Effect of manganese toxicity on growth and N2 fixation in groundnut, Arachis hypogaea

The development of manganese (Mn) toxicity symptoms and its effects on the growth, nodulation, and nitrogen fixation of groundnut genotypes were examined using a quartz-sand/solution culture system. The 11 genotypes tested all accumulated considerable concentrations of manganese (1.04–3.07 mg g^-1dry matter) when supplied with 15 μg Mn ml^-1of nutrient solution daily. Toxicity symptoms differed between genotypes: some showed no visual effects, some produced marginal leaf spots, and others developed marginal leaf spots coupled with an inward rolling of the margins of the younger leaves. The growth of one genotype (ICG 5394) grown with inorganic nitrogen as its source of N was more severely affected by Mn toxicity than when dependent on symbiotic fixation for its nitrogen.     

Growth and Nutrient Retranslocation in Needles of Radiata Pine in Relation to Nitrogen Supply

The effects of N application on tree growth and the retranslocationof N, P, and K from young needles to new growth were examinedin young radiata pine (Pinus radiata D. Don) trees. Nitrogen fertilization increased the number and size of needles,rates of shoot production, stem volume growth and tree biomass.Foliar N and P contents (µg per needle) fluctuated ina cyclic fashion with prominent phases of accumulation, retranslocationand replenishment. The patterns of these fluctuations in controland N-fertilized trees were similar, although the fluxes ofN, P and K in and out of needles were increased by N fertilization.Greater translocation (g per tree) of N and K from needles ofN fertilized trees occurred because fertilization increasedthe needle weight and the proportion of N and K retranslocatedfrom individual needles. Nitrogen fertilization increased theretranslocation of P largely as a result of higher needle mass.Trees supplied with more than adequate amounts of P in the soilretranslocated up to 58 per cent of the initial pool of P fromyoung needles. The periods of high retranslocation coincidedwith periods of high concentrations of soil mineral N and withshoot production. Conversely, the periods of rapid replenishmentof N and P into the needles coincided with the time of slowshoot growth and low concentration of soil mineral N. The growthrate of trees, rather than the availability of nutrients inthe soil was the main factor controlling retranslocation. For radiata pine, retranslocation from needles is not a mechanismspecific for coping with low soil fertility. It seems to bea mechanism which enhances the nutrient supply to apical growingpoints, especially during periods of flushing. Pinus radiata, nitrogen supply, shoot growth, nutrient fluctuations and retranslocation, nutrient use and adaptation     

Movement of Nutrients in Radiata Pine Needles in Relation to the Growth of Shoots

The pattern of needle growth and the movement of mineral nutrients(nitrogen, phosphorus, potassium and calcium) in needles ofradiata pine (Pinus radiata D. Don) were studied from needleinitiation to 2 years of age. During this period, very prominentcyclic patterns of nutrient accumulation, retranslocation andreplenishment were observed for nitrogen, phosphorus and potassium,which highlighted the potential role of needles as a nutrientreserve for growth. Significant retranslocation occurred from very young needlesabout 3 months after initiation. The phases of retranslocationcoincided with new flushes of shoot growth, and the growth ofnew shoots on a branch resulted in nutrient withdrawal frompre-existing needles, regardless of needle age and season. Suchwithdrawal occurred even in fertilized and irrigated trees onhigh quality sites and under environmental conditions conducivefor nutrient uptake. At all times, except for the short periodafter initiation when needles were actively growing, the nutrientsin the needle were readily available for retranslocation. Contraryto the general view, retranslocation of nutrients was not necessarilyrelated to senescence and ageing of needles. Because new shoots are the primary ‘sinks’ for retranslocatednutrients, an ongoing competition between different parts ofa branch for internal nutrients can be envisaged, preferencebeing for the youngest shoot in the hierarchy. The relevanceof these results to our understanding of ‘optimum nutrition’of pine trees is discussed. Pinus radiata D. Don, radiata pine, mineral nutrition, retranslocation, phosphorus, nitrogen, shoot growth     

Nitrate concentration and nitrate reductase activity in the leaves of three legumes and three cereals*

Nitrate concentration and nitrate reductase activity (NRA) were studied in the leaves of soybean (Glycine max), groundnut (Arachis hypogaea and cowpea (Vigna unguiculata) and sorghum (Sorghum bicolor), pearl millet (Pennisetum americanum) and maize (Zea mays) at three nitrogen fertiliser levels in two field experiments. Higher nitrate concentrations were detected in the leaves of groundnut, cowpea and pearl millet than in sorghum and maize. Nitrate content in the leaves and leaf NRA were not related across crop species, nor was a generalised pattern of leaf NRA and leaf nitrate observed within legumes or within cereals. Nitrogen application resulted in higher nitrate availability in the leaves, with varied leaf NRA.     

Epidemiological studies of Colletotrichum gloeosporioides disease of cocoa

The intensities of foliar infection (leaf blight and shot hole) and pod rot, caused by Colletotrichum gloeosporioides, were recorded from a cocoa-areca mixed garden and a cocoa-monocrop garden during 2 years. The intensity of pod rot was recorded from both the gardens. The intensities of leaf blight and shot hole gradually increased from July, reached a peak during September-November, decreased thereafter and reached the lowest level during April-June. Increase in leaf infection was associated in both plantings and in both years with the period of rain (June-November). The phylloplane population of C. gloeosporioides also increased during June-November when the temperature tended to be low and constant with high rainfall and relative humidity. During this period there were few susceptible stages of pods (cherelles and young pods) and pod infection was very low. Nearly mature pods were free from infection. I n both years, pod infection was more in the cocoaareca mixed garden than' in the cocoa-monocrop; it was observed during January-May, when the susceptible stages were mostly prevalent but when the C. gloeosporioides population was low and the climatic factors appeared to be relatively unfavourable. This may be one reason for the lesser incidence of pod rot when compared to foliar disease.     

