David J. Midmore

Aspects of bamboo agronomy

Abstract Various aspects of the growth and development of bamboo are reviewed,includ- ing growth cycles of plant parts,effects of aging on important plant tissues,uptake of water and nutrients,photosynthesis,storage and translocation of photosynthates and nutrients,and accumulation and partitioning of biomass and nutrients.Also discussed are how these aspects can be manipulated with agronomic techniques, such as management of standing-culm density,culm-age structure,leaf area,and leaf-age structure.Selected aspects of how the environment (i.e.,water availability), soil physical properties (such as slope,texture,bulk density,moisture-holding ca- pacity,and soil temperature),and soil chemical properties (such as pH,salinity,and nutrient availability)impact on bamboo production are outlined.This review also discusses how the environment can be managed with irrigation,terracing,tillage, covers and mulches,canopy adjustments,and fertilization with optimal amounts of nutrients,nutrient ratios,schedules,and forms of fertilizer.

Tissue Culture Studies of Tomato (Lycopersicon esculentum)

Tomato is a major vegetable crop that has achieved tremendous popularity over the last century. It is grown in almost every country of the world. Development of protocols for in vitro selection can provide new advances for the production of stress tolerant cultivars. Techniques have been optimised for the production of haploids and somatic hybrids. Attempts have also been made to transfer the higher regenerative ability of wild varieties to cultivated tomatoes. Although, some information is available on the morphogenesis of tomato, the techniques have not been developed to a level at which they can be utilised in large-scale multiplication of commercially important cultivars. The morphogenesis response seems to be highly dependent PGRs used in the media, which is again cultivar and genotypic specific. Somatic embryogenesis in tomato is still at its infancy, and efficient procedures for large-scale production via somatic embryogenesis are yet to be developed. Genetic stability of the tissue culture raised tomato plants also needs to be addressed. The use of a combination of molecular and conventional breeding techniques could be the option for the development of cultivars resistant to biotic and abiotic stresses. This paper reviews the advances made in various aspects of tissue culture in tomato. It also discusses the issues that still need to be addressed to utilise the full potential of plant tissue culture techniques in genetic improvement and mass propagation of tomato.

Oxygation Unlocks Yield Potentials of Crops in Oxygen‐Limited Soil Environments

Subsurface drip irrigation (SDI) offers well‐documented potential for improving water use efficiency in irrigated agriculture. However, SDI in common with other forms of irrigation is liable to exclude soil air (and therefore oxygen) around the root zone during and following irrigation events, thus reducing root function and crop performance. When SDI is practiced with oxygation (i.e., aerating the rhizosphere by way of the irrigation stream) it could transform the irrigation industry, for it provides a source of oxygen in a root environment that suffers from temporal hypoxia, and occasionally from anoxia. The oxygen is introduced into the irrigation stream by way of the venturi principle, or with solutions of hydrogen peroxide. Oxygation assures optimal root function, microbial activity, and mineral transformations, and leads to enhanced yield and water use efficiency under hypoxic conditions. It also improves plant performance and yield under irrigated conditions previously considered to be satisfactory for crop growth, and offers scope to offset some of the negative impacts of compaction and salinity, related to poor soil aeration, on crop growth. Representing minimal capital investment and recurrent costs, economic returns appear very favorable, as do associated benefits to the environment, measured as reduced drainage, containment of rising water tables, better nutrient use efficiency, and reduced demand by agriculture for irrigation water. The aeration status of irrigated soils deserves more attention than it has received in the past if we wish to unlock yield potential constrained by soil oxygen limitations and effect the yield increases essential to keeping pace with future food (and fibre) demand.

Aboveground and belowground competition between intercropped cabbage and young Eucalyptus torelliana

An expanding market for planted timber in the Philippines is providing a strong incentive for upland farmers to incorporate trees into their farming systems. Farmers often intercrop young timber species with well-fertilized annuals in expectation that inter- species competition for nutrients and light will be minimal while the trees are small, and that the trees will benefit from intensive nutrient and weed management of the intercrop. The relative level of aboveground and belowground competition in a vegetable/timber intercropping system was investigated in the uplands of Mindanao, the Philippines. Eight 5-m2 microplots were established containing one nine-month-old Eucalyptus torelliana and four rows of cabbage (two on each of the north and south sides of the tree, 0.5 and 1.0 m from the stem base). The tree canopy shaded north rows. Monocrop cabbage microplots (2 m2) were also installed. Four tree/cabbage microplots and all cabbage-only plots were fertilized with 15 5N-labeled ammonium sulfate (100 kg N ha−1); remaining microplots received unlabeled fertilizer. Cabbage yields were reduced by 16% in the north rows when compared to the south rows, and by 15% in rows closer to the tree when compared to rows further from the trees. Belowground competition in the first cabbage row, possibly for moisture, is supported by the high proportion of tree roots found in the top 30 cm of soil. Competition did not appear to be for N or other nutrients. Foliar analyses revealed no row differences in mineral concentrations in cabbage, uptake of applied N, or percent of N derived from fertilizer. The modest amount of 15N found in aboveground tree parts (4.5% of N applied to four cabbage rows) improved overall N-use efficiency in the intercropped plots. An improved understanding of the tradeoffs between improved nutrient efficiency and depressed intercrop growth, as well as management options to reduce competition, will help farmers design systems to improve efficiency without increasing competition.

