A2 WJEC BIOLOGY UNIT 4 Sexual reproduction in plants Biology Department - Gower College Swansea The generalised structure of flowers to be able to compare wind and insect pollinated flowers Learners should be able to recognise and label a halfflower of a typical regular, diocotyledonous, insect pollinated flower to include: receptacle, calyx, sepal, corolla, petal, stamen, filament, anther, carpel, ovary, ovule, style and stigma. They should be able to identify differences between an insect and a wind-pollinated flower in terms of function of flower parts and adaptations to different methods of pollination. The development of pollen and ovules, including examination of prepared slides of anther and ovary The role of mitosis and meiosis in the development of pollen grains in an anther to include: mitosis to produce large numbers of pollen mother cells followed by meiosis to produce a tetrad of four haploid cells; the role of the tapetum in pollen grain development; development and structure of a mature pollen grain, including subsequent mitotic divisions of the nucleus; dehiscence and pollen dispersal. The role of mitosis and meiosis in the development of an ovule in the ovary to include: meiosis of a megaspore mother cell in the nucellus to produce four haploid megaspores; the growth and subsequent development of one of the megaspores including three mitotic divisions to produce eight haploid nuclei within the embryo sac. Learners should be able to recognise structures in a mature ovule to include: funicle, integuments, micropyle, embryo sac, female gamete, two synergids, two polar nuclei, three antipodal cells.
Cross and self-pollination Pollination is the transfer of pollen from an anther to a stigma. Learners should understand the genetic consequences of self-pollination and cross-pollination and appreciate how meiosis and random fertilisation result in increased genetic variation through cross-pollination. There are different adaptations of flowers that promote cross-pollination. These include irregular flower structure and chemical self-incompatibility. Learners should understand the events following pollination to include: mitosis of the pollen grain nucleus to produce two male gametes and a pollen tube nucleus germination of a pollen grain on a compatible stigma; growth of a pollen tube (under the control of the pollen tube nucleus) through the digestion of the style through the secretion of hydrolase enzymes entry of the pollen tube into the embryo sac through the micropyle. Both male gametes are involved in separate fertilisation events: one male gamete enters the embryo sac and fuses with the female gamete to produce a diploid zygote the second male gamete fuses with the two polar nuclei to form a triploid primary endosperm nucleus. The formation and structure of seed and fruit as shown by broad bean and maize The events that take place following double fertilisation to produce seeds and fruits include: the ovule developing into a seed; the diploid zygote divides by mitosis to form the diploid embryo, consisting of plumule, radicle and one or two cotyledons; the triploid endosperm nucleus divides by mitosis to form endosperm tissue, an important food storage tissue in cereal grains, e.g. wheat; the integuments develop into the testa; the micropyle remains as a pore in the testa the ovary wall develops into a fruit wall enclosing the seeds. Learners should be able to identify and label diagrams of broad bean and maize seeds to include: hilum (scar of the funicle), micropyle, testa, position of radicle, plumule, cotyledons. Seeds have evolved as a survival strategy for a terrestrial mode of life. Plants have developed different mechanisms to enable the dispersal of seeds. This reduces competition following germination and increases the chance of growth into mature plants.
The process of germination of Vicia faba (broad bean) Seeds can remain dormant until suitable conditions are present, i.e. availability of water, oxygen and a suitable temperature. Germination involves the rapid onset of biochemical activity and growth of a seedling until the plant can carry out photosynthesis and become independent of the food stores contained in the cotyledons. The stages of germination in a non-endospermic seed, e.g. broad bean include: water being imbibed through the micropyle; the cotyledons swelling and the testa being split to allow entry of more oxygen for aerobic respiration; food reserves from the cotyledons, starch and proteins, are mobilised through hydrolysis (and also lipids in some seeds); providing sources of energy for respiration and growth of the plumule and radical. In endospermic seeds, e.g. maize, gibberellin, a plant hormone, is involved in the process of germination: following imbibition of water gibberellin is released by the embryo and diffuses to the aleurone layer which contains proteins; gibberellins induces the production of hydrolytic enzymes, e.g. amylase which break down stored nutrients glucose and other nutrients diffuse to the embryo where they are used in aerobic respiration and
The structure of insect and wind pollinated plants Diagram of the key features of an insect pollinated angiosperm flower Carpel Summary points on the structure of the flower The anther is the male reproductive organ and is where the male gamete is formed. The carpel is the female reproductive organ. The petals are brightly coloured to attract insects for pollination. The flower may also release a scent to attract pollinators. They have receptacles containing nectar as a reward for insects. The ovary is where the embryo will develop after fertilisation in a structure called the embryo sac which is found in the ovule. Angiosperm plants and insects are a good example of co-evolution in regards to pollination. This means that both the plant and the insects have adaptations to encourage and facilitated the transfer of pollen. Adaptations include: Brightly colored petals to attract insects. Sweat nectar for the insect to feed on. 'landing platform' and nectar guides that show the insect where to land and where to search for nectar
Diagram of the key features of a wind pollinated grass flower A comparison of the structures of wind and insect pollinated plants. Insect pollinated plants Wind pollinated plants
Structure of the anther and development of the male gametes (pollen) The anther consists of 4 pollen sacs/microsporangium in which pollen grains are made. The tapetum is a layer of large cells, often multinucleate, which are involved in supplying nutrients to the developing pollen grains. The pollen sac spontaneously opens when the pollen grains are mature, releasing them for transfer to the stigma. This opening and release is called dehiscence.
