Phencyclidine-induced expression of c-Fos-like immunoreactivity in mouse brain regions

For the purpose of studying a role of immediate early genes in psychotomimetic-induced behavioral excitation, we experimentally enhanced the locomotor activity of mice by acute administration of phencyclidine and examined the expression and localization of the c-Fos-like and c-Jun-like immunoreactivities in brain regions. A single injection of phencyclidine (5.0 mg/kg, i.p.) significantly increased not only the locomotor activity but also the expression of c-Fos-like immunoreactivity in several brain regions, particularly in the parietal cortex, hippocampal dentate gyrus, piriform cortex and hypothalamus. Interestingly, the c-Fos-like immunoreactivity in the parietal cortex continued to increase for 1 week after the phencyclidine injection. These results indicate that phencyclidine, even injected only once, can induce the persistent expression of c-Fos or c-Fos-related protein(s) in the mouse brain, and also suggest the possibility that such a c-Fos expression may underlie the behavioral and/or psychotomimetic effects of phencyclidine.     

Selection for mutants with low nitrate uptake ability in rice (Oryza sativa)

Screening for mutants deficient in the high affinity system of nitrate uptake was performed using mutagenized M₂ population of rice ( Oryza sativa , cv. Nipponbare or Kinmaze). For selecting mutants, M₂ seedlings were transferred individually to 10 ml solution containing 250 μ M potassium nitrate and 500 μ M calcium sulphate at 20 or 28°C. After 6 or 24 h, nitrate concentration of the solution was determined with a nitrate selective electrode and the seedlings showing impaired nitrate uptake were selected as nitrate uptake deficient variants. Of 74 variants, three were confirmed to be mutants with low nitrate uptake ability in the M₃ generation. Potassium uptake ability also decreased in the mutants. Three mutants were divided into two groups based on the analysis of nitrate reductase (NR, EC 1.6.6.1) activity and chlorate resistance. Two, NUE13 and NUE36 , had a lower level of NR activity than the original cultivar and were not resistant to chlorate, while the seedlings of NUE50 had the same level of NR activity as the original cultivar and were more resistant to chlorate than the original cultivar. All mutants were resistant to cesium, a toxic ion analogue for potassium, suggesting that the decreased levels of both nitrate and potassium uptake were coupled to the change of plasma membrane H⁺-ATPase activity.     

Molecular Cloning and Characterization of the cDNA for Discoidin II of Dictyostelium discoideum

By using monoclonal antibodies directed against discoidin II,we have isolated cDNA clones from axenically grown Ax-2 cells.On cDNA clone (D2) condtained a 1.2-k.b insert encoding theentire discoidin II protein, which is conposed of 257 aminoacid residuces and has a calculated molecular mass of 28,574.The amino acid sequences, determined by Edman degradation ofsix tryptic peptides of discoidin II, were identical to thosededuced from the cDNA sequences. The protein bears no resemblanceto any proteins in the data banks, except that its sequenceis 49% identical with the amino acid sequence of discoidin I.Discoidin II shares with discoidin I both a carbohydratebindingsite and an Arg-Gly-Asp (RGD) sequence, which has been foundin fibronectin in mammalian cells. With the onset of aggregation(8 h of development), a 1.3-kb discoidin II mRNA begins to accumulate.A similar pattern of regulation occurs at the protein level. ¹Present address: MRC Laboratory for Molecular Cell Biology,University College London, Gower Street, London, WC1E 6BT UnitedKingdom     

Dimer Formation of a Cell-Cell Adhesion Protein, gp64 of the Cellular Slime Mold, Polysphondylium pallidum

The cellular slime mold, Polysphondylium pallidum, has two EDTA-resistanttypes of cell-cell adhesion. The major component of them hasbeen identified as a glycoprotein with a molecular mass of 64kDa on SDS-PAGE (referred to as gp64). We found that a substantialamount of the gp64 run as dimer, when gp64 was dissolved inSDS-sample buffer without 2-mercaptoethanol and then subjectedto electrophoresis. The occurrence of a homophilic dimer wasdemonstrated by analyzing the dimer-like band on a gel for itsamino acid sequence and amino acid composition. The dimer-likeband also was analyzed by three sorts of monoclonal antibodies,two of which recognize respectively a conforniational epitopeand a denatured epitope of the protein moiety of gp64. The dataindicate that the native conformation of gp64 is necessary fordimer formation. ²Present address: Institute of Immunological Science, HokkaidoUniversity, Sapporo, 060 Japan     

Exercise-induced splitting of the inorganic phosphate peak: investigation by time-resolved 31P-nuclear magnetic resonance spectroscopy

