Wild pollinators are declining and the number of managed honey bee colonies is growing slower than agricultural demands for pollination. Because of these contrasting trends in pollinator demand and availability, breeding programs for many pollinator-dependent crops have focused on reducing the need for pollinators. Although numerous crop varieties are now available in the market with the label of pollinator-independent, the real dependence of these varieties on pollinators is mostly unknown. We evaluated the hypothesis of pollinator independence in the Independence almond variety, the fastest growing variety in California that is the main almond production region in the world. In this presumed pollinator-independent variety, we measured the effect of honey bees on fruit set, yield, and kernel nutritional quality at tree level. Fruit set was 60% higher in bee-pollinated than bee-isolated trees, which translated into a 20% increase in kernel yield. Despite its effect on almond production, there was no evidence that bee visitation affected almond nutritional quality. Based on these results, we recommend the use of bees, whether they are wild or managed, to maximize yield even in self-fertile almond varieties.
Alamanda is a tropical flowering plant known for its bright yellow flowers. Proper pollination is crucial for alamanda plants to produce an abundant yield of flowers and seeds. In this article, we will discuss the basics of alamanda pollination and provide tips for maximizing pollination to boost your alamanda yield.
Alamanda, scientifically known as Allamanda cathartica, is a flowering vine or shrub native to Brazil. This plant is characterized by its shiny, dark green leaves and striking yellow trumpet-shaped flowers. Alamanda is a popular ornamental plant grown in tropical and subtropical regions for its showy blooms.
In addition to being cultivated for its aesthetic value, alamanda has some medicinal uses. Various parts of the alamanda plant have been used to treat malaria, diarrhea, insomnia, and skin irritations. The plant also produces an edible fruit, although it is not commonly consumed.
The Role of Pollination
Pollination is the process of transferring pollen grains from the anther (male part) to the stigma (female part) of a flower. This allows fertilization to occur and the plant to produce seeds and fruit.
For alamanda plants, pollination is necessary for the production of the eye-catching yellow blooms. Without successful pollination, the flowers will wilt and drop off. Good pollination leads to more flowers over a longer blooming period. It also enables the plant to produce fruits and viable seeds.
Maximizing pollination is key to getting a bountiful alamanda display and boosting your overall yield
Natural Pollinators for Alamanda
In the wild alamanda relies on various natural pollinators to transfer pollen between flowers. Common pollinators include
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Bees – Bees are often the most efficient pollinators. They actively collect pollen to bring back to their hive.
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Butterflies – Butterflies drink the nectar from flowers and inadvertently move pollen between blossoms.
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Hummingbirds – Hummingbirds have long beaks perfect for accessing nectar at the base of alamanda’s tubular flowers. Their wings and heads pick up pollen in the process.
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Bats – In some tropical regions, nectar-feeding bats pollinate alamanda flowers at night.
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Beetles – Small beetles are also known to act as minor pollinators for alamanda.
In a cultivated environment, you may need to supplement natural pollination to maximize your alamanda yield.
Supplementing Pollination
Here are some tips for supplementing natural pollination of your alamanda plants:
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Attract pollinators – Create an environment that invites pollinators by planting a diversity of flowering plants and providing habitat like nesting boxes. Avoid pesticide use.
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Hand pollination – Use a small brush to manually transfer pollen from one alamanda flower to another. This is time-consuming but effective.
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Air circulation – Use fans to circulate air around plants, which helps distribute pollen.
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Plant close together – Ensure alamanda plants are grouped closely together so pollinators can easily move between them.
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Vibrate flowers – Gently shake flower clusters daily to promote pollen release and distribution.
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Honey bees – You can rent a beehive during alamanda’s bloom period to maximize pollination.
When to Pollinate
Alamanda typically blooms during the warm summer months. Pollination should be supplemented during peak flowering to boost yields.
In ideal conditions, alamanda can flower nearly year-round. Focus pollination efforts during heavy bloom periods, usually mid-summer. Alamanda blooms in the morning, so late morning is the best time for pollination.
Monitor your plants closely to identify when flower buds emerge and blooms open. Pollinate daily while the plant is actively flowering.
