Phycobilisomes in Blue-Green Algae

Fifteen species of freshwater blue-green algae, including unicellular, filamentous, and colonial forms, were subjected to a variety of fixatives, fixation conditions, and stains for comparison of the preservation of phycobilisomes. Absorption spectra of the corresponding in vivo and released photosynthetic pigments, in 10 of the species that were maintained in culture, demonstrated the presence of phycocyanin in all 10 species and phycoerythrin in only 2 of them. Spectroscope and electron microscope evidence was obtained for localization of phycobiliproteins in phycobilisomes of Nostoc muscorum. Phycobilisomes were observed in all species examined in situ, strenghening the hypothesis that phycobilisomes are common to all phycobiliprotein-containing photosynthetic blue-green algae.     

Aflatoxin production by a potent Aspergillus flavus link isolate

An aflatoxin-producing isolate of Aspergillus flavus was found to be a consistent producer of aflatoxin on all substrates which supported the growth of the mold. In competition with six other selected molds, this isolate was dominant except with one species of Penicillium. Aflatoxin production was parallel to the extent of A. flavus growth whether effected by substrate or competition.     

Sensory characteristics of the P afferent neurone of the crab thoracic-coxal muscle receptor organ

Intracellular recordings were made from the P fibre, the smallest of the three afferent neurones innervating the thoracic-coxal muscle receptor organ of the crab (Carcinus maenas). While the two larger afferents are nonspiking, the response of the P fibre to a trapezoidal change in receptor muscle length consists of a single action potential signalling the onset of stretch superimposed on a graded amplitude receptor potential. The P fibre is sensitive to the velocity of the applied stretch, but is insensitive to static joint position, stretch amplitude and the velocity of the release phase. The presence and amplitude of the action potential depends on the initial length of the receptor muscle, the tension caused by efferent activation of the receptor muscle prior to receptor stretch, and on the velocity of stretch. Length constant (1.9 mm) and specific membrane resistance (76 K · cm²) values obtained for the P fibre, together with its small diameter (7 m) suggest that this neurone is less well adapted to conveying passive signals to the thoracic ganglion than are the S and T fibres. It is likely that the P fibre complements the length sensitivity of the S fibre and the tension and velocity sensitivity of the T fibre by signalling the onset of receptor stretch via single action potentials.Abbreviations TCMRO thoracic-coxal muscle receptor organ - TTX tetrodotoxin     

Production of antibacterial compounds by phylloplane-inhabiting yeasts and yeastlike fungi.

The production of antibacterial compounds by yeasts and yeastlike fungi isolated from the phylloplane is reported. Aureobasidium pullulans, Citeromyces matritensis, Cryptococcus laurentii, Rhodotorula glutinis, and Sporobolomyces roseus produced antibacterial compounds inhibitory to both Pseudomonas fluorescens and Staphylococcus aureus in an overlay bioassay. In contrast, isolates of Candida albicans, Filobasidium uniguttulatum, Saccharomyces cerevisiae, Torulaspora delbruckii, Tremella foliacea, Trichosporon beigelii, and Trichosporon dulcitum obtained from soil or from culture collections did not produce inhibitory compounds when screened by the same procedure. The production of antibacterial compounds was examined in more detail, using several isolates of A. pullulans distinguished by cluster analysis on the basis of biochemical and physiological tests. They were found to produce a range of antibacterial compounds with different activities. Two distinct antibiotics were produced by an isolate of A. pullulans in liquid culture during both the logarithmic and the stationary phases of growth.     

The Influence of Genotype and Environment on the Physiological and Metabolic Diversity ofFusarium compactum

Talbot, N. J., Vincent, P., and Wildman, H. G. 1996. The influence of genotype and environment on the physiological and metabolic diversity ofFusarium compactum. Fungal Genetics and Biology20,254–267. Fungal species produce a large variety of secondary metabolites which are of considerable interest to the pharmaceutical industry. It is clear that the secondary metabolite production of a species varies significantly in strains from different geographic locations and from different habitats. The influence of genotype and environment on metabolite production is, however, poorly understood. In this study we examined the influence of genotypic variability, physiological variability, environmental location, and habitat on metabolite production byFusarium compactum.Isolates of the fungus from two geographic locations and two distinct habitat types were examined for growth on 95 different carbon sources, and genotypic variability was determined using RAPDs and rDNA–RFLP analysis. In a blind test secondary metabolite production was assessed using HPLC profiles of methanolic cell extracts. A number of correlations were observed between genotypic groupings, as determined using parsimony, and specific metabolite production. Similar correlations were also observed with physiological groups although genotypic analysis proved to be a more sensitive predictor of metabolite variability. The data suggest a complex relationship between environment, genotype, and metabolite production but highlight the use of genetic screening as a means of optimizing the chances of identifying a wide range of metabolites from a given species.     

Concentration of antibiotics by reverse osmosis

Reverse osmosis is shown to be a viable process for the concentration of highly labile antibiotic solutions. Mathematical n10deJs of antibiotic inactivation by chemical and biological contamination are proposed and correlated with experimental data. Procedures for obtaining high antibiotic recoveries are discussed.     

