54 research outputs found
Effects of Olive Mill Wastewater on Soil Microarthropods and Soil Chemistry in Two Different Cultivation Scenarios in Israel and Palestinian Territories
Although olive mill wastewater (OMW) is often applied onto soil and is known
to be phytotoxic, its impact on soil fauna is still unknown. The objective of this study was
to investigate how OMW spreading in olive orchards affects Oribatida and Collembola
communities, physicochemical soil properties and their interdependency. For this, we
treated plots in two study sites (Gilat, Bait Reema) with OMW. Among others, the sites
differed in irrigation practice, soil type and climate. We observed that soil acidity and
water repellency developed to a lower extent in Gilat than in Bait Reema. This may be
explained by irrigation-induced dilution and leaching of OMW compounds in Gilat. In Bait
Reema, OMW application suppressed emergence of Oribatida and induced a community
shift, but the abundance of Collembola increased in OMW and water-treated plots. In
Gilat, Oribatida abundance increased after OMW application. The effects of OMW
application on soil biota result from an interaction between stimulation of biological activity and suppression of sensitive species by toxic compounds. Environmental and
management conditions are relevant for the degree and persistence of the effects.
Moreover, this study underlines the need for detailed research on the ecotoxicological
effects of OMW at different application rates
Fruit load governs transpiration of olive trees
We tested the hypothesis that whole-tree water consumption of olives (Olea europaea L.) is fruit load-dependent and investigated the driving physiological mechanisms. Fruit load was manipulated in mature olives grown in weighing-drainage lysimeters. Fruit was thinned or entirely removed from trees at three separate stages of growth: early, mid and late in the season. Tree-scale transpiration, calculated from lysimeter water balance, was found to be a function of fruit load, canopy size and weather conditions. Fruit removal caused an immediate decline in water consumption, measured as whole-plant transpiration normalized to tree size, which persisted until the end of the season. The later the execution of fruit removal, the greater was the response. The amount of water transpired by a fruit-loaded tree was found to be roughly 30% greater than that of an equivalent low- or nonyielding tree. The tree-scale response to fruit was reflected in stem water potential but was not mirrored in leaf-scale physiological measurements of stomatal conductance or photosynthesis. Trees with low or no fruit load had higher vegetative growth rates. However, no significant difference was observed in the overall aboveground dry biomass among groups, when fruit was included. This case, where carbon sources and sinks were both not limiting, suggests that the role of fruit on water consumption involves signaling and alterations in hydraulic properties of vascular tissues and tree organs.</p
The effect of avocado ( Persea americana
International audienc
Omega-6:3 Ratio More Than Absolute Lipid Level in Diet Affects Associative Learning in Honey Bees
Floral pollen is a major source of honey bee nutrition that provides them with micro- and macro-nutrients, including proteins, fatty acids, vitamins, and minerals. Different pollens vary in composition, including in the essential fatty acids, alpha-linolenic acid (omega-3) and linoleic acid (omega-6). Monocultures, prevalent in modern agriculture, may expose honey bee colonies to unbalanced omega-6:3 diets. The importance of omega-3 in the diet for adequate learning and cognitive function, with a focus on suitable omega-6:3 ratio, is well documented in mammals. We have recently shown, for the first time in invertebrates, the importance of omega-3 in diets for associative learning ability in honey bees. In the current work, we examine the effect of the absolute amount of omega-3 in diet compared to the omega-6:3 ratio on honey bee associative learning. We fed newly emerged bees for 1 week on different artificial diets, which had lipid concentration of 1, 2, 4, or 8%, with omega-6:3 ratios of 0.3, 1, or 5, respectively. We then tested the bees in a proboscis-extension response olfactory conditioning assay. We found that both omega-6:3 ratio and total lipid concentration affected learning. The most detrimental diet for learning was that with a high omega-6:3 ratio of 5, regardless of the absolute amount of omega-3 in the diet. Bees fed an omega-6:3 ratio of 1, with 4% total lipid concentration achieved the best performance. Our results with honey bees are consistent with those found in mammals. Best cognitive performance is achieved by a diet that is sufficiently rich in essential fatty acids, but as long as the omega-6:3 ratio is not high
