PLANT KINGDOM:
Chapter at a glance
Based on vegetative characters or morphological characters.
E.g. Linnaeus’s artificial system (based on androecium structure).
Drawbacks: It
separates closely related species. Equal weightage to vegetative and
sexual characters.
2.
Natural classification systems
Based on natural affinities among organisms.
Considers external and internal features. E.g.
Classification of flowering plants by Bentham & Hooker.
3.
Phylogenetic classification systems
Based on evolutionary relationships.
o Numerical Taxonomy: Based on all observable
characters. It is easily carried out using computers.
o Cytotaxonomy: Based on cytological
information.
o Chemotaxonomy: It uses chemical
constituents of plants.
ALGAE
- Simple, thalloid, autotrophic, chlorophyll-bearing.
- Some are associated with fungi (lichen) and animals
(e.g. sloth bear).
-
Unicellular
forms: E.g. Chlamydomonas.
-
Colonial
forms: E.g. Volvox.
-
Filamentous
forms: E.g. Ulothrix and Spirogyra.
Reproduction:
- Vegetative: By
fragmentation.
- Asexual: By
spores. E.g. zoospores (most common).
- Sexual: Fusion
of two gametes. Many types:
o Isogamous:
Fusion of similar gametes. They may be flagellated (Ulothrix) or
non-flagellated (Spirogyra).
o Anisogamous: Fusion of dissimilar gametes. E.g. Eudorina.
o Oogamous: Large,
non-motile female gamete + small, motile male gamete. E.g. Volvox, Fucus.
Benefits of algae:
- Fix half of the total CO2 through photosynthesis.
- Basis of the food cycles of aquatic animals.
- Used as food. E.g. Porphyra, Laminaria and Sargassum.
- Agar (from Gelidium & Gracilaria) is
used to grow microbes and in ice-creams and jellies.
- Some produce hydrocolloids
(water holding substances). E.g. algin
(brown algae) and carrageen (red algae).
- Chlorella & Spirulina: Food for space travelers.
|
Algae
Classes |
Chlorophyceae (Green
algae) |
Phaeophyceae (brown
algae) |
Rhodophyceae (Red algae) |
|
Major pigments |
Chlorophyll a, b |
Chlorophyll a, c, Fucoxanthin |
Chlorophyll a, d, r-phycoerythrin |
|
Stored
food |
Starch. Most have pyrenoids
(storage bodies) in chloroplasts. |
Mannitol, laminarin |
Floridean Starch |
|
Cell wall |
Inner
cellulose + outer pectose. |
Cellulose and algin |
Cellulose |
|
Flagellar
number & position. |
2-8, equal, apical |
2, unequal, lateral |
Absent |
|
Habitat |
Fresh, salt &
brackish waters |
Fresh (rare), salt &
brackish waters |
Fresh, salt
(most) & brackish waters |
|
Reproduction |
o Vegetative: Fragmentation
or formation of spores. o Asexual: By
zoospores produced in zoosporangia. o
Sexual: Isogamous, anisogamous or oogamous. |
o
Vegetative: By fragmentation. o
Asexual: By biflagellate zoospores. o
Sexual: Isogamous, anisogamous or oogamous. |
o Vegetative: By fragmentation.
o Asexual: By
non-motile spores. o
Sexual: Oogamous. By non-motile gametes. |
|
Examples |
Chlamydomonas,
Volvox, Ulothrix, Spirogyra & Chara. |
Ectocarpus, Dictyota, Laminaria, Sargassum & Fucus. |
Polysiphonia, Porphyra, Gracilaria and Gelidium |
BRYOPHYTES
(Liverworts & Mosses)
- Amphibians of the plant kingdom.
- Thallus-like body. Attached to substratum by rhizoids.
- No true roots, stem or leaves.
- Main plant body is haploid (gametophyte) → gametes.
- Male sex organ (antheridium) produces biflagellate antherozoids.
Female sex organ (archegonium) produces an egg.
- Antherozoids → to water → archegonium → antherozoid +
egg → zygote → sporophyte → attached to
gametophyte → Some sporophyte cells undergo meiosis → haploid spores →
germinate → gametophyte.
Importance of Bryophytes:
- Food for mammals, birds etc.
- Peat from Sphagnum is used as fuel and packing material.
- Role in plant succession.
- Prevent soil erosion.
Liverworts
- Thalloid plant body. E.g. Marchantia.
- Asexual reproduction: By fragmentation or by formation of gemmae (asexual
buds).
- Gemmae develop in small receptacles (gemma cups).
Gemmae germinate to new individuals.
- Sexual reproduction: Sporophyte is differentiated into a foot, seta &
capsule. After meiosis, spores are formed in capsule → gametophyte.
Mosses
- Gametophyte (predominant
stage) consists of 2 stages:
o Protonema stage: Develops
from a spore. Green, branched and filamentous.
o Leafy stage: Develops
from secondary protonema. Spirally arranged leaves.
- Vegetative reproduction: By fragmentation & budding.
- Sexual
reproduction: Antheridia & archegonia
are produced. Zygote develops into a sporophyte. Spores are formed in capsule after
meiosis. E.g. Funaria, Polytrichum and Sphagnum.
