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Somatic hybridization and Protoplast Isolation
1. Protoplast isolation and
Somatic Hybridization
Submitted by :-
P.TEJASREE
BAM-20-27
M.Sc 1st Year
Dept of GPBR
DEPARTMENT OF GENETICS AND PLANT BREEDING
Course No :- GP-509
Course Title :- BIOTECHNOLOGY FOR CROP IMPROVEMENT
Assignment On :- PROTOPLAST ISOLATION AND SOMATIC HYBRIDIZATION
Submitted to :-
Dr. Lal Ahamed M.
Associate Professor
Dept of GPBR
1
2. Definition
Development of hybrid plants through the fusion
of somatic protoplasts of two different plant
species/varieties is called somatic hybridization.
This is a non conventional genetic procedure
involving fusion between isolated protoplast
under in vitro condition and subsequent
development of their product (heterokaryon) to a
hybrid plant.
2
3. History
ā The term āProtoplastā was introduced in 1880 by Hanstein - A cell with its cell wall removed
either mechanically or enzymatically is named as protoplast.
ā First isolation of protoplast was achieved by Klercker in 1892 by using mechanical method.
ā KĆ¼ster in 1909 described the process of random fusion in mechanically isolated protoplasts.
ā The real beginning in protoplast research was made by Cocking in 1960 who used enzymatic
method for cell wall removal.******
ā Takebe et al (1971) were successful to achieve the regeneration of whole tobacco plant from
protoplasts.
ā Somatic hybridization (fusion of protoplasts) is relatively a new versatile technique to induce or
promote genetic recombination in a variety of prokaryotic and eukaryotic cells (Bhojwani S.S.
et al 1977).
3
4. Need Of Somatic Hybridization**
ā Crossing barriers among plant species and in
organelle
ā Species barriers encountered in sexual
hybridization
ā Transfer of genes from wild species into the
genes of crop plants **
ā Tool for the modification and improvement of
polygenic traits
4
5. Importance of Protoplast Isolation
ā£ The term āProtoplastā refers to the spherical plasmolysed content of the plant cell
enclosed by plasma membrane or naked cell without cell wall.
ā£ Before culturing protoplast, it is important to isolate viable and uninjured protoplasts.
ā£ Production of hybrid plants through the fusion of protoplasts of two different plant
species/varieties is called Somatic Hybridization, and such hybrids are called Somatic
Hybrids.
ā£ Therefore, somatic hybridization can be resorted to only when the following two
criteria are satisfied:
ā£ i) Isolation of protoplast in large quantity, and
ā£ ii) Totipotency of the isolated protoplasts.
5
6. (q) Chromosome number of diploid 2n=2x=40.
(r) Chromosome number of somatic hybrid
(2n=4x=80). ā Symmetric Hybrid*** 6
7. Source of Protoplasts
ā Protoplast can be isolated from almost all plant parts:
ā Roots, leaves, fruits, tubers, root nodules, endosperm, pollen mother cell, callus and
suspension culture
ā Spongy and palisade mesophyll tissue obtained from mature leaves of Nicotiana and
Petunia.
ā Anthers of Pelargonium (Abo El-Nil and Hilderbrandt, 1971)
ā Callus of Gossypium hirsutum (Bhojwani, Cocking, and Power, 1977)
ā Crassulacean acid metabolism (CAM) plants (Doddds, 1980)
ā C3 and C4 plants (Kanai and Edwards, 1973)
ā Solanum tuberosum (Upadhya, 1975)
7
8. Somatic hybridization technique
Isolation of
protoplast
Fusion of the
protoplasts of
desired
species/varieties.
Identification
and Selection of
somatic hybrid
cells
Culture of the
hybrid cells
Regeneration of
hybrid plants
8
10. Methods of Isolation of Protoplasts
ENZYMATIC METHOD:
ā£ The plant cell wall is mainly composed of cellulose, hemicellulose and pectin which are respectively
degraded by the enzymes cellulase, hemicellulase and pectinase. In plant cells we mainly uses these enzymes
(cellulase, hemicellulase and pectinase) at pH 4.5-6.0 & temperature 25-300C with incubation period of half
an hour to 20 hrs.
