Plant Biology: How do seeds grow?
A single seed is bursting with powerful natural forces that allow it to grow into the tallest tree
Ev ery seed, no matter how tiny, is a just-add-water kit for new life. Kept safe within the seed coat is the embryo of a plant lying dormant until the moment is right to emerge and germinate. Some species require specific light or temperature conditions as well as moisture, while others need only oxygen and water to spring into action. Substances called germination inhibitors make a seed wait a year – or many years – if conditions aren’t right for plant development.
When water reaches a seed, it’s absorbed through a tiny opening in the coat and causes swelling as cells are rehydrated – a process known as imbibition. Metabolic processes begin within the seed and cells start to divide, fuelled by a small reserve of nutrients stored in a tissue called the endosperm or in the cotyledon, the part of the embryo that can become the first leaf. The force of the swelling causes the seed coat to burst, allowing the radicle – the embryonic first root – to emerge and anchor the seed.
Roots exhibit positive geotropism, turning in response to gravity’s pull as they grow, so they always head further into the ground. Once the little root has begun its journey downwards, it can provide the seed with water and minerals absorbed from the soil around it. A shoot grows away from the root and against gravity, pushing through the soil so that the seedling’s first leaves can reach the sunlight and take up the important job of photosynthesis.
How It Works – A single seed is bursting with powerful natural forces that allow it to grow into the tallest tree – Environment
How do seeds work
As various seed catalogs begin arriving in the mail, gardeners plan their vegetable gardens and flower beds. As you visualize the flowers and fruits to come, think about the complexity and elegance of the seeds themselves. Seeds are plant embryos packaged in a small container with stored food. Mother Nature provides the technology and packaging. Seed companies just breed the plants, collect and process the fruits, put them in and envelope, and sell them to us.
Seeds are the products of sexual reproduction. They contain DNA from a pollen grain and an ovule. The male and female parents can be different plants or the same plant depending on the species. As with all biological systems, there are many variations on this theme. Understanding the reproductive cycle for a given plant is critical to successful plant breeding and seed saving.
As mentioned above, a seed contains the embryo of the new plant, with a supply of food for the embryo until it has formed sufficient roots and leaves to obtain its own food. The embryo is a miniature plant in a state of arrested development. The food, endosperm, may be in the seed leaves (also called cotyledons) or it may be outside the seed leaves and be absorbed as the seed germinates. Endosperm food sources can be in the form of carbohydrates, proteins, or fats. Seeds also have a seed coat (testa) to protect them from disease and insects. The seed coat also prevents water from entering the seed which would initiate the germination process before the proper time.
The process of seed germination is the resumption of active growth of the embryo so that it can become a plant. Prior to any visual signs of growth the seed must absorb water through the seed coat and/or an area of the seed called the micropyle. In addition, the seed must be in the proper environmental conditions; that is, exposed to oxygen, favorable temperatures, and for some, specific light conditions.
Seed germination occurs in three stages. The process of water absorption (called imbibition) reactivates enzymes present in the seed. These enzymes break down storage compounds in the seed to make them available for the embryo. For example, when barley absorbs water, enzymes are activated that convert starch into sugars. Some industrious individuals use these processes to their advantage to produce malt which is used to make beer.
The second stage is digestion and translocation. In this stage, enzymes that were synthesized or activated previously begin to break down storage material within the seed into simple compounds which are translocated to the embryo. The embryo begins to grow as cells elongate and divide. In the final stage, the germinating seed continues to undergo metabolic changes which transform the embryo into a seedling.
The radicle is the first part of the seedling to emerge from the seed. It will develop into the primary root from which root hairs and lateral roots develop. In most broad-leafed plants, there are two seed leaves (called cotyledons) which encase the embryo and are usually different in shape from the leaves that the mature plant. The hypocotyl is the portion of the embryo which becomes the stem. These plants are often referred to as dicots. Plants producing one cotyledon are called monocots. Monocots include grasses, lilies, orchids, palms, agaves, and yuccas.
The processes described above are simplified and generalized. The bottom line is that seeds are alive. Respiration requires an energy source and some minute amount of oxygen. Seed viability can be extended under cool, dry storage conditions. While there are a lot anecdotal reports of seeds remaining viable for a 1,000 or more years. Controlled experiments have documented seed viability of 100 years for a handful of species investigated. Myself, I’m happy when seeds I purchased last year germinate.
The University of Arizona Cooperative Extension, Yavapai County, Backyard Gardener