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Chapter 27: Seedless Plants

Adaptations of Plants to Life on Land

  • The colonization of land by plants required the evolution of many anatomical, physiological, and reproductive adaptations.

    • Plants have a waxy cuticle to protect against water loss and stomata for gas exchange needed for photosynthesis.

  • Plant life cycles have an alternation of generations in which they spend part of their life cycle in a multicellular haploid gametophyte generation and part in a multicellular diploid sporophyte generation.

    • The gametophyte plant produces gametes by mitosis.

    • During fertilization these gametes fuse to form a zygote, the first stage of the sporophyte generation.

    • The zygote develops into a multicellular embryo that the gametophyte protects and nourishes.

    • The mature sporophyte plant develops from the embryo and produces sporogenous cells (spore mother cells).

    • These cells undergo meiosis to form spores, the first stage in the gametophyte generation.

  • Most plants have multicellular gametangia with a protective jacket of sterile cells surrounding the gametes.

    • Antheridia are gametangia that produce sperm cells, and archegonia are gametangia that produce eggs.

  • Ferns and other vascular plants have xylem to conduct water and dissolved minerals and phloem to conduct dissolved sugar.

  • Plants probably arose from a group of green algae called charophytes.

    • This conclusion is based in part on molecular comparisons of DNA and RNA sequences, which show the closest match between charophytes and plants.

Bryophytes

  • Unlike other land plants, bryophytes are nonvascular and lack xylem and phloem.

    • Bryophytes are the only plants with a dominant gametophyte generation.

    • Their sporophytes remain permanently attached and nutritionally dependent on the gametophytes.

  • Mosses (phylum Bryophyta) have gametophytes that are green plants that grow from a filamentous protonema.

  • Many liverworts (phylum hepatophyta) have gametophytes that are flattened, lobelike thalli; others are leafy.

  • Hornworts (phylum Anthocerophyta) have thalloid gametophytes.

  • The green moss gametophyte bears archegonia, antheridia, or both at the top of the plant.

    • During fertilization, a sperm cell fuses with an egg cell in the archegonium.

    • The zygote grows into an embryo that develops into a moss sporophyte, which is attached to the gametophyte.

    • Meiosis occurs within the capsule of the sporophyte to produce spores.

    • When a spore germinates, it grows into a protonema that forms buds that develop into gametophytes.

Seedless Vascular Plants

  • Seedless vascular plants have several adaptations that algae and bryophytes lack, including vascular tissues and a dominant sporophyte generation.

    • As in bryophytes, reproduction in seedless vascular plants depends on water as a transport medium for motile sperm cells.

  • Sporophytes of club mosses (phylum Lycopodiophyta) consist of roots, rhizomes, erect branches, and leaves that are microphylls.

  • Ferns (phylum Pteridophyta) are the largest and most diverse group of seedless vascular plants.

    • The fern sporophyte consists of a rhizome that bears fronds and true roots.

    • Phylum Pteridophyta also includes whisk ferns and horsetails.

    • Sporophytes of whisk ferns have dichotomously branching rhizomes and erect stems; they lack true roots and leaves.

    • Horsetail sporophytes have roots, rhizomes, aerial stems that are hollow and jointed, and leaves that are reduced megaphylls.

  • Fern sporophytes have roots, rhizomes, and leaves that are megaphylls.

    • Their leaves, or fronds, bear sporangia in clusters called sori.

    • Meiosis in sporangia produces haploid spores.

    • The fern gametophyte, called a prothallus, develops from a haploid spore and bears both archegonia and antheridia.

  • Homospory, the production of one kind of spore, is characteristic of bryophytes, most club mosses, and most ferns, including whisk ferns and horsetails.

    • In homospory spores give rise to gametophyte plants that produce both egg cells and sperm cells.

  • Heterospory, the production of two kinds of spores (microspores and megaspores), occurs in certain club mosses, certain ferns, and all seed plants.

    • Microspores give rise to male gametophytes that produce sperm cells.

    • Megaspores give rise to female gametophytes that produce eggs.

    • The evolution of heterospory was an essential step in the evolution of seeds.

