l-Ascorbic-acid biosynthesis in the euryhaline diatom Cyclotella cryptica

l-Ascorbic acid (AA) production in cells of Cyclotella cryptica Reimann, Lewin, Guillard (Bacillariophyceae) is enhanced when darkadapted cells are exposed to light.Heterotrophically grown cells incubated with d-[6-³H,6-¹⁴C]glucose and d-[1-³H,6-¹⁴C]glucose (2 h in dark followed by 15 h light) produced labeled AA with significantly different ratios of ³H and ¹⁴C. Comparisons of labeling patterns in AA and chitin-derived d-glucosamine support a path of conversion in Cyclotella from d-glucose to AA that inverts the carbon chain of the sugar. This process resembles similar conversions found in AA-synthesizing animals and species from two other algal classes.Abbreviations AA l-Ascorbic acid - glc d-glucose - glcN d-glucosamine     

Distribution of myosin and the glial fibrillary acidic protein (GFA Protein) in rat spinal cord and in the human frontal cortex as revealed by immunofluorescence microscopy

Summary The glial fibrillary acidic (GFA) protein and myosin were localized in rat spinal cord and human frontal cortex using specific antibodies against GFA protein from human spinal cord and highly purified smooth myosin from chicken gizzard by means of an indirect immunofluorescence microscopical approach. A strong GFA protein and myosin immunoreactivity was found in astrocytes of the white and grey matter and in the external glial limitans membrane. The very fine branches of astrocytic processes stained with antiGFA protein, but not with anti-myosin. Similar results were obtained with the human frontal cortex, where myosin antibodies failed to reveal the very fine branches of protoplasmic astrocytes.As a whole, staining with the GFA protein antiserum was more crisp than with the myosin antibody.Thanks are due to Professor J.R. Wolff, Max-Planck Institute for Biophysical Chemistry, Göttingen, for stimulating discussions, to Ursula König, Christa Mahlmeister and Renate Steffens for skilful technical assistance, and to Heidi Waluk for the photographic workSupported by grants from Deutsche Forschungsgemeinschaft (Br 634/1, Dr 91/1, Un 34/4, Ste 105/19)Dedicated to Prof. Dr. med. H. Leonhardt on the occasion of his 60. birthday     

Fine structure of dense-cored vesicles in glomus cells of rat carotid body after fixation with permanganate or glutaraldehyde

Summary Glomus (Type I) cells of the carotid body of adult rats were studied electron microscopically after fixation with potassium permanganate or with glutaraldehyde and osmium tetroxide. Two permanganate fixation methods (using Krebs-Ringer-glucose, pH 7.0, or acetate buffer, pH 5.0) were compared. Numerous dense-cored vesicles were observed only in about one tenth of the glomus cells when neutral permanganate was used for fixation, although all glomus cells showed such vesicles after fixation with glutaraldehyde and osmium tetroxide. Numerous vesicles with a dense core were observed in about one third of the cells after fixation with acid potassium permanganate. With this fixation, small dense-cored vesicles similar to those in adrenergic nerve terminals were occasionally seen in the cytoplasm of glomus cells. It is tentatively concluded that the amine-storing vesicles of the carotid body are different from those in the small intensely fluorescent (SIF) cells and those in adrenergic nerve terminals.     

Sequence homology and recombination between the genomes of morphologically dissimilar bacteriophages LP 52 and theta

Summary A restriction fragment map of Bacillus licheniformis temperate phage LP 52 DNA (molecular weight 38.5×10⁶) was established, using restriction endonucleases BamHI (8 target sites), BglI (10 sites), BglII (13 sites) and EcoRI (22 sites). The map is linear, with well-defined ends, without any signs of circular permutation. The DNA of a related phage, LP 51, produced identical restriction fragments. At least 62% DNA of LP 52 has been found homologous to the DNA of the recently discovered, morphologically quite dissimilar, phage , as demonstrated by hybridization of electrophoretically separated restriction fragments of DNA. Under the same conditions, the DNAs of LP 52 and of the morphologically similar Bacillus subtilis phage 105 did not cross-hybridize. The homologous regions in the genomes of phages LP 52 and have been shown to be colinear. Comparison of the cleavage maps of phages LP 52 and has shown that, within the regions of homology, not a single restriction fragment and few restriction sites have been conserved during divergent evolution. Three major regions of heterology were defined; the longest one, covering the right-hand end of the map (73±2.75% up to 100% LP 52 genome length) appeared to contain genes coding for structural proteins of the virions; a shorter region at the left-hand end of the map (coordinates zero to 10.3±3.3% LP 52 genome length) and a very short central region (coordinates 41.8–43.9%) could be identified, the latter apparently containing a regulatory locus responsible for the heteroimmune behavior of the two phages. Recombinants between phages LP 52 and were isolated. Mapping of recombinant genomes has indicated mutual substitution of allelic pieces of LP 52 and DNAs upon strict conservation of overall genome length.     

Restriction and modification in Bacillus subtilis 168. Regulation of hsrM(nonB) expression in spoOA mutants and effects on permissiveness for phi15 and phi105 phages

Summary Gene hsrM (nonB) of Bacillus subtilis 168, causing non-permissiveness to phage SP10 (Saito et al. 1979) and reduced plating efficiency of unmodified phage 105, is responsible for non-permissiveness of B. subtilis 168 for phages 15 and PZA. Upon transformation to sporulation deficiency (allele spoOA) B. subtilis 168 becomes permissive for 15 and PZA and loses the ability to restrict 105. spoOA str-1 double transformants of B. subtilis 168, however, retain the restriction 168 and non-permissiveness for 15 and PZA phages, in spite of their Spo^– phenotype. Therefore it appears that a functional product of the spoOA gene is required for expression of gene hsrM in wild-type bacteria, but is not essential in streptomycin-resistant bacteria. Phage genomes (PZA) were trapped in spores of the restriction deficient strain with much higher efficiency than in the wild-type.     

Determination and postnatal development of fructokinase activity in swine liver]

Starting from the spectrophotometric method, described in ADELMAN et al., optimal reaction conditions for the measurement of fructokinase (ketohexokinase) in pig liver were systematically studied. It was necessary to increase the concentration of the substrate and further to lower the concentration of ATP for an optimal Mg: ATP-radio of 2:1. Using the optimized method fructokinase activity was determined in pig liver in relation to age, beginning from the last days of pregnancy to puberty. In liver of fetuses and newborn piglets during the first two days of life no or only a minute activity of the fructokinase was recorded. Therefore, the high level of fructose in fetal blood results from the inability of the fetus to metabolize fructose synthezised in the placenta or the fetal organs. At the end of the first week of life the activity of fructokinase was 10 times, after the second week 15-20 times higher than at birth. This high level remains constant during the suckling period and after weaning. For this reason, piglets after the first week of life are able to metabolize fructose and after the third week to form glucose and to release it into circulation. In adult pigs the activity of fructokinase in the liver decreases slightly. It corresponds-as in rat and human-to the elimination rate of experimentally applied fructose from the circulation. Therefore, this enzyme even in pigs is of significant importance for the utilization of fructose.