, leaves, and flowers of
Averrhoa carambola Averrhoa carambola is a small, slow-growing evergreen tree with a short-trunk or a shrub. The branches are drooping and the
wood is white and turns reddish. It has a bushy shape with many branches producing a broad, rounded crown. The compound leaves are soft, medium-green, they are spirally arranged around the branches in an alternate fashion. The pinnate leaves have a single terminal leaflet and 5 to 11 nearly opposite leaflets, each leaf is 15–20 cm long, and the 3.8–9 cm long leaflets are ovate or ovate-oblong in shape. The top sides of the leaves are smooth and the undersides are finely hairy and whitish. The leaflets are reactive to light and tend to fold together at night, they are also sensitive to abrupt shock and when shaken tend to close up also. The lilac or purple-streaked, downy, flowers are produced in the axils of leaves at the end of twigs. The flowers are arranged in small clusters on the ends of the branches or sometimes on the larger stems and trunk, each cluster is attached to the tree with red stalks. The bell-shaped, perfect flowers, are produced in loose panicles that are much-branched with pedicellate flowers; each flower is around 6 mm wide, with five petals that have recurved ends. The fruits are showy with an oblong shape: they are longitudinally five to six-angled and 6.35–15 cm long and up to 9 cm wide. The fruits have a thin, waxy skin that is orange-yellow colored. The juicy fruits are yellow inside when ripe and have a crisp texture and when cut in cross-section are star-shaped. The fruits have an oxalic acid odor, which varies between plants from strong to mild, the taste also varies from very sour to mildly sweetish. Each fruit may have up to twelve 6–12.5 mm long seeds, which are flat, thin and brown. Some cultivated forms produce fruits with no seeds.
Rapid plant movement Rapid plant movement is seen in many plants and there are different mechanisms based on the speed of the movement and the situation the plant is in. Some plants may make movements within 2 seconds while some may take 20 seconds to complete a motion. Additionally, for some plants the movement can involve action potentials being activated, or it can involve changes in water pressure and fluctuation of ions moving in and out of cells. In the case of the
Averrhoa carambola plant it takes about 20 seconds for the leaves to move from their horizontal position to vertical. This mechanism involves the flux of ions and water. When the leaves receive an external stimulus (hands, herbivores) this will translate to an electrical stimulus which then leads to the flow of ions (specifically the potassium and chloride) out of the pulvinus. Within the pulvinus, there are flexor and extensor cells, and this is where the change of potassium and chloride concentration occurs. So as you can see in the diagram [where is the diagram?], when the cell is in its turgid state, the leaves are horizontal, and cells are filled with water. So when the chloride and potassium move out of the cells, the water will flux out which results in the leaves facing vertically. This movement of the leaves drooping takes only a couple of seconds as we saw in the video.{which video?] However, when the leaves or the tree is shaken, this will activate contractile proteins that are in the pulvinus, and they will cause the leaves to droop. There are a few benefits of the drooping of the leaves: one is that it has been hypothesized that when the leaves droop it makes the plant look malnourished and unappealing, so herbivores are compelled to eat a different plant. Additionally, the movement helps the plant with reducing water loss as well as avoid damages. The mechanism and reasoning for how this movement reduces water loss for plants is not fully known. However, one known mechanism is the closing of the stomatal pores which are the mouths of the plant in which gas exchange occurs. It takes in carbon dioxide which is important for photosynthesis. This movement of the stomatal pores is done by the guard cells that surround the pores. When there is not enough water in the air, the guard cells well release K+ ions into surrounding cells, and this causes water to move out of the guard cells. After the water is moved out the guard cells shrink in size as well as the stomata pores, and this prevents water from escaping through the pores. This information was obtained through Yahyai's research on the starfruit tree's response to differing soil water depletion levels. Trees were grown in a greenhouse, and there were four levels of soil water depletion. Stomatal response, levels, and transpiration were recorded and then analyzed. Finally, the drooping movement in the star fruit trees helps with reducing leaf damage, protecting it from increased leaf temperature, as well as losing photochemical efficiency (light energy being converted to be used for photosynthesis) from the sun. Excess radiation will act as a stimulus to these leaves, and they will respond with rapid movement. The leaf moving to a position that makes it parallel to the light source is important because the leaves will not be directly facing the sun. This information was found through recording sun to leaf area exposure, canopy diameter, and root growth. Trees had different levels of sun exposure, and how the tree responded was measured and analyzed. ==Distribution==