Degradation mechanisms of phenolic beta-1 lignin substructure model compounds by laccase of Coriolus versicolor

Phenolic beta-1 lignin substructure model compounds, 1-(3,5-dimethoxy-4-hydroxy-phenyl)-2-(3,5-dimethoxy-4-ethoxyphenyl)propa ne-1, 3-diol (I) and 1-(3,5-dimethoxy-4-ethoxyphenyl)-2-(3, 5-dimethoxy-4-hydroxyphenyl)propane-1,3-diol (II) were degraded by laccase of Coriolus versicolor. Substrate I was converted to 1-(3,5-dimethoxy-4-hydroxyphenyl)-2-(3,5-dimethoxy-4-ethoxyphenyl)-3- hydroxypropanone (III), 1-(3,5-dimethoxy-4-ethoxyphenyl)-2-hydroxyethanone (IV), syringaldehyde (V), 1-(3,5-dimethoxy-4-ethoxyphenyl)-3-hydroxypropanal (VI), 2,6-dimethoxy-p-hydroquinone (VII), and 2,6-dimethoxy-p-benzoquinone (VIII). Furthermore, incorporations of 18O of 18O2 into ethanone (IV) and 18O of H218O into hydroquinone (VII) and benzoquinone (VIII) were confirmed. Substrate II gave 1-(3,5-dimethoxy-4-hydroxyphenyl)ethane-1, 2-diol (IX), 1-(3,5-dimethoxy-4-hydroxyphenyl)-2-hydroxyethanone (X), and 3,5-dimethoxy-4-ethoxybenzaldehyde (XI). Also 18O of H218O was incorporated into glycol (IX) and ethanone (X). Based on the structures of the degradation products and the isotopic experiments, it was established that three types of reactions occurred via phenoxy radicals of substrates caused by laccase: (i) C alpha-C beta cleavage (between C1 and C2 carbons); (ii) alkyl-aryl cleavage (between C1 carbon and aryl group); and (iii) C alpha (C1) oxidation.     

Computer simulation of the folding-unfolding transition of island-model proteins--folding pathway, transition process, and fluctuations

Monte Carlo computer simulations were performed to elucidate the dynamic aspects of the folding and unfolding transitions of island-model protein. Five different types of model proteins were designed, according to characteristics of backbone structure. The computer simulations clearly show that the unfolding and folding transitions are all-or-none processes between the N-and U-states. They are typical Poisson processes. From the Arrhenius plots of rate constants, the activation enthalpies of folding and unfolding were determined. In addition, the folding pathways were determined along the reaction coordinate. Formations of several local structures along a polypeptide chain are almost simultaneous, but the most probable time sequence of events exists at the moment of transition. That is the most probable folding pathway. The unfolding pathway was found to be just the reverse process of the most probable folding pathway. The relationship between the fluctuations in each equilibrium state and the transition process was considered. In contrast to the theory of absolute reaction rate, the transient states are widely distributed along the reaction coordinate. From analysis of the “transient process,” we tried to determine the critical states from which the transient process starts. As a result, we found that the unfolding transition occurs at the stage near the N-state. During the U-state, large joined blocks rarely appear, but they appear in the transient process towards the N-state. However, the “branch point” between the N- and U-states lies near the N-state, and joined blocks tend to unfold prior to passing over the branch point. We concluded that the stability of later folding intermediates is important for selection of the folding pathway, while preferential selection of an early folding intermediate is important in acceleration of the folding rate. The effects of intrachain cross-linking and peptide fragment binding on the rate constants were examined by using computer simulations of model proteins. In general, a small-sized loop formed by cross-linking accelerates the folding rate and a large-sized loop contributes much to the stabilization of the native conformation. We also found that peptide fragment binding contributes little to the acceleration of the folding rate of the residual protein.     

Removal of endotoxin from water by microfiltration through a microporous polyethylene hollow-fiber membrane.

The microporous polyethylene hollow-fiber membrane has a unique microfibrile structure throughout its depth and has been found to possess the functions of filtration and adsorption of endotoxin in water. The membrane has a maximum pore diameter of approximately 0.04 micron, a diameter which is within the range of microfiltration. Approximately 10 and 20% of the endotoxin in tap water and subterranean water, respectively, was smaller than 0.025 micron. Endotoxin in these water sources was efficiently removed by the microporous polyethylene hollow-fiber membrane. Escherichia coli O113 culture broth contained 26.4% of endotoxin smaller than 0.025 micron which was also removed. Endotoxin was leaked into the filtrate only when endotoxin samples were successively passed through the membrane. These results indicate that endotoxin smaller than the pore size of the membrane was adsorbed and then leaked into the filtrate because of a reduction in binding sites. Dissociation of 3H-labeled endotoxin from the membrane was performed, resulting in the removal of endotoxin associated with the membrane by alcoholic alkali at 78% efficiency.     

Cloning in Saccharomyces cerevisiae of a cycloheximide resistance gene from the Candida maltosa genome which modifies ribosomes.

We have previously shown that cycloheximide resistance can be induced in a strain of Candida maltosa by modifying ribosomes (M. Takagi, S. Kawai, Y. Takata, N. Tanaka, M. Sunairi, M. Miyazaki, and K. Yano, J. Gen. Appl. Microbiol. 31:267-275, 1985). The present paper describes the cloning of the gene involved in this resistance (designated RIM-C for ribosome modification by cycloheximide) by using a host-vector system of Saccharomyces cerevisiae.     

