This document summarizes key details about the freshwater green alga Chara. It describes the order, common species, occurrence in freshwater ponds and lakes, thallus structure including main axis, nodes, branches, rhizoids, and cell structure. Reproduction is both vegetative through structures like bulbils and sexually through oogamous fertilization. Chara has economic importance as food for aquatic animals, in purifying water, as green manure, and used dried as an insect repellent.
2. Order : Charales
Family : Characeae
• Stone wort / brittle wort (Calcium carbonate)
• 90 / 27
• C. vulgaris , C. zeylanica, C. nuda
3. Occurance
• Chara is a fresh water, green alga found submerged in shallow water ponds,
tanks, lakes and slow running water.
• C. baltica is found growing is brackish water and C. fragilis is found in hot
springs.
• Chara is found mostly in hard fresh water, rich in organic matter, calcium
and deficient in oxygen.
• Chara plants are often encrusted with calcium carbonate and hence are
commonly called stone wort.
• Chara often emits disagreeable onion like odour due to presence of sulphur
compounds.
• In India Chara is represented by about 30 species of which common Indian
species are: C. zeylanica, C. braunii, C. gracilis, C. hatei, etc.
4. Thallus structure
• Sbmerged, fresh water, macroscopic
• Erect 20- 30 cm
• Main axis and rhizoids (uniseriate and branched)
• Nodes and internodes
• Node – 2 central cell + 6-20 cortical cells
• Internode 1 axial + cortical cell
5. Rhizoids
• The rhizoids are white, thread like, multicellular, uniseriate
and branched structures.
• The rhizoids arise from rhizoidal plates which are formed at
the base of main axis or from peripheral cells of lower nodes.
• The rhizoids are characterized by presence of oblique septa.
• Rhizoids help in attachment of plant to substratum i.e., mud
or sand, in absorption of minerals
• And in vegetative multiplication of plants by forming bulbils
and secondary protonema.
6. Main axis
• The main axis is erect, long, branched and
differentiated into nodes and internodes.
• The internode consists of single, much
elongated or oblong cell.
• The inter-nodal cells in some species may be
surrounded by one celled thick layer called
cortex and such species are called as
corticate species.
• The species in which cortical layer is absent
are called ecorticate species
• The node consists of a pair of central small
cells surrounded by 6-20 peripheral cells.
• The central cells and peripheral cells arise
from a single nodal initial cell.
7. Branches
Branches of limited growth.
• The branches of limited growth arise
in whorls of 6-20 from peripheral cells
of the nodes of main axis or on
branches of unlimited growth.
• These are also called branchlets,
branches of first order, primary
laterals or leaves.
• These branches stop to grow after
forming 5-15 nodes and hence are
called branches of limited growth
• .
• The stipulodes and reproductive
structures are formed on the node of
these branches.
Axillary branch
• The branches – of unlimited growth arise
from the axils of the branches of limited
growth hence these are also called
auxiliary branches or long laterals.
• These are differentiated into nodes and
internodes. At nodes they bear primary
laterals and these branches look like the
main axis.
• Their growth is also unlimited like main
axis.
8. Stipulodes:
• The basal node of the branches of
limited growth develops short, oval,
pointed single cell outgrowths called
stipulodes.
• In most of the species of Chara e.g.,
C. burmanica, the number of
stipulodes at each node is twice the
number of primary laterals, such
species are called as bi-stipulate.
• In some species of Chara e.g., C.
nuda and C. braunii, the number of
stipulodes at each node, is equal to
number of primary laterals at that
node, such species are called
unistipulate.
• When stipulodes are present in one
whorl at each node the species are
called as haplostephanous and with
two whorls on each node are called
diplostephanous.
9. Cortex
• Many species of Chara e.g., C. aspera,
C. inferma have inter-nodal cells of
main axis en-sheathed by cortex cells.
Such species are called corticated
species.
• The cortex consists of vertically
elongated narrow cells.
• The internode up to half of its length by
corticating filaments developed from
upper node called descending the lower
half of internode is covered by
filaments developed from lower node
called filaments.
• The ascending and descending
filaments meet at the middle of
internode. T species without cortex e.g.,
C. corallina are called ecorticated
species.
11. (i) Nodal cells
• The nodal cells are smaller in size and isodiametric.
• The cells are dense cytoplasmic, uninucleate with few small ellipsoidal
chloroplasts.
• The central vacuole is not developed instead many small vacuoles may be
present.
• The cytoplasm can be differentiated in outer exoplasm and inner
endoplasm.
(ii) Inter-nodal cells.
• The inter-nodal cells are much elongated.
• The cytoplasm is present around a large central vacuole.
• The cells are multinucleate and contain many discoid chloroplasts.
• The cytoplasm is also differentiated into outer exoplasm and inner
endoplasm.
• The endoplasm shows streaming movements.
13. • (a) Bulbils:
• The bulbils are spherical or oval tube like structures which develop on
rhizoids.
• The bulbils on detachment from plants germinate into new thallus. Eg:- C.
aspora
• (b) Amylum Stars:
• In some species of Chara e.g., C. stelligna, on the lower nodes of main axis
develop multicellular star shape aggregates of cells.
• These cells are full of amylum starch and hence are called Amylum stars.
• The amylum stars do detachment from plants develops into new Chara
thalli.
14. • (c) Amorphous bulbils:
• The amoiphous bulbils are group, many cells, irregular in shape
which develop on lower node main axis e.g., C. delicatula or on
rhizoids e.g., C. fragifera and C. baltica.
• The amorphous bulbils are perennating structures, when the main
plant dies under unfavorable conditions; these bulbils survive and
make Chara plants on return of favourable conditions.
• (d) Secondary Protonema:
• These are tubular or filamentous structure which develops from
primary protonema or the basal cells of the rhizoids.
• The secondary protonema like primary protonema form Chara
plants.
15. 2. Sexual
• Oogamous
• Sterile envelop
• Most of the Chara species are homothallic e.g., C.
zeylanica.
• Some species e.g., C. wallichii are heterothallic
• The sex organs arise on the branches of limited growth
or primary laterals, the nucule above the globule.
• The development of globule and nucule takes place
simultaneously but globule matures before nucule
16. Globule/ antheridium / spermatogema
The globule is large, spherical, red or yellow structure.
The mature globule is made up of 8 curved shield cells, 8 elongated manubrial
cells, 8 centrally located primary capitulum cells and 48 secondary capitulum
cells.
The secondary capitulum cells give rise to many antheridial filaments. Each
sperm mother cell forms a single bi-flagellated antherozoid.
At maturity the shield cells of antheridium separate from each other exposing
antheridial filaments in water. The sperm mother cell gelatinizes to liberate the
antherozoids.
17. Nucule
• The nucule of Chara is large, green, oval structure with short
stalk.
• It is borne at the node of the primary lateral.
• It lies just above the globule in homothallic species.
• The mature nucule is attached to the node by the pedicel cell.
• The nucule is surrounded by five tube cells.
• The tips of tube cells from corona at the top of nucule.
• The oogonial cell possesses a single large egg or ovum.
• The nucule contains large amount of starch and oil.
• The receptive spot is present at the upper part of nucule.
18. Fertilization
• When the oogonium is mature, the five tube
cells get separated from each other forming
narrow slits between them.
• Antherozoids are chemotactically attracted
towards ovum.
• The antherozoids enter through these slits
and penetrate gelatinized wall of the
oogonium.
• Many antherozoids enter oogonium but one
of those fertilizes the egg to make a diploid
zygote.
• The zygote secretes a thick wall around itself
to make oospore.