top of page

mantotie kultūraugi palīdz pielāgoties klimata pārmaiņām

Lecture 4

Understand The Pollination!

Intro: This lecture is part of a project funded by the Latvian Ministry of Foreign Affairs to improve sustainable agriculture in Africa.

Main Content: Pollination helps plants make fruits and seeds. Different plants need different methods. Maize relies on the wind to move pollen. If there aren't enough maize plants, the wind might not carry enough pollen, so you get fewer grains. Pumpkins and cucumbers need bees and other pollinators to carry pollen. Without insect pollinators, these plants won't produce well. Beans and peas use their pollen and don't need wind or insect pollinators. To help your crops, know how they get pollinated. For plants that require insect pollinators, plant flowers nearby to attract them. For wind-pollinated crops like maize and millet, plant them in dense blocks to maximize the chances of pollen reaching other plants and ensure the field is oriented with prevailing wind patterns for efficient pollen distribution. Proper spacing is also crucial to avoid unwanted cross-pollination.

Call for action: Learn how your crops get pollinated. Plant flowers to attract bees and other pollinators where needed. Plant in dense blocks with proper spacing and orient fields with prevailing wind patterns to maximize pollen distribution and prevent unwanted cross-pollination for wind-pollinated crops.

Understand the pollination!

Seed saving is a fascinating process that begins with understanding plant biology. Pollination is a crucial process in the plant reproductive cycle. Plants produce fruits and seeds "thanks to" the pollination process. 

 

Let's start with the biology!

The flower's male parts are the stamens with the anthers at the end. These are where the pollen (plant sperm) is produced and spread.

The female parts are at the bottom - the ovary, then the style, and at the top, the stigma where the pollen must land. From here, the pollen grows through the style and into the ovary to fulfill the fertilization.

In some plants, all flowers have both male and female organs. They are called perfect flowers.

Other plants have separate male and female organs in different flowers, though still on the same plant (e.g., pumpkin, melon, cucumber, maize (US corn). They are called monoecious.

In a few plants, the male and female flowers are found on different plants, so the whole plant is either male or female (e.g., asparagus, kiwi, spinach). These plants are called dioecious.

Pollination methods​

​Self-pollinating

  • Self-pollinating plants can use their pollen to fertilize their flowers. In some, the pollination even happens before the flower is open (peas, beans, lettuce, and most tomatoes). The pollen grains fall from the anther to the stigma, and when the flower opens, the whole thing is over and done. So, visiting insects cannot interfere with fertilization. In principle, you can grow viable seeds from just one plant of this type, but it is always better for genetic diversity to take seeds from several plants.

  • Most self-pollinators can use pollen from other plants of the same species. This happens very rarely in some cases (mentioned above), but the risk is much bigger in other cases. 

  • Some self-pollinators are also popular with insects and are therefore at risk of being contaminated with pollen from other plants (e.g., chili, pepper, broad (fava) bean, eggplant).

Cross-pollination

  • These plants are also called outcrossers. They primarily use pollen from other plants and hence need someone or something to bring the pollen from one plant to another – most commonly insects or wind. 

  • Insect pollinated: E.g., cabbages, carrots, pumpkins, squash, leeks, onions.  

  • Wind pollinated: E.g., maize, spinach, beetroot.

  • A particular group of outcrossers is self-infertile. This means that one plant cannot use its pollen to fertilize other flowers on the same plant. It must have pollen from another individual. Self-infertility is a good protection against spontaneous inbreeding. E.g., Cabbages, carrots, maize, rye.

Artificial pollination

  • Hand pollination: The manual transfer of pollen from the anther of one flower to the stigma of another, allowing for precise control over the pollination process.

  • Pollen mixtures: A method involving the mixing of pollen from various plants and its subsequent application to stigmas. While faster than hand pollination, this approach offers less precision.

  • Purpose:

    • To manipulate the pollination process.

    • To produce seeds with specific desired characteristics.

Hybridization

  • Hybridization is the process of crossing two different varieties or species to create a hybrid offspring.

  • Hybridization is often used to improve crop yield and disease resistance.

What is the significance of the pollination method in seed preservation?

 

The pollination method is crucial for seed saving. 

Self-pollination, where a plant fertilizes itself, allows for easy seed collection from a single plant but can limit genetic diversity. For instance, you can propagate plants from a single bean and obtain high-quality seeds.

Cross-pollination, where different plants of the same species fertilize each other, promotes genetic diversity and can make plants more resilient to diseases and pests. However, cross-pollination requires multiple plants to flower simultaneously and exchange pollen to produce high-quality seeds.

 

How can we tell how a plant is pollinated?

 

Examine the plant's flower:

  • If the stigma is not visible, the plant is likely self-pollinating.

  • If a plant has showy and fragrant flowers, it is most likely pollinated by insects.

  • If the flowers are small and inconspicuous and release pollen during flowering, the plant is likely wind-pollinated.

How to Prevent Unwanted Cross-Pollination

To prevent unwanted cross-pollination, which can impact seed quality and the characteristics of subsequent generations, it's essential to isolate varieties from unwanted pollen. There are several effective methods:

Physical Isolation:

  • Distance: Plant different varieties as far apart as possible. This makes it more difficult for pollinators to travel between them, reducing the risk of cross-pollination.

  • Barriers: Use physical barriers such as tall fences, walls, or windbreaks to prevent pollinators from moving between different varieties.

  • Grow only one type of plant: Ensure that no other plants nearby can pollinate your desired crop. For example, grow only one kind of squash, cucumber, melon, or watermelon.

  • Grow many plants: When growing insect-pollinated plants, plant a large number and collect seeds from the center of the field. This is because insects fly from plant to plant, carrying pollen on their bodies.

  • Cover with insect netting: When using insect netting, provide a suitable environment for the specific pollinators you want to attract. For example, food sources for the pollinators should be placed inside the netting.

  • Isolation bags: Cover individual flowers with paper or cloth bags to prevent accidental pollination.

  • Isolation rooms: Grow plants in special rooms where pollination conditions are controlled.

 

Temporal Isolation:

  • Different flowering times: Choose varieties that have different flowering times. This ensures that when one variety has finished flowering, the other has not yet begun, minimizing the risk of cross-pollination.

 

Genetic Isolation:

  • Self-pollinating varieties: Choose self-pollinating varieties that do not require cross-pollination. These are suitable for seed production even in small areas.

Artificial Pollination:

  • Hand pollination: If you want complete control over the pollination process, you can do it yourself by transferring pollen from one flower to another using a brush or tweezers. Then, isolate the pollinated flower to prevent it from receiving pollen from other plants.

Why are these methods important?

  • Creating new varieties: Artificial pollination allows for the combination of desirable traits from different plants, leading to the development of new varieties.

  • Preserving genetic diversity: Isolation and selective pollination help preserve rare and endangered plant varieties.

  • Improving fruit and seed quality: Selected plants are often more resistant to diseases, pests, and adverse environmental conditions.​

md-tanvir-ahmed-bhuiyan-bevWQn3YA98-unsplash_edited.jpg

Šīs lapas saturs sagatavots projekta "“Digitālas mantoto kultūraugu izglītības izveide Āfrikas pārtikas sistēmu noturībai klimata krīzē”" ietvaros. Projekts saņēmis Ārlietu ministrijas finansējumu 2024. gadā no attīstības sadarbības budžeta.

gerbonis_am_balts.png
bottom of page