Signs of Successful Pollination
How can you tell if your pollination techniques are working? Watch for these signs to confirm successful alamanda pollination:
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Fruit production – Pollinated alamanda flowers will develop into green oval fruits. Each fruit contains dozens of small seeds.
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Flower retention – Successfully pollinated flowers last longer on the vine instead of quickly wilting and dropping.
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Continuous blooming – Adequate pollination means new flower buds keep developing, leading to a longer bloom season.
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Seed viability – Check harvested seeds for proper development. Well-pollinated flowers produce plump, healthy seeds capable of germinating.
Maximizing pollination leads to more fruits, extended flower production, and viable seeds from your alamanda.
Common Causes of Poor Pollination
If you notice low flower count, premature flower drop, or lack of fruit on your alamanda, poor pollination may be the culprit. Some common causes include:
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Limited pollinators – Your environment may lack sufficient bees, butterflies, hummingbirds, etc. This restricts pollen transfer.
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Poor weather – Excessive heat, cold snaps, or heavy rain during flowering can inhibit pollinator activity.
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Pesticide usage – Chemical pest control impacts pollinators, reducing their numbers and pollination effectiveness.
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Inadequate sunlight – Alamanda needs full sun to bloom abundantly. Too much shade limits flowering and pollination.
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Nutrient deficiencies – Lack of nutrients like nitrogen leads to reduced flowering and pollen production.
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Pollen incompatibility – When growing multiple alamanda varieties, pollen from different plants may be incompatible, preventing pollination.
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Diseases – Fungal or bacterial diseases can affect flower viability and pollen transfer.
Addressing these underlying issues can help improve pollination rates.
How to Harvest Alamanda Seeds
With successful pollination, your alamanda plant will produce numerous round green fruits. Each fruit contains dozens of small black seeds which you can harvest.
Follow these steps for collecting alamanda seeds:
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Allow fruits to ripen completely on the plant before harvesting. Ripe fruits turn yellow and split open when gently squeezed.
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Pick ripe fruits and place them in a bowl. Crush lightly with your hands to separate the pulp and expose seeds.
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Add water to the bowl and mix. Let sit for 15 minutes, then pour off the pulp and debris, leaving clean seeds behind.
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Spread seeds out on paper towels and allow to dry for 1-2 weeks.
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Store thoroughly dried seeds in an airtight container in a cool, dry place. Seeds remain viable for up to a year.
Saving and planting alamanda seeds is an easy way to propagate new plants identical to the parent.
Troubleshooting Pollination Issues
Sometimes you may need to troubleshoot pollination problems to improve your alamanda yield. Here are some tips:
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Monitor pollinators – Identify if there are sufficient bees, butterflies, etc to pollinate flowers. Supplement if needed.
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Test pollen viability – Check under a microscope that pollen grains are round and yellowish. Misshapen, collapsed grains indicate unviable pollen.
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Check flower parts – Examine flowers to ensure the pollen-producing anther and pollen-receiving stigma are intact and functional.
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Control pests – Monitor for flower-damaging pests like thrips, aphids, or flower beetles. Use insecticidal soap or neem oil to control infestations.
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Treat diseases – If bacterial or fungal diseases are reducing flower viability, use appropriate organic pesticides. Improve air circulation.
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Adjust sunlight – Increase sunlight with pruning or relocation if inadequate light levels are limiting flowering.
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Test soil nutrients – Poor nutrition inhibits flowering. Have soil tested and amend accordingly with compost and organic fertilizer.
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Review variety compatibility – For multi-variety plantings, check that different alamanda varieties are cross-compatible. Isolate incompatible plants.
With a little troubleshooting, you can get your alamanda pollination back on track and achieve a bountiful bloom.
Successful pollination is the key to maximizing alamanda’s yield of flowers, fruits, and seeds. Natural pollinators like bees, birds, and bats facilitate pollen transfer in the wild. In cultivated gardens and farms, steps like attracting pollinators, hand pollination, and using hives can supplement natural pollination.