Hepatic adenylate cyclase. Development-dependent coupling to the beta-adrenergic receptor in the neonate

Guanine nucleotide-dependent modulation of agonist binding to the beta-receptor reflects coupling of the receptor to the nucleotide regulatory protein. Similarly, guanine nucleotide-dependent stimulation of adenylate cyclase can be used as an index of coupling between the regulatory protein and the catalytic unit of the cyclase. Using both approaches we have studied coupling in the beta-adrenergic receptor-adenylate cyclase system in rabbit liver during neonatal development. With [3H]dihydroalprenolol as ligand, the Bmax was relatively unchanged (200-300 fmol/mg of protein) between birth and end of day 1 and was similar to adult values. Guanyl-5'-yl imidodiphosphate-dependent shift in agonist (l-isoproterenol) competition curves was biphasic, decreasing from 10-fold in membranes isolated from animals at term to about 6-fold in membranes from 6-h-old neonates, and increasing progressively in older animals to a maximal measurable value of 42-fold in the adult. The ability of guanyl-5'-yl imidodiphosphate, GTP, GTP plus isoproterenol, NaF, or forskolin to activate adenylate cyclase was also biphasic and age-dependent. With Mn2+ the measured activity was not at any time greater than the activity at term. Pretreatment of membranes with cholera toxin resulted in differential levels of enhancement of adenylate cyclase activity wherein much lower enhancement was observed in membranes from neonatal animals. With [32P]NAD as substrate, cholera toxin-catalyzed ADP-ribosylation of membranes indicated development-dependent accumulation of Ns peptides. From these results we suggest that there is a decreased efficiency in the coupling of the beta-adrenergic receptor to hepatic adenylate cyclase in early neonatal life. The molecular basis for the biphasic nature of the coupling is presently unclear.     

Introduction of mouse C epsilon genes into Cos-7 cells and fertilized mouse eggs

A fragment of the cloned gene for the mouse C epsilon chain, coding for the first, second, third, and fourth domains, has been coupled to the SV40 promotor region (pSV2-mC epsilon). About 50 copies of pSV2-mC epsilon or its PvuII-EcoRI fragments were introduced into Cos-7 cells. Expression of PvuII-EcoRI fragments of pSV2-mC epsilon was observed in about 50% of the Cos-7 cells by indirect fluorescence staining. However, no expression of circular pSV2-mC epsilon was observed. About 200 copies of linearized pSV2-mC epsilon with EcoRI were introduced into fertilized mouse eggs. Two of 78 mice born from these eggs had integrated mouse C epsilon genes. Mouse C epsilon gene was shown to be integrated in a tandem array and as intact structures without undergoing gross deletions or rearrangements, judged from the Southern blotting patterns from several restriction enzymes. The first transgenic mouse was mated to a normal male to examine whether mouse C epsilon gene were stably transmitted to progeny. Among 5 mice to which the C epsilon gene had been transmitted, one deleted 5 copies of this gene and another deleted one junction fragment, thus demonstrating relatively unstable transmission. No C epsilon mRNA was detected in the liver, kidney, brain, lung, skeletal muscle, heart, testis, or spleen of a transgenic mouse.     

Spider toxin (JSTX) on the glutamate synapse

A new neurotoxin (JSTX) was separated from spider (Nephila clavata, Joro spider) venom. JSTX irreversibly suppressed the excitatory postsynaptic potential (EPSP) and the glutamate potential in the lobster neuromuscular junction with high degree of specificity. The threshold concentration for suppressing EPSPs corresponds to a small fraction of the toxin in a venom gland, roughly estimated as low as 10(-10) M/l. 10(-10) M/l. In the giant synapse of squid stellate ganglion JSTX suppressed EPSPs without affecting the antidromic response. Glutamate-induced membrane depolarization was blocked by JSTX. In mammalian brain slice preparation, JSTX suppressed the orthodromic spike response but failed to affect on the antidromic spike in the hippocampal pyramidal neuron of CA1 and CA3 region. The above results strongly support the view that the squid giant synapse and synapses in the hippocampal pyramidal neuron are mediated by glutamate.     

Characterization of a Rous sarcoma virus mutant defective in packaging its own genomic RNA: biochemical properties of mutant TK15 and mutant-induced transformants.

The accompanying paper (S. Kawai and T. Koyama , J. Virol. 51:147-153, 1984) describes the isolation and biological properties of a mutant, TK15 , derived from a Rous sarcoma virus mutant, tsNY68 . The cis-acting defect of the mutant is analyzed biochemically in this paper. TK15 virions released from virus-producing 15c (+) cells were deficient in viral genomic 39S RNA, although comparable amounts of viral RNAs were transcribed in 15c (+) and tsNY68 -infected cells. Analysis of provirus DNA occurring in 15c (+) cells suggested that the mutant genome had a deletion of ca. 250 bases near the 5' end of the genome somewhere between the primer binding site and the 5' end of the gag-coding region. These findings indicate that at least part of the sequence lost in the TK15 genome is indispensable for packaging viral genomic RNA into virions. TK15 induces nonvirus -producing 15c (-) transformants at high frequency. Southern blot analysis of DNAs from those 15c (-) clone cells revealed that TK15 -derived proviruses contained various extents of internal deletions. Many 15c (-) clones had a provirus carrying only the src gene with long terminal repeat sequences at both ends. The mechanism for the segregation of 15c (-) cells is discussed.     

Genotoxicity of quinone pigments from pathogenic fungi

The genotoxicity and mutagenicity of several kinds of quinone pigments from pathogenic fungi were examined by means of the hepatocyte primary culture (HPC)/DNA repair test and of Ames test with TA98 and TA100. Clear genotoxicity of the two quinone chemicals, xanthomegnin and luteosporin were observed in the HPC/DNA repair test, though definite mutagenicity was not detected in the Salmonella microsome test. These two pigments are thus suspected to be genotoxic carcinogens.