The pollen grain contains the male gamete this is called the generative nucleus. This divides later by mitosis to form 2 sperm nuclei. the pollen grain also contains the tube nucleus. The tube nucleus controls the development of the pollen tube The pollen grain has a highly textured surface called the exine. The pollen grain protects the generative nucleus from desiccation. The textured surface of the pollen grain aids in it s attachment to the stigma. The pollen grain is the vehicle to transport the male gamete (generative nucleus). Scanning electron micrograph of the surface of pollen grains.
The structure of the carpel (the female reproductive organ) and the female gamete Structure of the female carpel. Detailed structure of the ovary. The ovule is made up of the integuments, nucellus and the megasporocyte The megasporocyte divides by meiosis and mitosis (see next page) to produce the embryo sac The funicle/funiculus connects the ovule to the ovary wall. The area at the point of connect ion is called the placenta
Within the ovule, the megaspore mother cell divides by meiosis and then by mitosis three times to form 8 haploid nuclei. Initially these are present in the embryo sac without separation but are then walled off to produce separate cells. one of these will be the female gamete (the egg cell or ovum) two other nuclei form the polar nuclei which remain together in the embryo sac without being walled off until after fertilisation Two cells called the synergid cells form either side of the egg cell and are involved in releasing chemical signals to guide the pollen tube to the egg cell. They disintegrate after fertilisation. The antipodal cells form at the other end of the embryo sac but have no function and disintegrate.
Pollination Before fertilisation can occur in plants there has to be the transfer of pollen to the stigma this is called pollination. Pollination occurs by means of insects transferring pollen from the anther to the stigma. Pollination can also occur via the wind this is called wind pollination. There are two types of pollination 1. Self pollination. This occurs when pollen is transferred from the anther to the stigma of the same plant. This pollination reduces variability. 2. Cross pollination. This occurs when pollen is transferred from the anther to the stigma of a different plant. This pollination can promote the generation of variation in the offspring. The relative merits of self- and cross-pollination We have seen that insect and wind pollination are both ways of achieving cross-pollination and that selfpollination is possible in some flowers. There are advantages associated with both self- and crosspollination. In fact, many plant species show both types. Self-pollination has the advantage that it is very reliable, particularly if the plants are widely scattered. It is also advantageous in harsh environments, such as high on mountains where insects and other pollinators are scarce. The major disadvantage of self-pollination is that it results in less genetic variation. Self fertilisation occurs, with gametes from the same parent fusing. This is an extreme form of inbreeding (inbreeding is sexual reproduction between genetically similar individuals). Inbreeding makes it more likely that both parents will possess the same harmful recessive alleles, making it more likely that the alleles will come together and be expressed in the offspring. Also, the reduced genetic variation restricts the opportunities for natural selection to occur, and therefore for adaptation to changes in the environment. Evolution of the species is therefore restricted. Cross-pollination is a form of outbreeding, that is sexual reproduction between genetically different individuals - the more genetically different, the, greater the outbreeding. The advantage of cross- pollination is that it results in more genetic variation than self-pollination. This improves the chances of the species surviving environmental change and adapting well to its environment because it provides more variants for natural selection. Cross-pollination results in greater genetic variation for the simple reason that the gametes are produced by genetically different individuals, and therefore show more genetic variation.
