Практична робота 3 Тема: Порівняння будови мохів, папоротей та покритонасінних (квіткових)

Comparison of Structure of Mosses, Ferns, and Angiosperms

Mosses, ferns, and angiosperms (flowering plants) are all higher plants, but they differ in their structure and reproductive strategies. Let's compare the structure and life cycle of these three groups of plants.

Mosses

Mosses are non-vascular plants that belong to the phylum Bryophyta. They are small, herbaceous plants that lack true roots, stems, and leaves. Instead, they have simple structures called rhizoids that anchor them to the substrate and absorb water and nutrients. Mosses have a dominant gametophyte generation, which is the sexual phase of the life cycle. The gametophyte produces male and female reproductive structures called antheridia and archegonia, respectively. The male gametes (sperm) are released from the antheridia and swim through a film of water to reach the female gametes (eggs) in the archegonia. After fertilization, the zygote develops into a sporophyte, which remains attached to the gametophyte. The sporophyte consists of a foot, seta, and capsule. The capsule contains spores that are released and dispersed to start new gametophyte generations [[1]].

Ferns

Ferns are vascular plants that belong to the phylum Pteridophyta. They have true roots, stems, and leaves. Ferns have a dominant sporophyte generation, which is the asexual phase of the life cycle. The sporophyte produces spores in structures called sporangia, which are usually located on the underside of the leaves. The spores are released and dispersed by wind or water. When a spore lands in a suitable environment, it germinates and develops into a gametophyte called a prothallus. The prothallus produces both male and female reproductive structures. The male gametes (sperm) are released from antheridia and swim through a film of water to reach the female gametes (eggs) in archegonia. After fertilization, the zygote develops into a new sporophyte, which grows from the prothallus. The sporophyte consists of roots, stems, and leaves and is the visible fern plant that we commonly recognize [[2]].

Angiosperms (Flowering Plants)

Angiosperms are vascular plants that belong to the phylum Anthophyta. They have true roots, stems, and leaves, and they produce flowers and fruits. Angiosperms have a dominant sporophyte generation, similar to ferns. The sporophyte produces flowers, which are the reproductive structures. Flowers contain male reproductive organs called stamens, which produce pollen, and female reproductive organs called carpels, which contain the ovules. Fertilization occurs when pollen grains land on the stigma of a flower and grow a pollen tube to reach the ovules. After fertilization, the ovules develop into seeds, and the ovary of the flower develops into a fruit. The seeds are dispersed by various means, such as wind, water, or animals, and when they land in a suitable environment, they germinate and develop into new sporophytes [[3]].

Comparison Table

| Characteristic | Mosses | Ferns | Angiosperms | | --- | --- | --- | --- | | Dominant Generation | Gametophyte | Sporophyte | Sporophyte | | Gametophyte Organs | Antheridia (male) and Archegonia (female) | Prothallus | Not applicable | | Sporophyte Organs | Foot, Seta, and Capsule | Roots, Stems, and Leaves | Roots, Stems, and Leaves | | Dependence on Water | Yes | No | No | | Root System | Rhizoids | True Roots | True Roots | | Presence of Flowers | No | No | Yes | | Reproduction | Spores | Spores | Seeds |

Why are Angiosperms the Dominant Group of Plants on Earth?

Angiosperms, or flowering plants, are the most diverse and successful group of plants on Earth. There are several reasons why angiosperms have become the dominant group:

1. Efficient Reproduction: Angiosperms have evolved efficient reproductive structures, such as flowers, which attract pollinators like insects, birds, and mammals. This allows for more effective pollination and increases the chances of successful fertilization and seed production.

2. Seeds and Fruits: Angiosperms produce seeds enclosed within fruits. This provides protection and nourishment to the developing embryo, increasing its chances of survival. Fruits also aid in seed dispersal, allowing angiosperms to colonize new habitats.

3. Adaptability: Angiosperms have evolved a wide range of adaptations that allow them to thrive in diverse environments. They can be found in almost every habitat on Earth, from deserts to rainforests, and from high altitudes to underwater.

4. Co-evolution with Pollinators: Angiosperms have co-evolved with various pollinators, leading to specialized relationships. This mutualistic interaction benefits both the plants and the pollinators, ensuring successful reproduction for angiosperms.

5. Rapid Evolution: Angiosperms have a relatively short generation time, allowing for rapid evolution and adaptation to changing environmental conditions. This has contributed to their success and ability to outcompete other plant groups.

In conclusion, the dominance of angiosperms on Earth can be attributed to their efficient reproductive strategies, the production of seeds and fruits, adaptability to different environments, co-evolution with pollinators, and their ability to rapidly evolve and adapt.