The effect of avocado (Persea americana) nectar composition on its attractiveness to honey bees (Apis mellifera)
Honey bees are important avocado pollinators, but due to low attractiveness of avocado flowers pollination is often inadequate. Since honey is of nectar origin, we used it to test the effect of nectar composition on the preference of honey bees and we identified avocado honey due to its perseitol concentration. Bees preferred feeders containing non-avocado honey to avocado honey even when total sugar concentration in the avocado honey was higher. Crop loads were smaller for bees feeding on avocado than non-avocado honey. Finally, the learning performance of bees in a proboscis extension conditioning experiment was lower when they were rewarded with avocado honey than with non-avocado honey or sucrose solution. Moreover, only for avocado honey did the percentage of bees refusing to consume reward increase during the experiment. Our results indicate that honey bees prefer honey whose floral origin is of a competing flora over that of avocado. We conclude that avocado nectar composition may contribute to the low attractiveness of avocado flowers
Table_1_Omega-6:3 Ratio More Than Absolute Lipid Level in Diet Affects Associative Learning in Honey Bees.DOCX
<p>Floral pollen is a major source of honey bee nutrition that provides them with micro- and macro-nutrients, including proteins, fatty acids, vitamins, and minerals. Different pollens vary in composition, including in the essential fatty acids, alpha-linolenic acid (omega-3) and linoleic acid (omega-6). Monocultures, prevalent in modern agriculture, may expose honey bee colonies to unbalanced omega-6:3 diets. The importance of omega-3 in the diet for adequate learning and cognitive function, with a focus on suitable omega-6:3 ratio, is well documented in mammals. We have recently shown, for the first time in invertebrates, the importance of omega-3 in diets for associative learning ability in honey bees. In the current work, we examine the effect of the absolute amount of omega-3 in diet compared to the omega-6:3 ratio on honey bee associative learning. We fed newly emerged bees for 1 week on different artificial diets, which had lipid concentration of 1, 2, 4, or 8%, with omega-6:3 ratios of 0.3, 1, or 5, respectively. We then tested the bees in a proboscis-extension response olfactory conditioning assay. We found that both omega-6:3 ratio and total lipid concentration affected learning. The most detrimental diet for learning was that with a high omega-6:3 ratio of 5, regardless of the absolute amount of omega-3 in the diet. Bees fed an omega-6:3 ratio of 1, with 4% total lipid concentration achieved the best performance. Our results with honey bees are consistent with those found in mammals. Best cognitive performance is achieved by a diet that is sufficiently rich in essential fatty acids, but as long as the omega-6:3 ratio is not high.</p
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The role of macro-nutrients in olive tree flowering and fruit set
The independent effects of irrigation solution N, P and K concentrations on flowering and fruit set in olive trees (Olea europaea L. cv. Barnea) were studied over two successive seasons in a container experiment. Treatments included eight levels of N ranging from 5 to 202 ppm, seven levels of P from 0.2 to 20 ppm and seven levels of K from 10 to 208 ppm. At low concentrations of each of the minerals, additions led to large increases in their contents in leaves and, as the concentrations became high, relative increases in leaf accumulation were reduced. Availability of both N and P was found to influence flowering intensity in the olive trees while K had only a minor affect. Fruit set was affected by both N and P but not K levels. Total fruit load of olives was a function of combined flowering and fruit set levels. Fruit load increased to a maximum as leaf N increased from 0.8% to 1.77-1.56% and then decreased as leaf N increased to 2.1%-1.8% (2007 and 2008 respectively). The number of olives per tree increased appreciably as leaf P increased from minimum levels and relative increases in fruit load tapered at the highest measured leaf contents. Maximum fruit load was found corresponding to approximately 0.2% P. Fruit load was not influenced by leaf K concentration. The findings indicate that N and P play fundamental roles in processes affecting olive-tree productivity
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