Biosynthesis of branched-chain fatty acids in Bacillus subtilis. A decarboxylase is essential for branched-chain fatty acid synthetase

Branched long-chain fatty acids of the iso and anteiso series are synthesized in many bacteria from the branched-chain alpha-keto acids of valine, leucine, and isoleucine after their decarboxylation followed by chain elongation. Two distinct branched-chain alpha-keto acid (BCKA) and pyruvate decarboxylases, which are considered to be responsible for primer synthesis, were detected in, and purified in homogenous form from Bacillus subtilis 168 strain by procedures including ammonium sulfate fractionation and chromatography on ion exchange, reversed-phase, and gel absorption columns. The chemical and catalytic properties of the two decarboxylases were studied in detail. The removal of BCKA decarboxylase, using chromatographic fractionation, from the fatty acid synthetase significantly reduced its activity. The synthetase activity was completely lost upon immunoprecipitation of the decarboxylase. The removal of pyruvate decarboxylase by the above two methods, however, did not affect any activity of the fatty acid synthetase. Thus, BCKA decarboxylase, but not pyruvate decarboxylase, is essential for the synthesis of branched-chain fatty acids. The very high affinity of BCKA decarboxylase toward branched-chain alpha-keto acids is responsible for its function in fatty acid synthesis.     

Some properties of cassava mesocarp carbohydrates-low density polyethylene blends

Cassava mesocarp carbohydrate and its modified form were used as fillers in low density polyethylene to give plastic films that were biodegradable. It was found that the tensile strength of the films decreased with an increase in the amount of the filler incorporated. The water absorption results of the films showed that modification of the cassava mesocarp carbohydrate made it hydrophobic and therefore more compatible with the polyethylene.     

Three Distinct Types of Microautophagy Based on Membrane Dynamics and Molecular Machineries

Microautophagy is originally defined as lysosomal (vacuolar) membrane dynamics to directly enwrap and transport cytosolic components into the lumen of the lytic organelle. Molecular details of microautophagy had remained unknown until genetic studies in yeast identified a set of proteins required for the process. Subsequent studies with other experimental model organisms resulted in a series of discoveries that accompanied an expansion of the definition of microautophagy to also encompass endosomal membrane dynamics. These findings, however, still impose puzzling, non‐integrated images as to the molecular mechanism of microautophagy. By reviewing recent studies on microautophagy in various experimental systems, we propose the classification of microautophagy into three types, as the basis for developing a comprehensive view of the process.     

Nitric oxide-induced salt stress tolerance in plants: ROS metabolism,signaling, and molecular interactions

Nitric oxide (NO), a non-charged, small, gaseous free-radical, is a signaling molecule in all plant cells. Several studies have proposed multifarious physiological roles for NO, from seed germination to plant maturation and senescence. Nitric oxide is thought to act as an antioxidant, quenching ROS during oxidative stress and reducing lipid peroxidation. NO also mediates photosynthesis and stomatal conductance and regulates programmed cell death, thus providing tolerance to abiotic stress. In mitochondria, NO participates in the electron transport pathway. Nitric oxide synthase and nitrate reductase are the key enzymes involved in NO-biosynthesis in aerobic plants, but non-enzymatic pathways have been reported as well. Nitric oxide can interact with a broad range of molecules, leading to the modification of protein activity, GSH biosynthesis, S-nitrosylation, peroxynitrite formation, proline accumulation, etc., to sustain stress tolerance. In addition to these interactions, NO interacts with fatty acids to form nitro-fatty acids as signals for antioxidant defense. Polyamines and NO interact positively to increase polyamine content and activity. A large number of genes are reprogrammed by NO; among these genes, proline metabolism genes are upregulated. Exogenous NO application is also shown to be involved in salinity tolerance and/or resistance via growth promotion, reversing oxidative damage and maintaining ion homeostasis. This review highlights NO-mediated salinity-stress tolerance in plants, including NO biosynthesis, regulation, and signaling. Nitric oxide-mediated ROS metabolism, antioxidant defense, and gene expression and the interactions of NO with other bioactive molecules are also discussed. We conclude the review with a discussion of unsolved issues and suggestions for future research.     

Binding of Cu(II) or Zn(II) in a de novo designed triple-stranded alpha-helical coiled-coil toward a prototype for a metalloenzyme.

We previously reported the IZ-3adH peptide, which formed a triple-stranded coiled-coil after binding Ni(II), Cu(II), or Zn(II). In this paper, we report the peptide, IZ-3aH, having a new metal binding specificity. The IZ-3aH peptide was found to bind Cu(II) and Zn(II) and form a triple-stranded coiled-coil. However, it did not bind Ni(II). Metal ion titrations monitored by circular dichroism revealed that the dissociation constants, K(d) were 9 microm for Zn(II) and 10 microm for Cu(II). The bound Cu(II) ion has a planar tetragonal geometry, where the coordination positions are three nitrogens of the His residues and one H(2)O.     