EFFECTS OF GENOTYPE, EXPLANT ORIENTATION, AND WOUNDING ON SHOOT REGENERATION IN TOMATO

SummaryEffects of genotype and explant orientation on shoot regeneration from cotyledonary explants of tomato were studied using 10 commercially important cultivars. The explant orientation affected shoot regeneration in all the tested genotypes. Cotyledons placed in abaxial (lower surface facing down) orientation consistently produced better shoot regenerative response and produced greater numbers and taller shoots compared to those inoculated in adaxial (upper surface facing down) orientation. Genotypic variation in terms of shoot regeneration response, number of shoots, and shoot height was apparent. Wounding of cotyledonary explants increased shoot regeneration response. However, shoot height was much lower in shoots regenerated from wounded explants compared to those that originated from intact cotyledons. Shoots produced from wounded cotyledons were abnormal in their form and structure.

Carbon sequestration in a tropical landscape: an economic model to measure its incremental cost

Farm level rates of carbon sequestration are derived for timber and agroforestry systems based on Paraserianthes falcataria. An economic model is used to measure the incremental cost of carbon storage, based on the opportunity cost of land diverted from annual crop production. The method is applied to the Manupali watershed, in the Philippine province of Bukidnon, to estimate carbon storage potential and carbon storage costs at a landscape scale. Carbon storage via land use modification is calculated to cost between

An analysis of commercial vegetable farms in relation to sustainability in the uplands of Southeast Asia

3.30 per ton on fallowed lands and

Litter production, decomposition and nutrient release in cleared and uncleared pasture systems of Central Queensland, Australia

62.50 per ton on land that otherwise supports high value cropping. Carbon storage through agroforestry is less costly than via a pure tree-based system; a strong argument for the role of agroforestry rather than forestry per se, in re-forestation projects.

Source–sink manipulation to increase melon (Cucumis melo L.) fruit biomass and soluble sugar content

Abstract Commercial vegetable production systems in the uplands of Southeast Asia are important to supplement the demand for fresh vegetables in lowland Asian cities. A farm survey and soil sampling was done to characterise and identify major factors limiting vegetable productivity in the uplands of the Manupali watershed, Mindanao, the Philippines. Large yield differences were found among the four most common crops: tomato (Lycopersicon esculentum), cabbage (Brassica oleracea var. capitata), potato (Solanum tuberosum), and Chinese cabbage (Brassica pekinensis). The most closely correlated factors with crop yields were: nitrogen application rates for tomato and cabbage; topsoil per cent sand and fungicide usage for potato; and reliance on family labor for Chinese cabbage. Following multivariate data analysis, two vegetable farming systems were identified: the higher external nutrient (HEN) and the lower external nutrient (LEN) systems. To enhance their sustainability, both systems should adopt more appropriate soil conservation practices, cropping sequences, and plant protection techniques. Additionally, the LEN farmers should increase nutrient application, while the HEN farmers would benefit from labor saving technologies, crop diversification, and more judicious fertiliser application.

Impact of tree clearing on soil pH and nutrient availability in grazing systems of central Queensland, Australia

The temporal impact of clearing trees on litter production, litter decomposition and on C, N and P release through decomposition of litter was examined in the pasture systems of a semi-arid zone of central Queensland. Paired sites for cleared pastures (developed from clearing woodlands) and uncleared (intact woodland) pastures were selected to represent three dominant tree communities of the region i.e. Eucalyptus populnea, E. melanophloia and Acacia harpophylla, with three different time-since-clearing (5, 11–13 and 33 y) treatments. Yearly litter production was greater at uncleared sites (1732–1948 kg ha−1 y−1 for eucalypt and 2596 kg ha−1 y−1 for acacia communities) compared with cleared sites (1038–1282 kg ha−1 y−1 for eucalypt and 1100 kg ha−1 y−1 for acacia communities averaged over three time-since-clearing treatments). Rates of litter decomposition and of release of C, N and P from decomposing litter were higher at cleared than uncleared sites for all three tree communities. The cleared and uncleared sites did not differ significantly in total amount of C and N released per year since the concentrations of C and N were greater in litter from uncleared sites but the rate of release was less than that at cleared sites. Slow but continuous release of nutrients in eucalypt and acacia woodlands may be an adaptation of these communities to maintain the nutrient cycle and to avoid leaching of nutrients in the nutrient-poor soils of the region.