To investigate the splitting of the inorganic phosphate (Pi) peak during exercise and recovery, a time-resolved ³¹phosphorus nuclear magnetic resonance spectroscopy (³¹P-MRS) technique was used. Seven healthy young sedentary male subjects performed knee flexion exercise in the prone position inside a 2.1-T magnet, with the surface coil for ³¹P-MRS being placed on the biceps femoris muscle. After a 1-min warm-up without loading, the exercise intensity was increased by 0.41 W at 15-s intervals until exhaustion, followed by a 5-min recovery period. The ³¹P-MRS were recorded every 5 s during the rest-exercise-recovery sequence. Computer-aided contour analysis and pixel imaging of the Pi and phosphocreatine peaks were performed. Five of the seven subjects showed two distinct Pi peaks during exercise, suggesting two different pH distributions in exercising muscle (high pH and low pH region). In these five subjects, the high-pH increased rapidly just after the onset of exercise, while the low-pH peak increased gradually approximately 60 s after the onset of exercise. During recovery, the disappearance of the high-pH peak was more rapid than that of the low-pH peak. These findings suggest that our method ³¹P-MRS provides a simple approach for studying the kinetics of the Pi peak and intramuscular pH during exercise and recovery.     

Correlation of betacyanin synthesis with cell division in cell suspension cultures of Phytolacca americana

In suspension cultures of Phytolacca americana , betacyanin accumulation was reduced when cell division was inhibited by treatment with various inhibitors of DNA synthesis or anti-microtubule drugs. Aphidicolin (APC), an inhibitor of DNA synthesis, reduced the incorporation of radioactivity from labeled tyrosine into betacyanin, but the incorporation of radioactivity from labeled 3,4-dihydroxyphenylalanine (DOPA) into betacyanin was not affected by similar treatments. Propyzamide, another anti-microtubule drug, reduced incorporation of radioactivity from tyrosine and DOPA into betacyanin. However, the rate of incorporation from DOPA was higher than that from tyrosine. The results suggest that inhibition of betacyanin accumulation in Phytolacca americana cells by APC and propyzamide is due to suppression of the reaction converting tyrosine to DOPA, which may be closely related to cell division.     

Importance of purine-pyridine hydroxyl and purine amino groups for hammerhead ribozyme cleavage

The importance of the 2′-hydroxyl and 2-amino groups of guanosine residues for the catalytic efficiency of a hammerhead ribozyme has been investigated. The three guanosines in the central core of a hammerhead ribozyme were replaced by deoxyinosine, inosine, and deoxyguanosine, and ribozymes containing these analogues were chemically synthesized. Most of the modified ribozymes are drastically descreased in their cleavage efficiency. However. deletion of the 2-amino group at G₈ (replacement with inosine, deoxyguanosine, deoxyinosine) caused little alteration in the catalytic activity relative to that obtained with the unmodified ribozyme. Whereas, deletion of the 2′-amino group at G₁₂ and G₅ (replacement with inosine, deoxyinosine, and deoxyguanosine) resulted in ribozymes with drastic decrease in the catalytic activity relative to that obtained with the unmodified ribozyme. In contrast, two uridine residues, U⁷ and U⁴, in the ribozyne sequence were replaced by deoxyuridine (dU). The dU4 complex resulted in a decrease in the catalytic rate, with relative cleavage activity that ws about half that observed for the native complex. By comparison, the dU⁷ complex exhibited a relative cleavage activity within 3.3-fold of that observed with native ribozyme/substrate complex. This result suggests that the 2′-hydroxyl group at U ⁷ is not essential for activity.

The importance of the 2′-hydroxyl, and 2-amino groups of guanosine residues for the catalytic efficiency of a hammerhead roibozyme has been investigated. Most of the modified rybozymes are drastically decreased in their cleavage efficiency. However, deletion of the 2-amino group at G₈ or deletion of the 2′-hydroxyl group at G₁₂ caused little alteration in the catalytic activity relative to that obtained with the unmodified ribozyme. In contrast, two uridine residues, U₇ and U₄, in the ribozyme sequence were replaced by deoxyuridine (dU). The U4 complex resulted in a decrease in the catalytic rate, with relative cleavage activity that was about half that observed for the native complex.     

Mycobacterial cell wall: Structure and role in natural resistance to antibiotics

Abstract Mycobacteria show a high degree of intrinsic resistance to most antibiotics and chemotherapeutic agents. The low permeability of the mycobacterial cell wall, with its unusual structure, is now known to be a major factor in this resistance. Thus hydrophilic agents cross the cell wall slowly because the myobacterial porin is inefficient in allowing the permeation of solutes and exists in low concentration. Lipophilic agents are presumably slowed down by the lipid bilayer which is of unusually low fluidity and abnormal thickness. Nevertheless, the cell wall barrier alone cannot produce significant levels of drug resistance, which requires synergistic contribution from a second factor, such as the enzymatic inactivation of drugs.