Kingdom Plantae Bryophyta: Nonvascular Plants

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Presentation transcript:

Kingdom Plantae Bryophyta: Nonvascular Plants Lycophyta, Sphenophyta, Pterophyta: Seedless Vascular Plants Gymnosperms: Coniferophyta

Setting the Stage for Plants Earth’s atmosphere was originally oxygen free Ultraviolet radiation bombarded the surface Photosynthetic cells produced oxygen and allowed formation of a protective ozone layer

Invading the Land Cyanobacteria were probably the first to spread into and up freshwater streams Later, green algae and fungi made the journey together Every plant is descended from species of green algae

The Plant Kingdom Nearly all are multicelled Vast majority are photoautotrophs Energy from sun Carbon dioxide from air Minerals dissolved in water

zygophytes, related groups Evolutionary Tree for Plants flowering plants green algae zygophytes, related groups charophytes bryophytes lycophytes horsetails ferns cycads ginkgos conifers gnetophytes seed plants euphyllophytes embryophytes (land plants) vascular plants (closely related groups) Figure 23.3 Page 387

Nonvascular Plants Bryophytes Fewer than 19,000 species Three groups Liverworts Hornworts Mosses

Vascular Plants Majority of plants Have internal tissues that carry water and solutes Two groups Seedless vascular plants Seed-bearing vascular plants

Seedless Vascular Plants Arose during the Devonian Produce spores but no seeds Four main groups Whisk ferns Lycophytes Horsetails Ferns

Seed-Bearing Vascular Plants Gymnosperms arose first Cycads Ginkgos Gnetophytes Conifers Angiosperms arose later Monocots Dicots

Evolutionary Trend zygote SPOROPHYTE (2n) GAMETOPHYTE (n) GREEN ALGA BRYOPHYTE FERN GYMNOSPERM ANGIOSPERM

Adaptations to Land Root systems Shoot systems Vascular tissues Waxy cuticle

Traits of Seed-Bearing Plants Pollen grains Arise from megaspores Develop into male gametophytes Can be transported without water Seeds Embryo sporophyte inside nutritive tissues and a protective coat Can withstand hostile conditions

Bryophytes Small, nonvascular, nonwooody Gametophyte dominates life cycle; has leaflike, stemlike, and rootlike parts Usually live in wet habitats Flagellated sperm require water to reach eggs

Moss Life Cycle Zygote grows, develops into a sporophyte while still attached to gametophyte. mature sporophyte zygote Diploid Stage Fertilization Meiosis Haploid Stage Spores germinate. sperm-producing structure male gametophyte egg-producing structure female gametophyte Figure 23.5 Page 388

Phylum Bryophyta “Mosses” The gametophyte of mosses consists of a leafy shoot that is anchored to the substrate by branched multicellular rhizoids. http://www.science.siu.edu/landplants/Bryophyta/MossDesc.html

Leaf arrangement is normally spiralled.

The initial stage of gametophyte development, resulting from germination of the spore,

is a filamentous branched structure known as the protonema.

Moss, highly branched with sporophytes terminating lateral branches.

Antheridia are equally elongated with a long narrow stalk

General morphology are seen in Sphagnum

Sporophyte

Habit shot of female shoots with terminal sporophytes and male shoots with clusters of orange antheridia surrounded by leaves. Copyright by Alan Heilman (Univ. Tenn.).

Close-up of gametophyte with orange antheridia (right) and sporophyte (left).

Marchantia: A Liverwort Do not post on Internet Reproduces asexually by gemmae Gametophytes are male or female Female gametophyte Figure 23.7 Page 389

Seedless Vascular Plants Lycophytes (Lycophyta) Whisk ferns (Psilophyta) Horsetails (Sphenophyta) Ferns (Pterophyta)

Ferns (Pterophyta) 12,000 species, mostly tropical Most common sporophyte structure Perennial underground stem (rhizome) Roots and fronds arise from rhizome Young fronds are coiled “fiddleheads” Mature fronds divided into leaflets Spores form on lower surface of some fronds

Phylum Pterophyta “ferns”

Pattern of uncoiling “fiddle heads”.

young “Fronds”

Fern Life Cycle Sporophyte still attached to gametophyte sorus zygote rhizome Diploid Stage fertilization meiosis Haploid Stage Spores are released Spores develop egg sperm mature gametophyte Spore germinates

On the back (abaxial) side of the frond occur the spore-producing structures called sori (singular sorus).

The sori are covered by a thin structure called an indusium.

Male (left)  Bisexual (Right) Prothallus (gametophyte)

On the underside (ventral) of the prothallus, archegonia are frequently clustered around the apical notch as evidenced by the protruding archegonial necks seen in this SEM photo (by Joan Nester-Hudson).

Biflagellated sperm

At the moment of fertilization, the nuclei of sperm and egg fuse and a diploid zygote is formed. This begins the sporophytic generation again. The zygote divides mitotically to form and embryo and eventually a tiny sporophytic plant. These can often be seen still attached to the notch area of the prothallus.

Division Lycophyta “Club Mosses”

The sporophyte is relatively simple with dichotomously to pseudomonopodally branched green stems and spirally arranged microphylls (simple leaves with single veins).

Typically, the shoot system is separated into upright aerial shoots and morphologically distinct creeping rhizomes from which adventitious roots arise.

Sporangia are positioned on the adaxial side of specialized leaves that in turn are arranged in zones along the stem or in a terminal series, known as strobili

Division Sphenophyta “Horsetails or Scouring Rushes”

The sporophyte of Equisetum is differentiated into an underground rhizome that bears adventitious roots and an upright, photosynthetic stem with whorls of microphylls. The stem is jointed, i.e., the nodes are clearly defined by whorls of leaves.

Species in the subgenus Equisetum produce abundant branches that arise in whorls at the nodes.

The eusporangia of Equisetum are aggregated in terminal branched units known as strobili.

Strobili

Thousands of rounded spores are produced in each sporangium

Antheridia and biflagellated spermatozoids

Division Coniferophyta “Conifers”

Cluster of microsporangiate strobili of Pinus resinosa

Longitudinal section through a microsporangiate cone of pine consisting of microsporophylls spirally arranged around the central axis bearing microsporophylls.

Male gametophyte: pollen grain

Cross section of a pine needle