas nearly no expression was evident during nitrogen starvation conditions. Expression of Gat1 was also apparent during infection, suggesting for the first time that C. fulvum actively metabolises GABA during infection. This indicates that the fungus may be utilising the GABA in the apoplast as a nutrient source. Further analysis revealed that the expression of tomato glutamate decarboxylase, the enzyme responsible for GABA synthesis, appeared appreciably higher during a compatible interaction than in the incompatible interaction. These findings imply that the infecting fungus may alter the physiology of the tomato leaf with the result that a source of nitrogen is supplied.     

The synthesis of a major α′-mycolic acid of Mycobacterium smegmatis

The synthesis of (2R,3R,Z)-2-docosyl-3-hydroxytetracont-21-enoic acid, a significant α′-mycolic acid of Mycobacterium smegmatis and other mycobacteria is reported.     

2,4,5-trimethoxycinnamic acid: the major metabolite of α-asarone,retains most of the pharmacological properties of α-asarone

2,4,5-trimethoxycinnamic acid (TMC), the major and non toxic metabolite of α-asarone (2,4,5-trimethoxy-1-propenyl benzene), retains most of the pharmacological properties of α-asarone, since both substances, administered to hypercholesterolemic rats at 80 mg/kg body wt, decreased total serum cholesterol, lowered LDL-cholesterol levels and kept unaffected HDL-cholesterol levels. In addition, both substances increased bile flow, especially in hypercholesterolemic rats, by rising the secretion of bile salts, phospholipids and bile cholesterol. These drugs also reduced cholesterol levels of gallbladder bile, whereas phospholipids and bile salts concentrations were increased, decreasing the cholesterol saturation index (CSI). We also found that α-asarone was 20 times better inhibitor of HMG-CoA reductase than TMC. This effect on HMG-CoA reductase was the only property highly reduced in TMC in comparison with α-asarone, while the other pharmacological properties of α-asarone were retained by TMC. These experiments strongly suggest that TMC can be further studied as a possible hypocholesterolemic and cholelitholytic agent.     

The blood-brain barrier permeability of 18β-glycyrrhetinic Acid, a major metabolite of glycyrrhizin in glycyrrhiza root, a constituent of the traditional Japanese medicine yokukansan

18β-Glycyrrhetinic acid (GA) is a major metabolite of glycyrrhizin (GL), which is one of the components of glycyrrhiza root, a constituent herb of the traditional Japanese medicine yokukansan. It is well known that most GL is metabolized to GA in the intestine by bacteria. A previous in vitro study using cultured rat cortical astrocytes suggested that GA activates glutamate transport, which is a putative mechanism of the psychotropic effect of yokukansan. To activate the glutamate transport in the brain, GA must be absorbed into the blood after oral administration of yokukansan and then cross the blood-brain barrier (BBB) to reach the brain. However, there is no data on the BBB permeability of GA derived from yokukansan. In the present study, the BBB permeability of GA was investigated in both in vivo and in vitro studies. In the in vivo study, GA was detected in the plasma, brain, and cerebrospinal fluid of rats orally administered yokukansan. In the in vitro study using a BBB model composed of co-culture of endothelial cells, pericytes, and astrocytes, the permeability rate and apparent permeability coefficient of GA were found to be 13.3?±?0.5?% and 16.5?±?0.7 × 10(-6) cm/s. These in vivo and in vitro results suggest that GL in orally administered yokukansan is absorbed into the blood as GA, and then reaches the brain through the BBB. This evidence further supports the possibility that GA is an active component in the psychotropic effect of yokukansan.     

Indole-3-methanol—a metabolite of indole-3-acetic acid in pea seedlings

Summary Degradation of indole-3-acetic acid was investigated in etiolated pea shoots; the study was limited to indolic metabolites. The products formed were fractionated by column chromatography and identified by thin-layer chromatography and chemical methods. The pathway of indole-3-acetic acid degradation involving indole-3-aldehyde was found to be more significant than stated in literature, and indole-3-methanol was established as the major indolic metabolite.The following abbreviations will be used: IAA: indole-3-acetic acid; IM: indole-3-methanol; IAld: indole-3-aldehyde; ICA: indole-3-carboxylic acid.     

1β,7β-Dihydroxydehydroabietic acid,a new biotransformation product of dehydroabietic acid by Aspergillus niger

Microbial transformation of dehydroabietic acid by Aspergillus niger afforded the new derivative 1β,7β-dihydroxydehydroabietic acid and the known 1β-hydroxy and 7β-hydroxy derivatives. The structures were elucidated by spectroscopic methods. The compounds were assessed towards Gram (+) and Gram (−) bacteria and showed a weak antimicrobial effect. This revised version was published online in August 2006 with corrections to the Cover Date.     