The photoconversion of heat-treated Chenopodium chlorophyll protein and its pH dependence

Photosensitive Chenopodium chlorophyll protein was purifiedby warming the complex in a boiling water bath, followed bypassing it through a Sephadex column. The shape and positionof the absorption band in the absorption spectrum of purifiedchlorophyll protein (HCP668) were the same as those of non-treatedchlorophyll protein (CP668), except for a change in the proteinband in the UV region. The chlorophyll protein retained a quarterof its original photoconvertibility after heat treatment for25 min at 100°C. Results suggested that the chlorophyll-aminoacid residue binding is very stable against heat, and that chlorophyllis protected from decomposition through the rigid binding. The photoconvertibility of HCP668, as well as CP668, dependedstrongly upon pH, with a pronounced decrease below pH 4 andabove pH 6. Optimal convertibility was at pH 5. Above pH 12,convertibility vanished completely. However, pH-inhibited convertibilityof HCP668 was recovered to its original level by returning thepH to neutral. Illuminalion of CP668 in D₂O with red light caused a markedincrease in light scattering. This reveals the occurrence ofa conformational change of apoprotein, leading to aggregation. HCP668 was degraded by mechanical treatment to give a smallersized photosensitive chlorophyll protein without loss of photoconvertibility.This small chlorophyll protein did not precipitate in a saturated(NH₄)₂SO₄ solution. The spectral properties of this complexwere identical to those of HCP668 and CP668. (Received March 21, 1972; )     

Functional development of photosystems I and II in dark-grown pine seedlings

Green plastids prepared from seedlings of Pinus silvestris harvestedafter three weeks of growth in the dark, without exposure tolight, catalyzed photoreductions of methyl viologen and nicotinamide-adeninedinucleotide phosphate, and cyclic photophosphory-lation withN-methylphenazonium methosulfate, but could not catalyze thephotoreduction of 2,4-dichlorophenol indophenol in the absenceand presence of diphenylcarbazide. In dark-grown seedlings ofPinus silvestris, functional photosystem I developed with noexposure to light, but no photosystem II activity was abserved. (Received August 22, 1973; )     

Effects of density experience on mate guarding behavior by adult male Kanzawa spider mites

In the Kanzawa spider mite, Tetranychus kanzawai (Acari: Tetranychidae), adult males guard pre-reproductive quiescent females. I experimentally examined the effects of density experience during development and/or after adult emergence on precopulatory mate guarding behavior by T. kanzawai males. Mate guarding behavior was modified by density experience after adult emergence. When males had previously experienced high density after adult emergence (n = 71), 73.2% of them engaged in precopulatory mate guarding. In contrast, when males had previously experienced low density after adult emergence (n = 82), 61.0% of them did not guard females. Mate guarding with physical contact occurred more frequently when males had previously experienced a high density of potential rivals than when they had not, but the difference in behavior between the two groups of males was marginally not significant. Nevertheless, these results suggest overall that T. kanzawai males change mate guarding behavior in response to previously experienced density.     

Atg26-Mediated Pexophagy Is Required for Host Invasion by the Plant Pathogenic Fungus Colletotrichum orbiculare

The number of peroxisomes in a cell can change rapidly in response to changing environmental and physiological conditions. Pexophagy, a type of selective autophagy, is involved in peroxisome degradation, but its physiological role remains to be clarified. Here, we report that cells of the cucumber anthracnose fungus Colletotrichum orbiculare undergo peroxisome degradation as they infect host plants. We performed a random insertional mutagenesis screen to identify genes involved in cucumber pathogenesis by C. orbiculare. In this screen, we isolated a homolog of Pichia pastoris ATG26, which encodes a sterol glucosyltransferase that enhances pexophagy in this methylotrophic yeast. The C. orbiculare atg26 mutant developed appressoria but exhibited a specific defect in the subsequent host invasion step, implying a relationship between pexophagy and fungal phytopathogenicity. Consistent with this, its peroxisomes are degraded inside vacuoles, accompanied by the formation of autophagosomes during infection-related morphogenesis. The autophagic degradation of peroxisomes was significantly delayed in the appressoria of the atg26 mutant. Functional domain analysis of Atg26 suggested that both the phosphoinositide binding domain and the catalytic domain are required for pexophagy and pathogenicity. In contrast with the atg26 mutant, which is able to form appressoria, the atg8 mutant, which is defective in the entire autophagic pathway, cannot form normal appressoria in the earlier steps of morphogenesis. These results indicate a specific function for Atg26-enhanced pexophagy during host invasion by C. orbiculare.