3. Occurrence of Chara
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. C. hatei grows trailing on the
soil C. nuda and C. grovesii are found on mountains, C. wallichii and C.
liydropitys are found in plains.
4. Thallus Structure of Chara
The thallus of Chara is branched, multicellular and macroscopic. The
thallus is normally 20-30 cm. in height but often may be up to 90 cm to l
m. Some species like C. hatei are small and may be 2-3 cm. long. The
plants in appearance resemble Equisetum hence Chara is commonly called
as aquatic horsetail. The thallus is mainly differentiated into rhizoids and
main axis
5.
6. 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. The tips of rhizoids possess
minute solid particles which function as statoliths.
The rhizoids show apical growth. 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.
Rhizoids:
7. 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. T he species in which cortical layer is absent are called
ecorticate species (Fig. 3 A, B). The node consists of a pair of central
small cells surrounded by 6-20 peripheral cells (Fig. 3 C). The central
cells and peripheral cells arise from a single nodal initial cell.
Main Axis:
8.
9. On nodes develop these following four types of appendages:
(i) 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.
(ii) Branches of unlimited growth:
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.
10. (iii) 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
unitipulate. 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 (Fig. 4 A, B).
11. (iv) 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.
12. The main axis of Chara consists of mainly two types of cells:
(i) Nodal cells
(ii) Inter-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 (Fig. 5
A). 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 (Fig. 5 B). The cell
walls between the nodal cell and inter-nodal cells are porous to help in
cytoplasmic continuity between cells.
Cell Structure of Chara:
13.
14. Reproduction in Chara takes place by vegetative and sexual methods. Asexual
reproduction is absent.
(i) Vegetative Reproduction in Chara:
Vegetative reproduction in Chara takes place by following methods:
(a) Bulbils:
The bulbils are spherical or oval tube-like structures which develop on rhizoids.
C. aspora or on lower nodes of main axis e.g., C. baltica. The bulbils on
detachment from plants germinate into new thallus (Fig. 6 A).
(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 (Fig. 6 B). 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.
Reproduction in Chara
15.
16. (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.
17. Sexual Reproduction in Chara:
The sexual reproduction in Chara is of highly advanced oogamous
type. The sex organs are macroscopic and complex in organization. The
male sex organs are called antheridium or globule and the female oogonium
or nucule. Most of the Chara species are homothallic i.e., the male and male
sex organs are borne on the same nodes, (Fig. 7) e.g., C. zeylanica. Some
species e.g., C. wallichii are heterothallic i.e., male and female sex organs
are borne on different plants. 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 species globule
matures before nucule (Fig. 7 A, B).
18.
19. Globule:
The globule is large, spherical, red or yellow structure.
Development and Structure:
The early development of globule and nucule is similar. The pripheral
cell of the lower node of the primary lateral divides periclinally to form and an
inner cell. The outer cell functions as antheridial initial and the lower cell
again divides a periclinal division. Out of these three cells formed, the
lowermost functions as inter-nodal cell the middle forms basal node, the
uppermost functions as the antehridial initial (Fig. 8 A, B). The middle basal
node cell divides to make 5 peripheral cells. Out of these five peripheral cells,
the upper one develops into oogonium, two lateral ones form unicellular
bracteoles and two lower ones, one on either side of oogonium forms cortex or
remains non-functional (Fig. 8 C, D).
20.
21. The antheridial initial divides by transverse division to make basal
pedicel cell and a terminal antheridial mother cell (Fig. 9 A, B). The pedicel
cell does not divide further and forms pedicel or stalk of mature antheridium.
The antheridial mother cell enlarges and divides by two successive vertical
division at right angle to each other to make a quadrant (Fig. 9 C-D). All
these four cells divide by a transverse wall to make eight cells or octant stage.
Each eel of the octant divides periclinally and forms two layers of eight cells
each. The cells of inner or outer layer divide periclinally to make three radial
layers of eight cells each. The outermost eight cells enlarge laterally to form a
curved plate of eight shield cells (Fig. 9 E, F). The cells of the middle layer
elongate towards centre to make eight rod-shaped manubrial cells (Fig. 9 F).