ā£ Credit of developing High Yield Protoplast Isolation Technique from higher plant protoplasts goes to
Cocking (1960)
MECHANICAL METHOD
ā£ HISTORY: Klercher (1892) was the first to isolate protoplast from plasmolyzed cell of Stratiates aloides. The
studies were later extended for protoplast isolation from tissues of Onion bulbs.
ā£ PROCEDURE: Onion Scales were immersed in 1.0 M Sucrose until the protoplast shrunk away from their
enclosing wall and then the plasmolysed tissue was cut into small strips. The protoplasts were released by
Osmotic Swelling when these strips of the tissue were placed in Low Concentration Sucrose Solution. This
method is suitable for isolation of protoplasts from higher plant tissue such as leaf, bulb scale, fruit epidermis,
radish roots
10
12. TYPES OF ENZYMATIC METHOD:
There are two types of enzymatic method. Both methods have certain advantages and
disadvantages (Evans and Cocking, 1977; Bajaj, 1977). Generally 50 mM CaCl2 is added
to increase the stability of released protoplasts (Rose, 1980).
1. One Step Method (Direct/Mixed Method): In this method protoplasts are isolated from
plant tissues directly by using two enzymes, cellulase and pectinase, simultaneously.
Power and Cocking (1968) used this method for isolation of protoplasts.
2. Two Step method (Sequential Method): This method was first used Takebe and others
in 1968 in two steps. In this method, cells are first isolated from callus or tissues by
using pectinase and to this cell suspension cellulase is added to digest the cell walls
and release protoplasts
12
13. Purification of Protoplasts
Commonly used methods include:-
1. Filtration (For Removal of Debris):- Debris (undigested material) can be removed from
protoplast suspension by filtering the preparation through a steel or nylon mesh of 100Āµ pore
size.
2. Sedimentation & Washing (For Removal of Enzymes):- Enzyme is removed by centrifuging
protoplast suspension at 600 rpm for 5 minutes. The protoplasts settle to the bottom of the
centrifuge tube while the supernatant is removed with the help of a pipette. The protoplasts
are then resuspended in a Washing Medium containing an osmoticum only or osmoticum
with nutrient medium or hydrated Calcium Chloride. The suspension is centrifuged again to
settle the protoplasts and the washing medium is decanted. Traces of enzymes are removed
by washing the protoplasts twice or thrice with the medium.
13
14. 3. Flotation (Separation of Protoplasts):- In this method intact protoplasts are separated
from the broken debris by suspending the protoplast preparation in 20-40% Sucrose
Solution and centrifuging at 350rpm for three (3) minutes. Intact protoplasts collect at
the top of the sucrose solution and are carefully removed with a pipette (Gregory and
Cocking, 1965; Power and Cocking, 1971; Evans et al., 1972). Schenk and
Hildebrandt (1969) used Ficoll Solution.
4. Density Buffer Method: Larkin (1976) used this method for purification of
protoplasts. In this method 0.5- 3.0 volumes of crude protoplast preparation after
filtration through sterile muslin cloth is layered on LymphoPrep (LymphoPrepā¢ is a
ready-made, sterile and endotoxin tested solution suitable for the purification of
human mononuclear cells) in the centrifuge tube and then spun at 50-200 g for about
10 minutes. The protoplasts collect as a ring between the enzyme solution and
lymphoprep and debris settle to the bottom (See Figure).
14
17. Testing Viability of Protoplasts And Cell Wall Formation
ā Cell Wall Formation Test: To the small volume of the
protoplast suspension add equal volume of 0.1%
Calcofluor solution, incubate for 5 minutes and then
observe under fluorescent microscope. The cell wall will
fluoresce and protoplast remain dark.
ā Protoplast Viability Test: Fluorescein Diacetate (FDA)
solution in acetone (5mg/l) is added to protoplast
suspension to give a final concentration of 0.01%. After
5 minutes at room temperature the protoplasts are
examined using fluorescent microscope. Only viable
protoplasts can be seen.
17
18. Factors Affecting Protoplast Isolation And Its Viability
āAs a thumb rule, low enzyme concentration at low
temperature and high pH (5-8) for short incubation period
prove to better than longer incubation periods with high
enzyme concentration, high temperature and low pH value.