Optimized production of L-β-hydroxybutyric acid by a mutant of Yarrowia lipolytica

A mutant strain of Yarrowia lipolytica was developed which produced 8.0 g l--hydroxybutyric acid l^–1 from butyric acid in a batch culture. The optimum culture conditions in the fermenter for maintenance of a high cell activity, determined by chemostat analyses, were a specific growth rate of 0.06 h^–1, a glucose concentration of 2.0 g l^–1, and a butyric acid concentration of 8.1 g l^–1. A fed-batch fermentation was performed under these conditions resulting in an l--hydroxybutyric acid yield of 31 g l^–1.     

Easy stereoselective synthesis of 5α-estrane-3β,17α-diol, the major metabolite of nandrolone in the horse

5α-Estrane-3β,17α-diol is the major metabolite of nandrolone in horse urine. The presence of 5α-estrane-3β,17α-diol in female and gelding urines is prohibited by Racing Rules and its natural presence in male urine led regulation authorities to establish a concentration threshold of 45 ng/mL. This paper describes a rapid, simple and stereoselective synthesis of 5α-estrane-3β,17α-diol, providing horseracing laboratories with an essential reference material for their antidoping performance.     

Hepatic reduction of the secondary bile acid 7-oxolithocholic acid is mediated by 11β-hydroxysteroid dehydrogenase 1

The oxidized bile acid 7-oxoLCA (7-oxolithocholic acid), formed primarily by gut micro-organisms, is reduced in human liver to CDCA (chenodeoxycholic acid) and, to a lesser extent, UDCA (ursodeoxycholic acid). The enzyme(s) responsible remained unknown. Using human liver microsomes, we observed enhanced 7-oxoLCA reduction in the presence of detergent. The reaction was dependent on NADPH and stimulated by glucose 6-phosphate, suggesting localization of the enzyme in the ER (endoplasmic reticulum) and dependence on NADPH-generating H6PDH (hexose-6-phosphate dehydrogenase). Using recombinant human 11β-HSD1 (11β-hydroxysteroid dehydrogenase 1), we demonstrate efficient conversion of 7-oxoLCA into CDCA and, to a lesser extent, UDCA. Unlike the reversible metabolism of glucocorticoids, 11β-HSD1 mediated solely 7-oxo reduction of 7-oxoLCA and its taurine and glycine conjugates. Furthermore, we investigated the interference of bile acids with 11β-HSD1-dependent interconversion of glucocorticoids. 7-OxoLCA and its conjugates preferentially inhibited cortisone reduction, and CDCA and its conjugates inhibited cortisol oxidation. Three-dimensional modelling provided an explanation for the binding mode and selectivity of the bile acids studied. The results reveal that 11β-HSD1 is responsible for 7-oxoLCA reduction in humans, providing a further link between hepatic glucocorticoid activation and bile acid metabolism. These findings also suggest the need for animal and clinical studies to explore whether inhibition of 11β-HSD1 to reduce cortisol levels would also lead to an accumulation of 7-oxoLCA, thereby potentially affecting bile acid-mediated functions.     

Properties of a major α-globulin of rice endosperm

Globulin was isolated from milled rice (Oryza sativa, line IR480-5-9) by 5% NACl extraction and was precipitated by (NH₄)₂SO₂ or by dialysis against water. The extract was purified by repeated isoelectric precipitation at pH 4.5. The major globulin fraction (40%) exhibited one band by electrophoresis at pH 4.5 but two bands at pH 8.3. Similarly, one sharp peak was shown by sedimentation corresponding to 1.41S (α-globulin) in acetic acid (pH 2) and NaOH (pH 11.7) but a broad asymmetric peak was obtained at pH 6.7, 8.3 and 8.9. Gel filtration of the α-globulin at pH 6.5 exhibited 2 proteins with MW 20 000 and 98 000. The results suggest a pH dependent aggregation phenomenon. The two proteins could not be separated by DEAE-cellulose chromatography. SDS-polyacrylamide electrophoresis of α-globulin revealed one subunit with MW 18 000. This α-globulin is poorer in lysine and histidine but richer in cystine, methionine, arginine, tyrosine and glutamic acid than whole milled rice proteinfa]Taken part from the M.S. thesis of AAP from the University of the Philippine at Los Baños (1977).     