PTERIDOPHYTES
- Include horsetails and ferns.
- First terrestrial plants to possess vascular tissues.
- Dominant phase is a sporophyte. It is differentiated
to true root, stem & leaves.
- Leaves are small (microphylls) as in Selaginella or
large (macrophylls) as in ferns.
REPRODUCTION:
- Sporophytes bear sporangia & sporophylls.
In some cases, sporophylls form strobili or cones (E.g. Selaginella,
Equisetum).
- Sporangia → spore mother cells → meiosis → spores → prothallus
(free-living thalloid gametophytes).
- Prothallus needs water
for fertilization. So, the spread of pteridophytes is limited to narrow
geographical regions.
- Prothallus bears antheridia and archegonia.
- Antherozoids (male
gametes from antheridia) → via water → to archegonium → fuses with egg in
archegonium → zygote → sporophyte.
- Most pteridophytes are homosporous (produce similar kinds of spores). Others are heterosporous (2 kinds of spores: macro & micro). E.g. Selaginella & Salvinia.
- Megaspores & microspores
germinate to form female and male gametophytes, respectively.
- In female gametophytes, zygotes develop to embryos.
-
1. Psilopsida: E.g. Psilotum
2. Lycopsida: E.g. Selaginella, Lycopodium
3. Sphenopsida: E.g. Equisetum
4. Pteropsida: E.g. Dryopteris, Pteris, Adiantum
GYMNOSPERMS
- Ovules are not enclosed by ovary wall. Seeds are naked.
- Sequoia
(giant redwood) is the tallest tree species.
- Generally tap roots. Roots in some genera have fungal
association (mycorrhiza. E.g. Pinus).
- Roots of Cycas etc. are associated with N2-
fixing cyanobacteria (coralloid roots).
- Stems are unbranched (Cycas) or
branched (Pinus, Cedrus).
- In conifers (Pinus,
Cedrus etc.), needle-like
leaves reduce the surface area. Their thick cuticle and sunken stomata reduce
water loss.
REPRODUCTION:
- Heterosporous- haploid
microspores and megaspores.
- Some leaves become sporophylls. They bear sporangia.
- Sporophylls are 2 types:
o Microsporophylls: Arranged to male strobili (microsporangiate). They
bear microsporangia → microspores → male gametophytes → pollen grains.
o Megasporophylls:
Arranged to female strobili
(macrosporangiate). They bear megasporangia (ovules). Megasporangium
consists of nucellus. A cell of nucellus differentiates to megaspore
mother cell → meiosis → 4 megaspores. One megaspore develops to female
gametophyte that bears archegonia.
- Male or female cones may be on same tree (Pinus) or
on different trees (Cycas).
- Pollen grain from microsporangium → via air → to opening of
ovules → male gametes move through pollen tube → archegonia → fertilization →
zygote → embryo.
ANGIOSPERMS (FLOWERING PLANTS)
2 classes:
o Dicotyledons: 2
cotyledons in seeds, reticulate venation.
o Monocotyledons: One
cotyledon, parallel venation.
REPRODUCTION:
- Flower is the reproductive structure.
- Male sex organ: stamen (filament + anther).
- Pollen mother cell in anthers → meiosis → microspores → pollen
grains.
- Female sex organ: Pistil (ovary + style + stigma).
- Ovary contains ovules. An ovule has a megaspore
mother cell → meiosis → 4 megaspores (n) → 3 of them degenerate and
one forms embryo sac.
- Each embryo sac has a 3-celled egg apparatus (1 egg
cell & 2 synergids), 3 antipodal cells & 2 polar
nuclei. The polar nuclei fuse to produce a secondary nucleus (2n).
- Pollen grains → to stigma
(pollination) → germinate on stigma → pollen tubes form → reach
the ovule → enter the embryo-sac → 2 male gametes are discharged.
- One male gamete + egg cell → zygote → Embryo.
- Other male gamete + secondary nucleus (2n) → triploid primary endosperm nucleus (PEN) → endosperm (nourishes embryo).
- Thus there are two fusions. So it is called double
fertilisation. It is an event unique to angiosperms.
- Synergids & antipodals degenerate after fertilization.
- Ovules develop
to seeds and ovaries develop to fruit.
PLANT
LIFE CYCLES AND ALTERNATION OF GENERATIONS
- Angiosperms show alternation of generations between
gametophyte (haploid) and sporophyte (diploid).
- Gametophyte (n) → mitosis → gametes → fertilization → zygote → mitosis → sporophyte (2n) → meiosis → haploid
spores → mitosis → Gametophyte.
Patterns of Plant life
cycles
1. Haplontic: Sporophyte
is represented only by zygote.
Zygote → meiosis → spores (n) → mitosis → gametophyte (dominant,
photosynthetic).
E.g. Algae such as Volvox, Spirogyra and Chlamydomonas.
2. Diplontic: Sporophyte is dominant & photosynthetic. E.g. An alga, Fucus sp., gymnosperms & angiosperms.
3. Haplo-diplontic: Both gametophyte & sporophyte are multicellular. But they have different dominant phases. E.g. Bryophytes & Pteridophytes.
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