The cells of the inner layer function as eight primary capitulum cells.
22. Each primary capitulum cell divides to form six secondary capitulum
cells. Sometimes the secondary capitulum cells divide to make tertiary
capitulum cells. Each capitulum cell divides repeatedly to form 2-4 long,
multicellular, branched or un-branched antheridial Filaments or
sperinatogenous filaments (Fig. 9 G-H). The antheridial filament has up to 250
uninucleate cells. These cells function as sperm mother cell and each cell gives
rise to a single spirally coiled, uninucleate, bi-flagellated antherozoid (Fig. 9 J-
L). The mature globule thus 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
(Fig. 9 K).
23.
24. Liberation of Antherozoids:
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.
25. 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. Development and Structure: The upper peripheral cell of
the basal node of the antheridium functions as the oogonial initial. The oogonial
initial divides by two transverse divisions to make three celled filament. It has
lower pedical cell, the middle nodal cell and the upper oogonial mother cell
(Fig. 10 A-C). The pedicell does not divide further and makes pedicel of the
oogonium. The middle nodal cell under many vertical divisions to make five
sheath cells or peripheral cell which surrounds the central cell (Fig. 10 D-F).
The central cell does not divide and functions as the node of the oogonium.
26.
27. The oogonial mother cell elongates vertically and divides by
transverse division to make lower small stalk cell and an upper large
oogonium. The oogonium contains uninucleate ovum or egg. (Fig. 10 G, H).
The peripheral cells or five sheath initials elongate and divide by transverse
division to make two tiers of five cells each. The five upper tier cells from
coronary cells which form the corona of nucule. The five lower tier functions
as tube cells, the tube cells elongate and get spirally twisted in clockwise
directions on oogonium. The nucleus migrates on lower side and receptive spot
develops at the tip of oogonium. Large amount of starch and oil get deposited
in oogonium. 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.
28. 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.
29. Oospore:
The mature oospore is hard, oval, ellipsoid structure which may be
brown e.g., C. inferma, black e.g., C. corallina or golden brown e.g., C. flauda.
The oospore inside contains a diploid nucleus and many oil globules in
cytoplasm.
On maturity of oospore the inner walls of tube cells get thickened,
suberised and silicified. The oogonial as well as oospore walls become thick.
The oospore nucleus moves towards the apical region. In advanced stage the
outer walls of the envelope or sheath cells fall off and the inner parts remain
attached to mature oospore in form of ridges.
30. Germination of Oospore:
The oospore germinates when favourable conditions appear. The diploid nucleus present
in apical colourless region divides by meiosis forming four haploid daughter nuclei (Fig.
II A-B). At this stage a septum divides oospore into two unequal cells. The upper
smaller apical cell contains a single nucleus and the large basal cell contains three
nuclei. The three nuclei of basal cell degenerate gradually. The oospore apical cell
divides by longitudinal division to make a rhizoidal initial and protonemal
initial (Fig. 11 D). The rhizoidal initial shows positive geotropism and forms primary
rhizoid, the protonemal initial shows negative geotropism and forms primary
protonema. The primary protonema differentiates into nodes and internodes. The
peripheral cells of the basal node give rise to rhizoids and secondary protonema. The
peripheral cells of the upper nodes give rise to lateral branches (Fig. 11 E-I).
31.
32. Life Cycle of Chara
The plant body of Chara is haploid. The vegetative reproduction takes
place by the formation of amylum stars, bulbils and secondary
protonema. Asexual reproduction is absent. The sexual reproduction
is advanced oogamous type. The male and female sex organs are
globule and nucule respectively. After fertilization a diploid spore is
formed. At the time of germination diploid oospore nucleus divides to
make hapoid nuclei and haploid Chara plant. Thus the life cycle of
Chara a predominantly haploid type (Fig. 12, 13).