Monitor for signs of effective pollination like fruit production, flower retention, and viable seeds. Troubleshoot issues like insufficient pollinators, weather, p
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Dependence on animal pollination is increasing in global agriculture1. In 2005, the total estimated value of pollination worldwide was about $172 billion and accounted for nearly 10% of the world’s agricultural crop production consumed by humans2. However, this percentage is increasing year after year as the area cultivated with pollinator-dependent crops is continuously expanding3. Unfortunately, wild pollinators are declining whereas managed honey bees are growing slower than agricultural demands for pollination4,5. Because of these uneven trends in pollinator demand and availability, breeding programs for many pollinator-dependent crops are targeted to reducing the need of biotic transfer of pollen for ovule fertilization, and thus for seed and fruit production. Many varieties of several typically pollinator-dependent crops are now available in the market with the label of “self-fertile” and sold as pollinator-independent. However, the extent to which these varieties depend on pollinators for either yield quantity or quality under field conditions is unknown.
Almond (Prunus dulcis) production in California, USA, clearly illustrates this trend. California produces more than 80% of world’s almonds, and the area devoted to this crop is continuously growing6,7. For decades, almond varieties cultivated in California have been self-incompatible and growers have relied almost exclusively on managed honey bees (Apis mellifera) for pollen transfer and effective pollination8,9. Because of almond’s high pollinator-dependence and high-market value, more than a million honey bee colonies are moved to California from all over the U.S. every season, representing the largest man-driven pollination event in the world10,11. However, the number of honey bee colonies has been dwindling in the U.S. over the last decades12. Although new evidence is showing that the number of colonies has stabilized during the last years13, beekeepers are still dealing with several health problems affecting honey bees. These health problems can be related in part to long-distance colony movement, which facilitates the spread of pathogens14. In parallel, the almond-cultivated area has expanded and demands for almond pollination services have increased6,10,11. Because of these opposing trends, the average rental rate for single honey bee colony has increased from ~$70 in 1995 to an average of ~$180 in 201810,15. After accounting for inflation, costs of renting colonies are now ~60% higher than two decades ago7,10,15.
Under this scenario, the self-fertile almond variety named Independence (IndependenceR (Alm-21 cv.) Patent no. 20295) was developed, becoming increasingly popular among Californian growers16. This was meant to be a massive breakthrough for almond industry, because this new variety was advertised as bee-independent due to self-fertility and its presumed high capacity for autonomous self-pollination7,17,18. Thus, cultivation of this variety would, in principle, benefit growers by removing the costs of renting bee colonies, among other advantages. In fact, the area cultivated with self-fertile Independence increased exponentially since its release in 200816. However, despite claims of bee-independence, there is an information gap on the real pollinator dependence of this fast-growing almond variety.
Given the profound impact that replacements of self-incompatible by self-compatible crop varieties can exert on production, food quality and beekeeping financial well-being, an accurate evaluation of pollinator dependence on much promoted bee-independent varieties appears as a straightforward priority. Here, we measured the effect of bees on fruit set, kernel yield, and kernel nutritional quality on the “self-fertile” Independence almond variety. If this variety were fully self-fertile and capable of autonomous self-pollination, we should observe a similar fruit set, and kernel yield and quality in trees visited as in those not visited by bees.
Thirty almond trees of the Independence variety were used in our experiment. Ten trees were entirely covered with a fine mesh normally used by growers to isolate citrus trees from bees (henceforth “isolation treatment”). Another ten trees were partially covered with a mesh above, without interfering with bee visitation to flowers but to control for possible effects of irradiation and frost (henceforth “control treatment”). The remaining ten trees were kept open to bees (henceforth “open treatment”; see Fig. 1 and Supplementary Information S1). Honey bee colonies were placed at a stocking rate of five colonies/ha surrounding the experimental study fields, which is a standard stocking rate for self-incompatible varieties19.
Aerial s of the experimental setup. Left , almond fields with experimental trees. Right , a closer look of the treatment “blocks”, consisting of a group of three neighboring trees, each one randomly assigned one the three different pollination treatments.
During flowering, we quantified visitation rate of bees to flowers in open and control trees. We recorded only flower visitors that contacted anthers and/or stigma. After flowering, we quantified initial and final fruit set (i.e., proportion of flowers setting a fruit) in all thirty trees. Finally, during harvest, we quantified almond yield (i.e., the entire kernel production at tree level) and nutritional quality. Because the main components in almond used to value its nutritional quality are fats, and particularly the proportion of oleic to linoleic fatty acids, here we analyzed the oleic to linoleic fatty acid ratio of dry kernels (see M&M).