Though the ionic salts when used with osmoticum degrade the
enzymes but increase the stability of protoplasts. Protoplasts
isolated in the presence of Ca++ or Mg++ showed a greater
capacity for the cell wall regeneration as compared to
protoplasts in the absence of these ions (Rose, 1980).
18
20. Methods of Protoplast Fusion
ā¢ Different methods of protoplast fusion are described by Bengochea and Dodds
(1986).
ā¢ Protoplast fusion can be broadly classified into two categories:
1. Spontaneous fusion (fuse through their plasmodesmata)
2. Induced fusion (needs fusion inducing chemicals/Fusogens)
ā¢ a) Mechanical fusion
ā¢ b) Chemo fusion
ā¢ c) Electro fusion
20
21. Spontaneous Fusion
Spontaneous Fusion Protoplast during
isolation often fuse spontaneously and this
phenomenon is called spontaneous fusion
During the enzyme treatment, protoplast
from adjoining cells fuse through their
plasmodesmata to form multinucleate (2-
40) protoplasts.
21
22. Induced Fusion Induced Fusion of freely isolated protoplasts from different
sources with the help of fusion inducing chemicals agents is
known as Induced Fusion.
Normally isolated protoplast do not fuse with each other
because the surface of isolated protoplast carries negative
charges (-10mV to -30mV) around the outside of the plasma
membrane. And thus there is a strong tendency in the
protoplast to repel each other due to their same charges.
So this type of fusion needs a fusion inducing chemicals
(Fusogens) which actually reduce the electronegativity of
the isolated protoplast and allow them to fuse with each
other (Narayanswamy S. 1994).
22
23. Types of Induced Fusion
The isolated protoplast can be induced to fuse by three ways;
A) MECHANICAL FUSION: In this method the isolated protoplast are brought into intimate
physical contact mechanically under microscope and using Micromanipulator or Perfusion
Micropipette.
B) CHEMO FUSION : Several chemicals have been used to induce protoplast fusion such as
NaNO3 , Polyethylene Glycol (PEG) and Calcium ions (Ca++). Chemical fusogens cause the
isolated protoplast to adhere (stick) each other and leads to tight agglutination followed by fusion
of protoplast (Pasha C.R et al 2007; Jogdand S.N.2001).
23
24. ā¢ NaNO3 Treatment:-Isolated protoplasts exposed to a mixture of 5.5% NaNO3 in 10% Sucrose Solution.
Incubation carried out for 5 mins at 350C followed by centrifugation. Protoplast pellet kept in water bath
at 300C for 30 mins during which fusion occurs. Induced fusion by NaNO3 was first demonstrated by
Power et al (1970).
ā¢ Treatment With Calcium Ions (Ca++) At High pH:-This method involves spinning (centrifugation) the
protoplasts in a Fusion Inducing Solution (0.05M CaCl2 , 0.4M mannitol at pH 10.5, Glycine-NaOH
buffer) for 30 minutes at 50g, after which the tubes are placed in a water bath (37Ā°C) for 40-50 minutes.
This leads to fusion of 20-50% of the protoplasts. This method was developed by Keller and Melchers
(1973) for fusing two different lines of tobacco protoplasts. The details of the protocol are described by
Bhojwani and Razdan (1983).
ā¢ Polyethylene Glycol (PEG) Treatment:-Isolated protoplasts in culture medium (1ml) are mixed with equal
volume (1ml) of 28-56% PEG (Mol. Wt. 1500-6000 dalton) in a tube. Tube is shaken and then allowed to
settle and settled protoplasts are washed several times with culture medium during which fusion occurs.
24
25. Electro Fusion
Electro Fusion:- In this method an electric
field of low strength (10Kv/m) gives rise to
dielectrophoretic dipole generation within
the protoplast suspension and a high
strength of electric field (100Kv/m) for
some micro seconds are applied this lead to
fusion.
25
26. Fusion Products
ā Fusion Products :-
ā Fusion of cytoplasm of two protoplasts results in
coalescence of cytoplasms. The nuclei of two protoplasts
may or may not fuse together even after fusion of
cytoplasms. Cells containing nonidentical nuclei are referred
to as Heterokaryons or Heterokaryocytes (Mastrangelo,
1979).