Polydom/SVEP1 is a ligand for integrin α9β1

A variety of proteins, including tenascin-C and osteopontin, have been identified as ligands for integrin α9β1. However, their affinities for integrin α9β1 are apparently much lower than those of other integrins (e.g. α3β1, α5β1, and α8β1) for their specific ligands, leaving the possibility that physiological ligands for integrin α9β1 still remain unidentified. In this study, we found that polydom (also named SVEP1) mediates cell adhesion in an integrin α9β1-dependent manner and binds directly to recombinant integrin α9β1 with an affinity that far exceeds those of the known ligands. Using a series of recombinant polydom proteins with N-terminal deletions, we mapped the integrin-binding site to the 21st complement control protein domain. Alanine-scanning mutagenesis revealed that the EDDMMEVPY sequence (amino acids 2636-2644) in the 21st complement control protein domain was involved in the binding to integrin α9β1 and that Glu(2641) was the critical acidic residue for the integrin binding. The importance of this sequence was further confirmed by integrin binding inhibition assays using synthetic peptides. Immunohistochemical analyses of mouse embryonic tissues showed that polydom colocalized with integrin α9 in the stomach, intestine, and other organs. Furthermore, in situ integrin α9β1 binding assays using frozen mouse tissues showed that polydom accounts for most, but not all, of the integrin α9β1 ligands in tissues. Taken together, the present findings indicate that polydom is a hitherto unknown ligand for integrin α9β1 that functions as a physiological ligand in vivo.     

The type-4 pilus is the major virulence-associated adhesin of Pseudomonas aeruginosa – a review

Pseudomonas aeruginosa (Pa) produces several surface-associated adherence factors or adhesins which promote attachment to epithelial cells and contribute to the virulence of this pathogen. Among them, the type-4 pilus accounts for about 90% of the adherence capability of Pa to human lung pneumocyte A549 cells. Furthermore, it is responsible for more than 90% of the virulence in AB.Y/SnJ mice. Pa type-4 pili display a tip-base differentiation with the adherence function located at the tip of the pilus. All Pa pili prototypes characterized so far contain an intrachain disulfide loop (DSL) of 12 to 17 semi-conserved amino acid residues at the C-terminus of pilin. In Pa, this DSL comprises the epithelial cell-binding domain. Despite little sequence homology, DSL-containing peptides of different pilin prototypes seemingly reveal striking structural similarities. Two β-turns within the loop and the disulfide bridge impose significant structural rigidity on the DSL pilin peptide, suggesting a conformationally conserved binding domain. Insertions of C-terminal pilin peptides with disrupted DSL displayed on the surface of bacterial S-layer mediate the same receptor binding characteristics as pili, indicating that a DSL is not essential in maintaining the functionality of the binding domain. Pa pili bind specifically to the carbohydrate moiety of the glycosphingolipids (GSL) asialo-G_M1 and asialo-G_M2 and, to a much weaker extent, to lactosyl ceramide and ceramide trihexoside. The disaccharide sequence GalNAcβ(1-4)Gal, common in both asialo-G_M1 and asialo-G_M2, likely represents the minimal structural receptor motif recognized by the pili. Pa pili also bind to surface-localized proteins of human epithelial cells and other cell types, suggesting that non-sialylated GSL and (glyco)proteins function as receptors of pili. In addition to the major pilus adhesin, exoenzyme S and, as recent studies indicate, flagella, are further protein adhesins of Pa with GSL receptor binding specificities similar to those of pili.     

7′-hydroxy (−)-R-abscisic acid: A metabolite of feeding (−)-R-abscisic acid to Xanthium strumarium

Feeding of(±)-abscisic acid to leaves of Xanthium strumarium resulted in formation of a new metabolite. The compound was identified as 7′-hydroxy (−)-R-abscisic acid by high resolution mass spectrometry of its methyl ester and monoacetate, and by optical rotary dispersion. The numbering system for abscisic acid has been extended to include the exocyclic methyl groups. Feeding racemic [2-¹⁴C]abscisic acid to Xanthium leaves resulted in ca 20% conversion of the radiolabelled compound into the new metabolite. Evidence is presented that, in Xanthium, only the synthetic (−)-R-enantiomer of abscisic acid is hydroxylated at the 7′-position.     

Transformation of lithocholic acid to a new bile acid, 3α, 15β-dihydroxy-5β-cholanic acid by Cunninghamella blakesleeana ST-22

Summary A fungus identified as Cunninghamella blakesleeana (Lendner) can carry out 15-hydroxylation of lithocholic acid to a new bile acid (3,15-dihydroxy-5-cholanic acid). By optimizing the fermentation conditions, the amount of the product increased from 0.17 g/l to 1.2 g/l. Hydrophilicity measurements and in vitro cholesterol solubilization tests showed that 3, 15-dihydroxy-5-cholanic acid was as effective as ursodeoxycholic acid in cholesterol solubilization.Abbreviations LCA lithocholic acid (3-hydroxy-5-cholanic acid) - 3, 15-DHC (3, 15-dihydroxy-5-cholanic acid) - DMSO dimethyl sulfoxide - CHES 2-[N-cyclohexylamino]ethanesulfonic acid