Managed honey bees accounted for all flower visits to the self-compatible Independence almond variety. We did not find evidence that bee visitation differed between open-pollinated and mesh-control trees (in log scale, β = −0.29, SE = 0.31, Z = −0.92, P = 0.35), with an observed mean (±SE) of 0.05 ± 0.010 and 0.04 ± 0.008 visits · flower−1 · 5 min−1, respectively. Taking into account that almond flowers remain open for about 4–6 days and were visited during ~5 h each day, this visitation rate represents approx. 12–18 visits during a flower’s lifespan.
Initial and final fruit set
Bee visitation had a positive effect on the likelihood of a flower setting a fruit. Initial fruit set (about three weeks after the end of flowering) was ~90% higher in bee-pollinated than bee-isolated trees (in logit scale, β = 1.70, SE = 0.17, Z = 9.65, P < 0.001; and β = 1.62, SE = 0.17, Z = 9.23, P < 0.001; for comparisons between the isolation and open, and isolation and control treatments, respectively). Also, initial fruit set did not differ significantly between open-pollinated and mesh-control trees (in logit scale, β = −0.08, SE = 0.18, Z = −0.44, P = 0.89). Initial fruit set in isolated trees was, on average (±SE), 0.42 ± 0.02 fruits/flower, and in open-pollinated and mesh-control trees was 0.79 ± 0.01 and 0.78 ± 0.01 fruits/flower, respectively (Fig. 2, gray points). Final fruit set (i.e., before harvesting) was ~60% higher in bee-pollinated than bee-isolated trees (in logit scale, β = 0.63, SE = 0.18, Z = 3.37, P = 0.002; and β = 0.75, SE = 0.18, Z = 4.03, P < 0.001; for comparisons between the isolation and open, and isolation and control treatments, respectively). Also, final fruit set of open-pollinated and mesh-control trees was not statistically different (in logit scale, β = 0.12, SE = 0.18, Z = 0.66, P = 0.78). Final fruit set in isolated trees was, on average (±SE), 0.19 ± 0.01 fruits/flowers, and in open-pollinated and mesh-control trees was 0.30 ± 0.02 and 0.33 ± 0.02 fruits/flower, respectively (Fig. 2, white points). Even though many fruits abort early on during development, increases in fruit set in bee-pollinated trees persist until fruit maturity.
Initial and final fruit set per pollination treatment. Effects of the pollination treatment (isolation, open and control) on initial (gray) and final (white) fruit set. Points represent mean values and bars represent two standard errors.
Increases in fruit set translated into increases in kernel yield in bee-pollinated trees. Kernel yield (i.e., estimated as total fruit mass produced per tree times the proportion of the fruit weight represented by the kernel; see Supplementary Information S3) was ~20% higher in bee-pollinated than bee-isolated trees (β = 1.04, SE = 0.39, t = 2.65, P = 0.01; and β = 0.82, SE = 0.33, t = 2.45, P = 0.02; for comparisons between the isolation and open, and isolation and control treatments, respectively). Mean (±SE) kernel yield in isolated trees was 4.49 ± 0.18 kg · tree−1, whereas kernel yield in open-pollinated and mesh-control trees was 5.53 ± 0.39 and 5.31 ± 0.33 kg · tree−1, respectively (Fig. 3), with no statistical differences between these two latter treatments (β = 0.003, SE = 0.006, t = 0.63, P = 0.802).
Quantitative yield per treatment. Effects of the pollination treatment (isolation, open and control) on mass production of kernels at tree level. Points represent mean values and bars represent two standard errors.
Despite effects on almond quantity, there was no evidence that bee visitation affected almond quality. Specifically, mean (±SE) ratio of oleic to linoleic acid in kernels from isolated trees was 2.63 ± 0.04, a similar ratio to that found in kernels from trees pollinated by bees (β = −0.11, SE = 0.06, t = −1.87, P = 0.16; and β = −0.05, SE = 0.06, t = −0.89, P = 0.64; for comparisons between the isolation and open, and isolation and control treatments, respectively). Mean (±SE) ratio of oleic to linoleic acid in kernels from open-pollinated and mesh-control trees was 2.52 ± 0.06 and 2.58 ± 0.06, respectively, with no statistical differences between these two treatments (β = 0.05, SE = 0.06, t = 0.92, P = 0.62). Therefore, whereas bee pollination affected almond seed quantity, it did not seem to affect seed quality.