ā The fusion nuclei in a nucleate heterokaryon results in the
formation of a true Hybrid Protoplast or Synkaryocyte
(Constabel, 1978).
ā The fusion of two protoplasts from the same culture results
in a Homokaryon. Frequently genetic information is lost
from one of the two nuclei. If one nucleus completely
disappears, the cytoplasms of the two parental protoplasts
are still hybridized (see Figure) and the fusion product is
known as āCybridā (Cytoplasmic Hybrid or Heteroplast)
26
27. IDENTIFICATION AND SELECTION OF SOMATIC HYBRID CELLS
Various protocols have been proposed and practiced for the effective selection of hybrids:
1. Genetic Complementation: Complimentary selection of somatic hybrids on specific culture medium (Melscher
& Labib 1974; Smith et al.1976). In this case complementation or genetic or metabolic deficiencies of the two
fusion partners are utilized to select the hybrid component.
When protoplasts of two parents, (one parent bearing cytoplasmic albino trait and the other parent bearing green
trait) each parent carrying a non-allelic genetic or metabolic defect are fused, it reconstitutes a viable hybrid cell, of
wild type in which both defects are mutually abolished by complementation, and the hybrid cells are able to grow
on minimal medium nonpermissive to the growth of the parental cells bearing green trait.
Later, the calli of hybrid nature could be easily distinguished from the parental type tissue (albino trait) by their
green color.
The complementation selection can also be applied to dominant characters, such as dominant resistance to
antibiotics, herbicides or amino acid analogues.
27
28. 2. Mechanical isolation by visual means and knowledge of identification of somatic hybrids.
Schieder and Kohn (1986) used the scheme in which the parental protoplasts and heterokaryons were allowed
to develop calli in cultures. The morphological differences in the resultant three types of calli permitted
identification of the hybrid tissue, which could then be selected out to regenerate somatic hybrid plants.
Individual heterokaryons can be identified visually under a light microscope, be isolated mechanically by
means of Drummond pipette, and can be cloned in microdrop cultures. This approach suffers from the fact that
it requires special culture media for each particular hybrid cell type to divide and form clusters. This is also
called the fishing method.
3. Morphology :- of the plant after regeneration. Somatic hybrids in most of the cases show characters
intermediate between the two parents such as, shape of leaves, pigmentation of corolla, plant height, root
morphology and other vegetative and floral characters. The method is not much accurate as tissue culture
conditions may also alter some morphological characters or the hybrid may show entirely new traits not shown
by any of the parents.
28
29. Pigmentation
4. Pigmentation:-(Morpho-Physiological Basis of Calli):
The whole mixture of the protoplasts are cultured after
fusion treatment and the resulting calli or regenerants are
screened for their hybrid characteristics. Occasionally the
hybrid calli outgrow the parental cell colonies and are
identified by their intermediate morphology, i.e. green
with purple coloured cells.
However, the process is labour intensive and requires
glasshouse facilities. It is limited to certain combinations
showing differences in their regeneration potential under
specific culture conditions.
29
30. 5. Cytoplasmic Markers
ā Fluorochromes like FITC (fluoroscein isothiocyanate) and RITC (Rhodamine isothiocyanate) are used for labelling of
parental cells
ā Manual isolation requires that the two parental type protoplasts have distinct morphological markers and are easily
distinguishable.
ā For example, green vacuolated, mesophyll protoplasts from one parent and richly cytoplasmic, non-green protoplasts
from cultured cells of another parent. The dual fluorescence method also helps easy identification of fusion
products.
ā In this case, the protoplast labeled green by treatment with fluorescein diacetate (FDA, 1-20 mgl-1) are fused with
protoplasts emitting a red fluorescence, either from chlorophyll autofluorescence or from exogenously applied
rhodamine isothiocyanate (10-20 mgl-1). The labeling can be achieved by adding the compound into the enzyme
mixture. This can be applied even for morphologically indistinguishable protoplasts from two parents
30
31. 6. Nuclear staining: Heterokaryon is stained by carbol-fuschin, aceto-
carmine or aceto-orcein stain.
