Structure repair of a compacted vertisol with wet-dry cycles and crops

We hypothesized that the four rotation crops: wheat (Triticum aestivum L.), sorghum [Sorghum bicolor (L.) Merr.], lablab [Lablab purpureus (L.) Sweet] and mung bean [ Vigna radiata (L.) R. Wilczek] differ in their ability to repair soil structure. The study was conducted on a Typic Haplustert, Queensland, Australia, locally termed a Black Earth and considered a prime cropping soil. Large (0.5-m depth by 0.3-m diam.) soil cores, collected from compacted wheel furrows in an irrigated cotton (Gossypium hirsutum L.) field, were subjected to three, six, or nine wet-dry cycles that simulated local flood irrigation practices. After each cycle, soil profiles were sampled for clod bulk density, image analysis of soil structure, and evapotranspiration. Generally, all crops improved soil structure over the initial field condition but lablab and mung bean gave improvements to greater depths and more rapidly than wheat and sorghum. Mung bean and lablab caused up to a threefold increase in clod porosity in the 0.1- to 0.4-m soil layer after only three wet-dry cycles, whereas sorghum required nine wet-dry cycles to increase clod porosity in only the 0.2- to 0.3-m layer, and wheat gave no improvement even after nine wet-dry cycles. Image analysis of soil structure showed that lablab and mung bean rapidly (by three wet-dry cycles) produced smaller peds with more interconnected pore space than wheat and sorghum. By nine wet-dry cycles, sorghum achieved deep cracking of the soil but the material between the cracks remained large and dense. Evapotranspiration was double under lablab and mung bean compared with wheat and sorghum. Our results indicate greater cycles of wetting and drying under lablab and mung bean than wheat and sorghum that have led to rapid repair of soil compaction.

Effects of silicon treatment and inoculation with Fusarium oxysporum f. sp. vasinfectum on cellular defences in root tissues of two cotton cultivars

BACKGROUND AND AIMS: Silicon has been shown to enhance the resistance of plants to fungal and bacterial pathogens. Here, the effect of potassium silicate was assessed on two cotton (Gossypium hirsutum) cultivars subsequently inoculated with Fusarium oxysporum f. sp. vasinfectum (Fov). Sicot 189 is moderately resistant whilst Sicot F-1 is the second most resistant commercial cultivar presently available in Australia. METHODS: Transmission and light microscopy were used to compare cellular modifications in root cells after these different treatments. The accumulation of phenolic compounds and lignin was measured. KEY RESULTS: Cellular alterations including the deposition of electron-dense material, degradation of fungal hyphae and occlusion of endodermal cells were more rapidly induced and more intense in endodermal and vascular regions of Sicot F-1 plants supplied with potassium silicate followed by inoculation with Fov than in similarly treated Sicot 189 plants or in silicate-treated plants of either cultivar not inoculated with Fov. Significantly more phenolic compounds were present at 7 d post-infection (dpi) in root extracts of Sicot F-1 plants treated with potassium silicate followed by inoculation with Fov compared with plants from all other treatments. The lignin concentration at 3 dpi in root material from Sicot F-1 treated with potassium silicate and inoculated with Fov was significantly higher than that from water-treated and inoculated plants. CONCLUSIONS: This study demonstrates that silicon treatment can affect cellular defence responses in cotton roots subsequently inoculated with Fov, particularly in Sicot F-1, a cultivar with greater inherent resistance to this pathogen. This suggests that silicon may interact with or initiate defence pathways faster in this cultivar than in the less resistant cultivar.

Novas linhagens de algodoeiro herbáceo com coloração na fibra.

No Brasil, o programa de melhoramento visando obtenção de cultivares com fibras coloridas foi iniciado pela Embrapa Algodão em meados da década de 1990 e até o presente momento já foram lançadas seis cultivares. Excetuando-se a BR 200, a primeira a ser desenvolvida e descendente de uma espécie de algodoeiro arbóreo (G. hirsutum L. r. marie galante Hutch.) as demais são de espécies de algodoeiro herbáceo (G. hirsutum L. r. latifolium Hutch.) e descendem do cruzamento de germoplasma de fibra colorida introduzido com germoplasma de fibra branca e adaptado ao cultivo na região Nordeste. Entre as cultivares desenvolvidas, há uma com fibra na cor verde e as demais possuem fibra marrom em diferentes tonalidades. Por outro lado, a espécie G. barbadense L. possui acessos silvestres com cores diferentes daquelas de G. hirsutum L., tais como lilás e marrom púrpura, além de outras. Há alguns anos a Embrapa Algodão vem trabalhando com estes materiais. Assim, o objetivo deste ?documento? é apresentar os resultados obtidos utilizando esta espécie com doadora de cores na fibra. O programa de melhoramento do algodão de fibra colorida da Embrapa objetiva a obtenção de cultivares com novas tonalidades de cores utilizando métodos convencionais de melhoramento.

Composição das tortas oleaginosas comercializadas no Pará.

1970

Mycosphaerella areola - the Teleomorph of Ramularia areola of cotton in Brazil, and its epidemiological significance.

2016