Self-fertile almond varieties are becoming increasingly popular among growers and, consequently, their cultivated area is increasing at a high rate16. However, studies estimating true pollinator dependence in tree crops are still scarce. This may relate to the complexity of conducting this estimation at the level of entire trees, like we did here. Most studies assessing pollinator dependence in multi-flowered plants compare fruit or seed set between isolated and open-pollinated individual flowers or inflorescences, which can lead to overestimation of pollinator dependence due to the possibility of resource translocation20. Here, we evaluated the hypothesis of pollinator independence in the Independence almond variety, which is the fastest growing variety in California, in turn, the most important almond production area globally16. When bee visitation to Independence trees was curtailed, trees did in fact produce many fruits. Nevertheless, honey bee visits to almond flowers of this variety increased yield substantially. This result implies that growers will be experiencing lower crop yields if bees are not present in areas where this variety is cultivated, and thus, the hypothesis of complete pollinator independence should be rejected.
Until recently, all almond cultivars were self-incompatible, characterized by a gametophytic system controlled by a S-locus21. For this reason, almond orchards include a mix of different interfertile varieties, honey bees being a required input to ensure cross pollination. Approximately, 80% of the U.S. honey bee colonies have been used for almond pollination in California during 201822. In turn, pollination services for the almond industry represent one third of the U.S. beekeeping incomes, and many beekeepers rely to a great extent on the almond pollination market for profit23. As a consequence, almond growers and beekeepers have developed a strong inter-dependency.
Given the potential economic benefits for almond growers resulting from the disruption of their partnership with beekeepers, autonomous self-pollination and self-fertility have been priority target traits in almond breeding programs, traits which not only avoid costs of renting colonies but also facilitate management though the cultivation of monovarietal plantations18,24,25,26. Although most of the new varieties decreased dependency from bees, they did not seem to achieve total pollinator independence. They did, however, allow growers to decrease stocking rates of managed honey bee colonies per cultivated area and to overcome production costs involved in inter-varietal mixing23. The Independence variety was expected to achieve the ultimate goal of not requiring bee visitation for maximizing yield and income, and was advertised accordingly17,18. However, here we provide evidence that this variety could be truly self-fertile but not totally pollinator independent, probably because of incomplete autonomous self-pollination.
The impact of misleading information on the true pollinator dependency of the Independence variety could be detrimental for almond growers and beekeepers in terms of potential profits, labor losses, and social conflicts. First, misinformation on decreased honey bee usage could lead to a reduction in profits for almond growers, because non-bee visited trees will translate into yields lower than maximum potential. After considering kernel yield per tree, the differential price related to kernel class size and colony renting costs (see Supplementary Information S4), bee pollination still translated into differences of about 20% and 10% in gross and net profit (i.e., without and with consideration of renting colonies), respectively. These economic benefits were observed in young trees (i.e., below their yield potential), and thus, the benefits could be even higher in full production plantations. Therefore, bee pollination affected positively the yield and economic profit in this self-fertile almond variety. Second, if Independence continues growing and replacing self-incompatible varieties, many beekeepers may lose one of their key annual incomes, threatening their financial well-being. This could lead, eventually, to the loss of one the most important incentives for maintaining beekeeping industry in the U.S. and the narrowing of a work source for beekeepers. Third, honey bees from colonies rented by neighboring growers would visit Independence plantations, which will dilute bee density in fields cultivated with the self-incompatible almond varieties. This could represent an advantage for Independence almond growers, because the presence of these honey bees will increase their yields at no cost. At the same time, this could cause yield drops for those growers that actually paid for the pollination service. This scenario could generate social conflicts between neighboring growers, particularly being aware of the casual benefits received by their neighbors.
