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G. Obolensky Dr. Ing. Agr. 《Plant foods for human nutrition (Dordrecht, Netherlands)》1960,7(3):297-310
Ohne Zusammenfassung
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A modified caustic peeling process for potatoes was developed and evaluated. The process, called the double-dip process, comprises two separate caustic applications with an intervening holding period. Results on Russet Burbank potatoes showed that tissue removal was enhanced for the double-dip process when compared to the standard single dip process and that the double-dip process can effect reduction in caustic usage without requiring additional heat input. 相似文献
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Nitrogen, amino acids and protein analyses were compared for determination of tuber protein. Micro-Kjeldahl nitrogen provided a poor estimate of both protein and amino acids (r = 0.55 and 0.45 respectively). Potato protein contains about 13.5% nitrogen, making 7.5 an appropriate conversion factor. Autoanalyzer determinations of amino acids were correlated with protein analyzed by a modified Potty technique (r = .82). Amounts of six specific protein-bound amino acids were also correlated. with protein. Free amino acids accounted for about 10% of the total and non-essential amino acids constituted over 90% of this free pool. Only 23% of total nitrogen was accounted for in the free pool. Protein content and tuber size were not correlatel. Protein content was similar in the cortical, medullary and pith region. Loss in tuber protein during six months of storage at about 3 C (38-40 F) was 3%. 相似文献
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The aim of this study was to investigate the antimicrobial activity of C.I. Basic Red 18:1 (D1) and C.I. Basic Yellow 51 (D2)
cationic dyes and dyed acrylic fabrics against the common pathogens Escherichia coli, Staphylococcus aureus and Pseudomonas aeruginosa. C.I. Basic Red 18:1 dye was most effective against the test bacteria E. coli, S. aureus and P. aeruginosa in vitro whereas C.I. Basic Yellow 51 had a lesser effect. The acrylic fabrics dyed with these dyes, however, showed less
antimicrobial activity depending on the dyeing depth. It can be said that acrylic fabrics dyed with these dyes inhibit bacterial
growth. 相似文献
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At present 75 species of Hypocrea have been identified in temperate Europe. Nineteen green-spored species and their Trichoderma asexual states are here described in detail. Extensive searches for Hypocrea teleomorphs in 14 European countries, with emphasis on Central Europe, yielded more than 620 specimens within five years. The morphology of fresh and dry stromata was studied. In addition, available types of species described from Europe were examined. Cultures were prepared from ascospores and used to study the morphology of cultures and anamorphs, to determine growth rates, and to extract DNA that was used for amplification and sequencing of three genetic markers. ITS was used for identification, while RNA polymerase II subunit b (rpb2) and translation elongation factor 1 alpha (tef1) were analyzed for phylogenetic reconstruction of the genus.Several unexpected findings resulted from this project: 1) The previous view that only a small number of Trichoderma species form a teleomorph is erroneous. 2) All expectations concerning the number of species in Europe are by far exceeded. Seventy-five species of Hypocrea, two species of Protocrea, and Arachnocrea stipata, are herein identified in temperate Europe, based on the ITS identification routine using fresh material, on species described earlier without molecular data and on species recently described but not collected during this project. 3) Current data suggest that the biodiversity of Hypocrea / Trichoderma above soil exceeds the number of species isolated from soil. 4) The number of Trichoderma species forming hyaline conidia has been considered a small fraction. In Europe, 26 species of those forming teleomorphs produce hyaline conidia, while 42 green-conidial species are known. Three of the detected Hypocrea species do not form an anamorph in culture, while the anamorph is unknown in four species, because they have never been cultured.This work is a preliminary account of Hypocrea and their Trichoderma anamorphs in Europe. Of the hyaline-spored species, H. minutispora is by far the most common species in Europe, while of the green-spored species this is H. strictipilosa.General ecology of Hypocrea is discussed. Specific associations, either with host fungi or trees have been found, but the majority of species seems to be necrotrophic on diverse fungi on wood and bark.The taxonomy of the genus will be treated in two parts. In this first part 19 species of Hypocrea with green ascospores, including six new teleomorph and five new anamorph species, are described in detail. All green-spored species belong to previously recognised clades, except H. spinulosa, which forms the new Spinulosa Clade with two additional new species, and H. fomiticola, which belongs to the Semiorbis Clade and forms effuse to large subpulvinate stromata on Fomes fomentarius, a trait new for species with green ascospores. Anamorph names are established prospectively in order to provide a basis for possible policy alterations towards their use for holomorphs.Taxonomic novelties: Hypocrea aeruginea Jaklitsch, Trichoderma aerugineum Jaklitsch, T. dacrymycellum Jaklitsch, H. danica Jaklitsch, H./T. fomiticola Jaklitsch, H. longipilosa Jaklitsch, H./T. parepimyces Jaklitsch, H. parestonica Jaklitsch, T. parestonicum Jaklitsch. 相似文献
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《Field Crops Research》2001,73(1):35-46
Net blotch caused by Pyrenophora teres F. teres, is one of the important diseases in Moroccan barley fields. Contributing factors include the lack of adequate disease and crop management. Furthermore when agricultural techniques were recommended without disease control, objectives were seldom reached and resulted in adverse growers’ reaction. To sustain farmers in the Moroccan semi-arid regions and to optimize barley production, we have focused on net blotch epidemiology and the development of adequate disease management approaches. A field experiment, conducted in five locations for two consecutive years, used six cultivars with different levels of susceptibility to net blotch. These cultivars were grown under high, medium and low inoculum levels of the pathogen, and with and without disease control. Hence, a broad range of disease epidemics was generated. All the disease progress curves showed a depression in disease severity at stem elongation. The boost in biomass production coupled with the relationship between initial disease severity and area under the disease progress curve led us to recommend seed treatment and/or seedling resistance as the initial means of disease control. Although statistical differences were measured in disease severity between fungicide treated and inoculated plots during the growing season, biological differences were not substantial until all the cultivars attained boot stage. Because of this, a single application of foliar fungicide is necessary at boot stage, with a second application needed toward the end of ear emergence when weather conditions favor disease development. 相似文献
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Peanut fields are monitored for pod rot, which is typically caused by Pythium spp. and Rhizoctonia solani, in order to determine need, and the type and timing of fungicide applications. Pod rot can lead to damaged peanut kernels and when damage exceeds 2.49%, substantial price reductions occur. Nine fields or tests were sampled weekly for pod rot during the 2009 through 2012 growing seasons. The sampling was conducted on fields treated uniformly with fungicides for pod rot or within large research plots with various fungicide treatments. Pythium myriotylum was the most frequently identified pathogen species, although Rhizoctonia spp. were also recovered from diseased pods at all sites. Pod rot incidence was related to percent damaged kernels at harvest in 3 of 5 sites. Collection of 304 samples (sample unit = 46 cm of row) in a field was required to estimate 1% pod rot accurately (CV = 20%). There was a linear relationship between average % pod rot in a field, and the percentage of sampling units (absence/presence) with pod rot at low disease incidences. Scouting for pod rot of peanuts to make in-season fungicide applications will be hampered by high sample number, destructive sampling of plants, frequent sampling (due to rapid increase of disease), and the poor relationship between disease during the season and kernel damage at harvest. Making one preventative application at 60–70 days after planting may be a better practice than timing the initial fungicide application based on sampling for disease. 相似文献