Inheritance behavior of information coding for small subunit polypeptides of fraction 1 protein

In various genera of plants, the small subunit of fraction 1 protein is often composed of more than one kind of polypeptide; these differ in isoelectric points and amino acid composition. Previous analysis of numerous individual progeny of Nicotiana tabacum (two kinds of polypeptides), N. glauca + N. langsdorffii parasexual hybrids (three kinds), and other examples showed no change in F-1 protein composition as a consequence of alternation of generations. Experiments reported here show that absence of one member of each of the 24 different pairs of chromosomes in an N. tabacum monosomic series and also absence of the “S” pair in a nullisome did not affect F-1 protein composition. Absence of the “E” pair caused reduction in the amount of the least acidic of the two kinds of N. tabacum small subunit polypeptides. The question of how many individual progeny of self-fertile hybrids would have to be analyzed to detect segregation of genes coding for F-1 protein small subunit polypeptides, if segregation occurs, was answered by analysis of F₁ hybrids between N. otophora and N. tomentosiformis, and two subspecies of N. suaveolens, together with their F₂ progeny. In both cases, analysis of 16 progeny was sufficient to demonstrate a segregation pattern of two F₁ hybrid type to one each of the two parental types. Therefore, in the absence of segregation, it is likely that coding information for different kinds of F-1 protein small subunit polypeptides is sequestered on heterologous chromosomes, as postulated in previous reports.     

Nontranslation of foreign genetic information for fraction 1 protein under circumstances favorable for direct transfer ofNicotiana gossei isolated chloroplasts intoN. Tabacum protoplasts

Summary The nuclei and cytoplasm ofN. gossei andN. tabacum are compatible to the extent that reciprocal, interspecific F₁ hybrids can be produced by conventional breeding techniques. Conditions were established in which manyN. gossei isolated chloroplasts could be seen by phase and fluorescence microscopy to adhere to 40% of the population of protoplasts obtained from white tissue of variegatedN. tabacum plants and to remain attached after washing the protoplasts. Chloroplasts also could be seen to enter the interior of the protoplasts. After treating albino protoplasts withN. gossei chloroplasts, the protoplasts were subjected to further conditions whereby 65 calluses containing shoots developed. TwentyN. tabacum protoplasts not treated with foreign chloroplasts also produced calluses with shoots to serve as a control. All calluses developed chlorophyll irrespective of whether or not the albino protoplasts had been treated with isolatedN. gossei chloroplasts. The Fraction 1 protein ofN. tabacum has a different electrophoretic mobility from the protein ofN. gossei or anN. gossei xN. tabacum F₁ hybrid. The Fraction 1 protein large subunit is coded by chloroplast DNA, whereas the small subunit is coded by nuclear DNA. Fraction 1 protein was isolated from the variegated shoots of the 65 calluses obtained after treating albino protoplasts with foreign chloroplasts. Immunoelectrophoresis demonstrated the protein from each callus to have a mobility identical toN. tabacum protein. Therefore, under circumstances highly favorable for the direct transfer ofN. gossei isolated chloroplasts (and possibly nuclei also) intoN. tabacum protoplasts, no evidence was obtained to suggest that genetic information contained in the isolated foreign organelles was being translated into the polypeptides of either the large or small subunits of Fraction 1 protein contained in newly differentiated leaves derived from the protoplasts. Supported by Research Grant PCM-75-07368 from the National Science Foundation.     

Nuclear DNA codes for Nicotiana ferredoxin.

Ferredoxin was purified from 10 species of Nicotiana and spinach leaves. Fingerprints showed all to contain five major tryptic peptides. Some of the spinach peptides were different in RF and mobility from the Nicotiana peptides, but none of the Nicotiana ferredoxins had peptides which could distinguish one species of ferredoxin from another. Electrofocusing S-carbaminomethylcysteinyl ferredoxins showed spinach ferredoxin to have a more acidic and N. glutinosa ferredoxin a slightly more acidic isoelectric point than the other 9 Nicotiana species which were alike. Electro-focusing ferredoxin from the hybrid N. glutinosa female times N. glauca male resolved two bands or isozymes of ferredoxin, one corresponding to N. glutinosa, the other to N. glauca, the code for the latter having come from the DNA in the N. glauca pollen used to form the hybrid plant. N. glutinosa ferredoxin does not contain methionine and is different from N. tabacum and N. glauca ferredoxins which contain methionine. The N. glutinosa female times N. glauca male ferredoxin contained one-half the methionine found in N. glauca ferredoxin, thus confirming that some of the genetic information for ferredoxin in the hybrid was originally contained in the nuclear DNA of N. glauca.     

A multiscale optimisation method for bone growth scaffolds based on triply periodic minimal surfaces

Tissue engineered bone scaffolds are potential alternatives to bone allografts and autografts. Porous scaffolds based on triply periodic minimal surfaces (TPMS) are good candidates for tissue growth because they offer high surface-to-volume ratio, have tailorable stiffness, and can be easily fabricated by additive manufacturing. However, the range of TPMS scaffold types is extensive, and it is not yet clear which type provides the fastest cell or tissue growth while being sufficiently stiff to act as a bone graft. Nor is there currently an established methodology for TPMS bone scaffold design which can be quickly adopted by medical designers or biologists designing implants. In this study, we examine six TPMS scaffold types for use as tissue growth scaffolds and propose a general methodology to optimise their geometry. At the macro-scale, the optimisation routine ensures a scaffold stiffness within suitable limits for bone, while at the micro-scale it maximises the cell growth rate. The optimisation procedure also ensures the scaffold pores are of sufficient diameter to allow oxygen and nutrient delivery via capillaries. Of the examined TPMS structures, the Lidinoid and Split P cell types provide the greatest cell growth rates and are therefore the best candidates for bone scaffolds.