One critical question regarding crop varieties is their nutritional quality. Brittain et al.27 showed that self-pollinated almond trees produce almonds with lower nutritional quality, in terms of their fat composition, than those produced by cross pollination. However, we did not detect a sizable effect of bee pollination on almond nutritional quality in this study. Differences in results could be attributed to the variety studied, because Brittan et al.27 worked with Nonpareil, the most commonly planted self-incompatible variety in the U.S., and we did it with self-compatible Independence. In terms of fat composition quality, oleic to linoleic ratio estimated in the present work for Independence was, on average, 2.5, which is within the ranges (i.e., 1.79–3.79) estimated for all the varieties cultivated in California28. Therefore, any effect of bees on production in this self-compatible crop variety seems to occur through increases in yield quantity rather than in nutritional quality.
Concerns about the decline of wild pollinators, increasing cost of colonies, and stability in food production caused the introduction of self-compatibility and self-pollination traits as key factors in many plant breeding programs5,24,25,26. Although nowadays there are many varieties available in the market with the “self-fertile” and “pollinator independent” labels, the real dependence on pollinators was not rigorously estimated in most cases. Misleading information from nursery companies on pollinator dependency levels can trigger cascading effects among growers and beekeepers like we describe above. Under this context, reliable and precise information is crucial for profit maximization and socio-economic stability. Breeding programs are clearly reducing pollination dependence for ensuring food production, but bees are still needed for full fertilization. Based on our results and their implications, we highly recommend to almond growers the use of bees, whether they are wild or managed, to maximize yields, even in self-fertile almond varieties.
The experiment was carried out from February to August 2018. The site was located in Kings County (36° 21.698′ N, 119° 42.263′ W) California, USA. We selected young almond trees for this experiment, because kernel quantity and quality of whole trees can be measured, and accumulated resources are limited in smaller trees29,30, which make any test on pollinator dependence more conservative. Two 20-ha plots planted with 50–50% of Nonpareil – Independence tree varieties were used to perform the experiment. Sampled trees were approximately 4-m tall and had been harvested twice before this study. Honey bee colonies were placed at a stocking rate of five colonies/ha surrounding the experimental study site and were part of the commercial pollination management system used by the grower.
To evaluate honey bee effects on fruit set, and kernel yield quantity and quality at tree level, we randomly selected 30 experimental almond trees of Independence variety on two plots (i.e., 15 trees per plot). To each tree, we assigned one of the following treatments: (i) isolation (i.e., trees were isolated from bees by covering them with a fine mesh 10% Crystal, Green-tek, Sultana, California 93666), (ii) open (i.e., trees were kept open to bees), and (iii) control (i.e., trees covered with mesh above and along a fringe on the sides, without interfering with bee visitation, to control for effects of the net on attenuating irradiation and frost) (see Fig. 1 in main text and Supplementary Information S1). Each treatment (isolation, open, control) was replicated in 10 trees. Treatments were set in “blocks”, consisting of a group of three neighboring trees, each one randomly assigned one the three different pollination treatments (see Fig. 1 and Supplementary Information S1). In the isolation and control treatments, trees were mesh-covered before blooming started and the mesh immediately removed after bloom was over.
Allamanda Plant Care, Allamanda Flower || How to Grow Allamanda flowers in Pots.
FAQ
How do I get more flowers on the allamanda plant?
What pollinates allamanda?
Where is the best place to plant allamanda?
What is the best fertilizer for allamanda plants?
Is Alamanda a good plant?
This beautiful plant produces vibrant yellow flowers that bloom in clusters, making it a popular choice for gardens and indoor spaces alike. However, like all plants, alamanda requires proper care and attention to ensure healthy growth.
How to plant Alamandas?
Before planting the alamandas in your yard, garden, vegetable garden, or terrarium, make sure that the soil is at least 70 centimeters deep. Also provide supports or stakes for the branches of the vine if it is not to be planted near walls, pergolas, fences, or the like.
Can Allamanda be propagated from seed?
Allamanda plants can be propagated from seed or from cuttings. Propagating from seed is the most common method. To propagate Allamanda plants from seed, start by collecting the seeds from a mature plant. The seeds should be sown in a well-draining potting mix and kept moist. The seeds will germinate in about two to three weeks.
Which Allamanda plant should you choose?
If you want to add more color to your landscape, you should definitely check out the allamanda bush! This impressive tropical plant with golden-yellow flowers can perfectly decorate any area. In addition to a beautiful yellow color, you can also choose other allamanda varieties that produce red or purple flowers.