Mechanisms favoring cross-pollination We have seen that cross-pollination brings genetic advantages and that elaborate mechanisms exist to increase the likelihood and efficiency of crosspollination. The main ones are listed here but other, often unique, mechanisms can be found. Dioecious plants. When a species, such as willow, produces separate male and female plants it is described as dioecious. Self pollination is impossible in such species, but the number of dioecious plant species is very few. They are often trees: holly, yew and poplar are other examples. Monoecious plants. Monoecious species, such as oak and birch, are those which produce separate male and female flowers on the same plant. This encourages cross-pollination between adjacent plants, while still allowing self-pollination among the flowers of the same plant. Protandry and protogyny. Anthers and stigmas sometimes mature at different times, thus encouraging cross-pollination. If the anthers mature first, as in the white deadnettle, it is known as protandry. The term used when the stigmas mature first, as in the bluebell, is protogyny. Usually there is an overlapping period when both anthers and stigmas are ripe, allowing for selfpollination as well. Self-incompatibility. Even if self-pollination occurs, self fertilisation is often made less likely or impossible by slow or zero growth of the pollen tubes. This is termed incompatibility and is genetically determined. An extreme example is clover, which is totally self-incompatible. Structural Incompatibility. The diagram below shows this mechanism in the primrose (Primula vulgaris) which has 2 flower types (a) thrum and (b) pin. These 2 types were originally described by Darwin. He suggested that when an insect visits a pin flower it inserts its proboscis (feeding tube) into the flower tube to feed on the nectar, and pollen from the anthers would stick onto the proboscis about halfway down. If the insect then visits a thrum flower the pollen already on its proboscis is at the right level to meet and stick to the stigma about halfway down the flower tube, leading to cross fertilisation. At the same time pollen from the anthers at the top of the thrum flower tube is likely to stick to the top of the insect proboscis, the perfect position for cross-fertilising the next pin flower the insect visits. (a) (b)
Fertilisation Fertilisation in plants is internal. It follows pollination and is summarized in the diagram below: Summary of events in plant fertilisation: The pollen grain lands on the stigma. The pollen grain undergoes the changes shown in the diagram below: The generative nucleus in the pollen grain divide to form two male gametes. A pollen tube is formed by the action of the tube nucleus The pollen tube digests its way through the stigma and travels to the ovary. The two male gametes travel down the pollen tube.
The pollen tube enters the embryo sac via the micropyle. The tube nucleus degenerates. One of the male gametes fertilizes the egg cell (ovum) which lies directly above the micropyle. This forms a zygote. The second male gamete fuses with the polar nuclei to form a triploid nucleus (which has three sets of chromosomes compared to the normal two). This is called double fertilisation and only occurs in angiosperms. The fertilised egg cell will develop into the embryo The fertilised polar nuclei will develop into the endosperm which is a food supply for the growing embryo. the embryo sac will form into the seed and the ovary will form into the fruit. The integuments will form the testa which is the hard outer coat of the seed. Diagram showing the changes in the embryo sac after fertilisation.
Development of the embryo and the seed Diagram above shows the further development of the embryo sac in a dicotyledon plant. Note the formation of the zygote which is made up of cotyledons, a plumule and radical. Note in the bottom diagram the testa which is the coat of the seed. The testa is a protective layer. The cotyledons are a food source. The plumule will from the shoot of the new plant. The radical will from the roots of the new plant. Diagram of the Broad Bean (dicotyledon) seed external features. Diagram of the Broad Bean seed internal features.
Germination: the necessary conditions The essential environmental factors for germination are an adequate supply of water, a suitable temperature and an appropriate partial pressure of oxygen. The essential internal conditions required for germination are the maturity of the embryo and the overcoming of dormancy. 1) Water uptake Germination can commence after the uptake of water by the seed. Water is absorbed through the micropyle and the testa. Water absorption is imbibition, the process of uptake of water by the dry colloidal substances of the seed, which include lipids and the dry cell wall substances of the dehydrated seed tissue. The resultant swelling of the seed may rupture the testa. Subsequent movement of water in the hydrated seed tissue is by osmosis. Water is essential to the vacuolation of the growing cells and for the activation of the enzymes that catalyse the biochemical reactions of germination. Turgor of plant cells is a force for cell expansion when the walls are in a condition permitting stretching. Water is a reagent in the hydrolysis of stored food substances, and is required for the translocation of hydrolysed food reserves - the sugars, amino acids and fatty acids - to the sites of growth in the embryo. 2) Temperature The optimum temperature for germination is the optimum for the enzymes involved in mobilisation of food reserves, provided that other factors are nonlimiting. This temperature varies from species to species; wheat seeds germinate in the temperature range 1-35 C, and maize in the range 5-45 C. 3) Oxygen Respiration makes available the energy for metabolism and growth. Germinating seeds respire very rapidly, and require oxygen for aerobic respiration. Seeds will not germinate in the total absence of oxygen. Diffusion of oxygen through the testa may be slow, however, and in the early stages of germination seeds may rely on some anaerobic respiration, at least until the testa has ruptured. 4)Mobilisation of stored food The stored foods of seeds consist of carbohydrates, lipids and proteins. Starch forms the major food reserve of most seeds, but in the sunflower and some other seeds oil makes up about half of the food stored. In pea and bean seeds protein is an additional important reserve food. Food is stored in seeds in an insoluble form, and must be hydrolysed to soluble substances early in germination, following the hydration of the seed. Stored food is hydrolysed to produce the substrates for respiration (sugars) and the building blocks for synthesis (substances such as sugars, amino acids and fatty acids). Some hydrolytic enzymes already exist in the seed and await only water uptake and an appropriate temperature to become activated. Other enzymes are produced in response to hormones released from the developing embryo. Release of hydrolytic enzymes is triggered by gibberellic acid (GA/ gibberellin), which is produced in the embryo and diffuses to the food store. GA works directly on the nuclei of the food storage cells, activating the genes that code for hydrolytic enzymes. Since GA is formed by the embryo only after sufficient water has been absorbed, mobilisation of food reserves is linked to germination.