Root Regeneration and Plant Water Status of Pinus radiata D. Don Seedlings Transplanted to Different Soil Temperatures

The regeneration and configuration of new roots on transplanted8 month old Pinus radiata D. Don seedlings were measured inrelation to soil temperature and time after transplanting. Theeffects of root wrenching and nutrition on root regenerationwere compared. Low soil temperature adversely affected the initiationand elongation of new roots. The branching and morphology ofthe new roots were also influenced by soil temperature. Theprocesses of initiation and elongation are greatly retardedbelow a critical root temperature between 11 and 14 ?C. Wrenchingand fertilization stimulated new root growth at low temperatures.There is a close interrelationship between the constituent partsof the network which forms the new root system. The first-orderlaterals on transplants are critical as a basic framework forextension and production of second-order laterals which formthe major part of the regenerating root system. Needle water potential was closely related to the new root growth.The water stress experienced by the transplants for severalweeks after planting was due primarily to the suppressive effectof low soil temperature on root regeneration. Wrenched plantswere less water-stressed than unwrenched plants. Field measurements confirmed the finding from controlled experimentsthat, in southern Australia, the low soil temperature in theplanting season imposes a major restriction on early root regenerationwhich in turn inflicts water stress in transplants. This needsto be considered during the planning of planting and fertilization.     

Factors affecting competition of three strains of rhizobia nodulating groundnut,Arachis hypogaea*

The nitrogen (N₂) fixing ability of three strains of rhizobia (NC 92, NC 43.3, and TAL 176) was compared in groundnut cv. Robut 33–1. The competitiveness of these strains in pot culture in a sand-vermiculite medium and with native rhizobia in the field was also investigated. In pot culture, NC 43.3 formed more nodules than TAL 176 and NC 92. Nodules formed by NC 43.3 and NC 92 fixed more N₂ (as measured by total N content in the plants at 42 days after sowing) than nodules formed by TAL 176. TAL 176 was a poor competitor compared with NC 92, NC 43.3, or with native rhizobia in the field. NC 92 when mixed with NC 43.3 (10⁶ cells seed^-1 of each strain) formed only 21% of the nodules, but when independently inoculated in the soil containing native rhizobia, the two-strains formed similar percentages of nodules. Thirty percent of the nodules in two strain combinations of NC 43.3 and NC 92 showed double occupancy. Strain NC 43.3 formed nodules earlier than NC 92 and TAL 176 and this may be one of the factors responsible for its better N₂-fixation and competitiveness. Nodules formed earlier by one strain (NC 92 or TAL 176) were found to have no effect on the subsequent nodulation by the other (TAL 176 or NC 92) strain. Although NC 92 and NC 43.3 were equally competitive with native rhizobia in the field and NC 43.3 fixed more N₂ than NC 92 in pot culture, earlier experiments indicated that only inoculation with NC 92 increased pod yield in field trials.     

Enumeration of rhizobia by enzyme-linked immunosorbent assay (ELISA)

The use of the enzyme-linked immunosorbent assay (ELISA) to enumerate rhizobia in peat carrier and in soil has been investigated. The ELISA technique takes less time than the conventional plant infection technique often used to enumerate rhizobia present in the presence of other micro-organisms. A minimum of 10₂–10₃ cells are required for a detectable ELISA reaction, limiting the use of this technique when the number of rhizobia is low.     

Ontogenic variation in nitrogen assimilation,nodulation and nitrogen fixation in groundnut (Arachis hypogaea) genotypes*

Seasonal pattern of acetylene reduction (AR) and shoot nitrogen accumulation was studied in nine groundnut cultivars. Shoot N accumulation by all the cultivars was maintained until shortly before maturity and it occurred faster over the reproductíve growth phase than over the earlier phases. In all cultivars plant AR (PAR) did not reflect this pattern of N accumulation, being greater over the vegetative and pod initiation phases. This suggests that the commonly observed low PAR values for groundnut over the reproductive growth phase may be the result of factors other than sink competition. There were significant interactions of cultivar with stage of crop growth for PAR, nodule mass, and specific nitrogenase activity (SNA). Virginia types generally showed better nodulation, higher N₂-fixing capacity (both PAR and SNA) than valencias, and significant differences were observed between cultivars within a botanical type.     

Genetic Differences in the Root Regeneration of Radiata Pine

The root regeneration capacity of eight open-pollinated familiesof radiata pine (Pinus radiata D. Don) was compared after transplantingeight month old seedlings to 8, 11 and 14 ° C soil temperaturefor 32 d. The results confirmed the major influence of soil temperatureon root regeneration. Families differed markedly in their abilityto initiate and grow new roots. Differences in the number ofnew root apices produced between the first and last rankingfamilies were ninefold at 8 ° C, threefold at 11 °Cand sevenfold at 14 °C. There was significant family x temperatureinteraction for new root length. The ability of some familiesto grow new roots at the warmer temperature of 14 °C didnot match their ability at 11 ° C and 8 °C. The weights of shoot and root at transplanting had no apparenteffect on the root regeneration capacity of the families studied.The important factors which contributed to genetic effects werethe renewed growth of the existing first order lateral rootsand the production of second order lateral roots on them. The root regeneration characters were highly heritable. Thelarge genetic difference and the high heritabilities in rootcharacters indicate the scope to exploit genetic effects onroot configuration in radiata pine to improve survival and earlyestablishment.