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Chapter 27: Seedless Plants

Adaptations of Plants to Life on Land

  • The colonization of land by plants required the evolution of many anatomical, physiological, and reproductive adaptations.

    • Plants have a waxy cuticle to protect against water loss and stomata for gas exchange needed for photosynthesis.

  • Plant life cycles have an alternation of generations in which they spend part of their life cycle in a multicellular haploid gametophyte generation and part in a multicellular diploid sporophyte generation.

    • The gametophyte plant produces gametes by mitosis.

    • During fertilization these gametes fuse to form a zygote, the first stage of the sporophyte generation.

    • The zygote develops into a multicellular embryo that the gametophyte protects and nourishes.

    • The mature sporophyte plant develops from the embryo and produces sporogenous cells (spore mother cells).

    • These cells undergo meiosis to form spores, the first stage in the gametophyte generation.

  • Most plants have multicellular gametangia with a protective jacket of sterile cells surrounding the gametes.

    • Antheridia are gametangia that produce sperm cells, and archegonia are gametangia that produce eggs.

  • Ferns and other vascular plants have xylem to conduct water and dissolved minerals and phloem to conduct dissolved sugar.

  • Plants probably arose from a group of green algae called charophytes.

    • This conclusion is based in part on molecular comparisons of DNA and RNA sequences, which show the closest match between charophytes and plants.

Bryophytes

  • Unlike other land plants, bryophytes are nonvascular and lack xylem and phloem.

    • Bryophytes are the only plants with a dominant gametophyte generation.

    • Their sporophytes remain permanently attached and nutritionally dependent on the gametophytes.

  • Mosses (phylum Bryophyta) have gametophytes that are green plants that grow from a filamentous protonema.

  • Many liverworts (phylum hepatophyta) have gametophytes that are flattened, lobelike thalli; others are leafy.

  • Hornworts (phylum Anthocerophyta) have thalloid gametophytes.

  • The green moss gametophyte bears archegonia, antheridia, or both at the top of the plant.

    • During fertilization, a sperm cell fuses with an egg cell in the archegonium.

    • The zygote grows into an embryo that develops into a moss sporophyte, which is attached to the gametophyte.

    • Meiosis occurs within the capsule of the sporophyte to produce spores.

    • When a spore germinates, it grows into a protonema that forms buds that develop into gametophytes.

Seedless Vascular Plants

  • Seedless vascular plants have several adaptations that algae and bryophytes lack, including vascular tissues and a dominant sporophyte generation.

    • As in bryophytes, reproduction in seedless vascular plants depends on water as a transport medium for motile sperm cells.

  • Sporophytes of club mosses (phylum Lycopodiophyta) consist of roots, rhizomes, erect branches, and leaves that are microphylls.

  • Ferns (phylum Pteridophyta) are the largest and most diverse group of seedless vascular plants.

    • The fern sporophyte consists of a rhizome that bears fronds and true roots.

    • Phylum Pteridophyta also includes whisk ferns and horsetails.

    • Sporophytes of whisk ferns have dichotomously branching rhizomes and erect stems; they lack true roots and leaves.

    • Horsetail sporophytes have roots, rhizomes, aerial stems that are hollow and jointed, and leaves that are reduced megaphylls.

  • Fern sporophytes have roots, rhizomes, and leaves that are megaphylls.

    • Their leaves, or fronds, bear sporangia in clusters called sori.

    • Meiosis in sporangia produces haploid spores.

    • The fern gametophyte, called a prothallus, develops from a haploid spore and bears both archegonia and antheridia.

  • Homospory, the production of one kind of spore, is characteristic of bryophytes, most club mosses, and most ferns, including whisk ferns and horsetails.

    • In homospory spores give rise to gametophyte plants that produce both egg cells and sperm cells.

  • Heterospory, the production of two kinds of spores (microspores and megaspores), occurs in certain club mosses, certain ferns, and all seed plants.

    • Microspores give rise to male gametophytes that produce sperm cells.

    • Megaspores give rise to female gametophytes that produce eggs.

    • The evolution of heterospory was an essential step in the evolution of seeds.