Changes in Brain Tissue and Behavior Patterns Induced by Single Short-Term Fasting in Mice

In humans, emaciation from long-term dietary deficiencies, such as anorexia, reportedly increases physical activity and brain atrophy. However, the effects of single short-term fasting on brain tissue or behavioral activity patterns remain unclear. To clarify the impact of malnutrition on brain function, we conducted a single short-term fasting study as an anorexia model using male adult mice and determined if changes occurred in migratory behavior as an expression of brain function and in brain tissue structure. Sixteen-week-old C57BL/6J male mice were divided into either the fasted group or the control group. Experiments were conducted in a fixed indoor environment. We examined the effects of fasting on the number of nerve cells, structural changes in the myelin and axon density, and brain atrophy. For behavior observation, the amount of food and water consumed, ingestion time, and the pattern of movement were measured using a time-recording system. The fasted mice showed a significant increase in physical activity and their rhythm of movement was disturbed. Since the brain was in an abnormal state after fasting, mice that were normally active during the night became active regardless of day or night and performed strenuous exercise at a high frequency. The brain weight did not change by a fast, and brain atrophy was not observed. Although no textural change was apparent by fasting, the neuronal neogenesis in the subventricular zone and hippocampus was inhibited, causing disorder of the brain function. A clear association between the suppression of encephalic neuropoiesis and overactivity was not established. However, it is interesting that the results of this study suggest that single short-term fasting has an effect on encephalic neuropoiesis.     

Substructure of the Cytoplasmic Membrane of Bacillus megaterium

The components of fractions obtained by dialyzing and differential centrifuging the “Ghost” of Bacillus megaterium were analyzed in detail. The compositions of amino acids in the main fractions (Fraction 2 and 3) of the “Ghosts”, were estimated. Fraction 2 was rich in non-polar amino acids, while Fraction 3 was scanty of them. Most of the fatty acids in Fraction 2 were 12-methyl tetradecanoic acid, while in Fraction 3 many kinds of fatty acid were detected.

As for the localization of enzymes, the three enzymes, glucose oxidase, succinic dehydrogenase and reduced nicotinamide-adenine dinucleotide oxidase, which were present in the original “Ghosts”, were mostly observed in Fraction 2, and a very little amount of them was found in the other fractions. Further, Fraction 2 could be dissolved in formic acid and dialysis of the solution brought about reaggregation to form membrane-like structure in the presence of Ca or Mg ion.     

Effect of Inositol Deficiency on Cellular Permeability of the Inositol Exacting Yeast

Inositol deficiency caused the abnormalities of permeability of the cell envelope of the inositol exacting yeasts. In the case of Schizosaccharomyces pombe, in which the marked leakage of cellular free-pool fraction was not detected, the uptake activity of glucose or methylglucoside decreased in inositol deficiency, especially in aerobic condition. Investigations on the compositions of lipids and fatty acids showed that the change in fatty acid composition was not so remarkable as that in phosphatides in inositol deficiency. One of the main causes of low transport activity may be due to the change in phosphatides, but not due to that in fatty acids, possibly. Intracellular contents of glucose was not less in inositol deficiency than in sufficiency. These results suggest that inositol deficiency caused the low activity of uptake, which might not be, however, the primary cause of low fermentative activity.

In the case of Saccharomyces cerevisiae Ino^– mutant A–21–20, the similar results about permeability and lipid analyses were obtained in inositol deficiency.     

Effects of Inositol Deficiency on Respiratory and Fermentative Activities of Inositol-exacting Yeast,Schizosaccharomyces pombe

Inositol deficiency of Schizosaccharomyces pombe did not induce significant change of contents of various cellular components except for phospholipids and inositol. The most remarkable decrease in inositol content by the deficiency occurred in the mitochondrial fraction. Electronmicroscopic observation of the inositol-deficient cells of Sch. pombe showed no remarkable thickening of cell wall as occurred in the inositol-exacting mutant of Saccharomyces cerevisiae Strain A–21–20.

Marked loss of fermentative activity under the aerobic condition was caused from inositol deficiency without significant change of activities of respiration and anaerobic fermentation. This seemed to indicate elevated regulatory control of the fermentative activity by oxygen in the inositol-deficient Sch. pombe.

Phosphorylative activities of intact cells and the isolated mitochondria coupled with oxidation was also remarkably suppressed by inositol deficiency.     

Interleukin-2 (IL-2) induces erythroid differentiation and tyrosine phosphorylation in ELM-I-1 cells transfected with a human IL-2 receptor beta chain cDNA.

The molecular mechanism of erythroid differentiation has been still ill-defined. In this study, we introduced a human interleukin-2 receptor (IL-2R) beta chain cDNA into ELM-I-1 cells which differentiated into hemoglobin-positive cells in the presence of erythropoietin (Epo), and established the transformant which expressed IL-2R beta chain. In this transformant, we revealed that IL-2 induced erythroid differentiation and the same pattern of tyrosine phosphorylation as Epo. These data suggest that tyrosine phosphorylation is involved in signal transduction pathway of erythroid differentiation. It is also implicated that the Epo and IL-2 receptor system share a common signal transduction pathway.     

Efficient Solar‐Driven Water Oxidation over Perovskite‐Type BaNbO2N Photoanodes Absorbing Visible Light up to 740 nm

Photoelectrochemical water splitting using semiconductors absorbing a wide range of visible light is a potentially attractive means of harvesting large portions of the solar spectrum. However, this is also very challenging because narrowing the semiconductor band gap lowers the driving force for photoreactions. Herein, a highly active perovskite BaNbO₂N exhibiting photoexcitation up to 740 nm for water oxidation is reported. The synthesis route, consisting of moderate nitridation and subsequent annealing in inert Ar flow, enhances the crystallinity of the BaNbO₂N surface without inducing the reduction of the Nb species. As a result, a particulate BaNbO₂N photoanode exhibits a photocurrent of 5.2 mA cm^?2 at 1.23 V_RHE under simulated solar irradiation, which is the highest yet reported for an oxynitride responsive at wavelengths above 600 nm. Suppressing the reduction of B‐site cations during the synthesis of perovskite AB(O,N)₃, which otherwise results in surface defects or impurities, is critical for achieving high water oxidation activity.     

The retrotransposon RTip1 is integrated into a novel type of minisatellite, MiniSip1, in the genome of the common morning glory and carries another new type of minisatellite, MiniSip2

 Transposable elements have often been discovered as new insertion sequences in known genes, and minisatellites are often employed as molecular markers in diagnostic and mapping studies. We compared the genes for flower pigmentation in a line of the common morning glory bearing fully colored flowers with those in two anthocyanin ^flaked mutable lines producing variegated flowers and found RFLPs at the region of the ANS gene for anthocyanin biosynthesis. The DNA rearrangements detected by the RFLPs are due to integration of a novel type of minisatellite, MiniSip1, having a long LTR retrotransposon, RTip1, inserted in the mutable lines. The structural analysis of the rearranged region revealed that the 12.4-kb RTip1 element is flanked by 5-bp target duplications within the MiniSip1 sequence and contains two LTR sequences of about 590 bp, a primer binding site for tRNA^Lys, a typical polypurine tract and another new type of minisatellite, MiniSip2. Since no long open reading frame corresponding to the gag and pol genes was found, RTip1 appears to be a defective Ty3/gypsy-like element. Interestingly, the 269-bp-long MiniSip1 element comprises two alternating motifs of 41 bp and 19 bp, whereas the 962 bp long MiniSip2 element consists of two partially alternating motifs of 86 bp and 90 bp which are partially homologous to each other. Possible evolutionary processes that may have generated the rearranged structure at the ANS gene region are also discussed. Received: 25 April 1997 / Accepted: 16 May 1997