7. Phytotoxins: (soybean resistant to Hm T toxin whereas Zea mays
sensitive to it)
8. Molecular analysis: Specific restriction pattern of nuclear,
mitochondrial and chloroplast DNA characterizes the plastomes of
hybrids and cybrids. Molecular markers such as RFLP, RAPD, and
ISSR can be employed to detect variation and similarity in banding
pattern of fused protoplasts to verify hybrid and cybrid.
9. Specific amino acid :(Conavalin present in soybean but not in sweet
clover, alfalafa)
10. Auxin autotrophy :(Nicotiana glauca and Nicotiana langsdorffi)
31
32. 11. Isozyme Analysis: Multiple molecular forms of same enzyme which catalyses similar or
identical reactions are known as āIsozymesā. Electrophoresis is performed to study banding
pattern as a check for hybridity. If the two parents exhibit different band patterns for a specific
isozyme the putative hybrid can be easily verified. The isozymes commonly used for hybrid
identification include, acid phosphatase, esterase, peroxidase.
12. Chromosomal Analysis (Cytological Analysis): Chromosome counting of the hybrid is an
easier and reliable method to ensure hybridity as it also provides the information of ploidy level.
Cytologically the chromosome count of the hybrid should be sum of number of chromosomes
from both the parents. Besides number of chromosomes, the size and structure of chromosomes
can also be monitored. However, the approach is not applicable to all species, particularly where
fusion involves closely related species or where the chromosomes are very small. Moreover,
sometimes the somaclonal variations may also give rise to different chromosome number
32
33. Antibiotics
13. Antibiotics: Drug sensitivity technique was originally developed by Power et al (1976) for the selection of
hybrids of Petunia sp. This method is useful for the selection hybrids of two plant species, if one of them is
sensitive to a drug. Protoplasts of Petunia hybride (species A) can form macroscopic callus on MS medium,
but are sensitive to (inhibited by) actinomycin D. Petunia parodii protoplasts (species B) form small colonies,
but are resistant to actinomycin D.
When these two species are fused, the fused protoplasts derive both the characters-formation of macroscopic
colonies and resistance to actinomycin D on MS medium. This helps in the selection of hybrids (Fig. 44.6).
The parental protoplasts of both the species fail to grow. Protoplasts of P. parodii form very small colonies
while that of P. hybrida are inhibited by actinomycin D ā ruled out.
Ishige (1995) used transgenic resistance to kanamycin in one potato dihaploid and hygromycin in another to
regenerate exclusively somatic hybrids that varied for ploidy. However, the restrictions of this system are the
extensive pre-breeding required to introduce transgenic resistance into the protoplast fusion partner(s) and the
limitation of the procedure only to transgenic plants
Pandeya et al., (1986) adopted a similar procedure for somatic hybrids between Nicotiana sylvestris and N.
knightiana. This selection system makes use of two dominant drug resistant cell lines. Selection of somatic
hybrids following protoplast fusion of two such cells, lines is carried out on, media containing both drugs.
33
35. CULTURE OF HYBRID CELLS
Hybrid cells are cultured on suitable
medium provided with the appropriate
culture conditions.
ā¢ Iscove's MDM with 25 mM Hepes.
ā¢ DMEM/F-12 with 15 mM HEPES.
ā¢ Alpha MEM with Nucleosides
ā¢ RPMI 1640 Medium
35
36. REGENERATION OF HYBRID PLANTS ā¢ Plants are induced to regenerate from hybrid
calli. These hybrid plants must be at least
partially fertile.
ā¢ CELL WALL REGENERATION: May be
completed in two to several days. Although
protoplast in culture generally start regenerating
a cell wall within a few hours after isolation.
ā¢ Protoplast lose their characteristic spherical
shape once the wall formation is complete.
ā¢ Regeneration of cell wall can be demonstrated
using Calcalfluor White ST fluoresecent Stain or
Tinapol solution.
1. Protoplast fusion and somatic hybrid plantlet regeneration of
cvs. āKensington Prideā + āHadenā. (a) Young leaves of cv.
āHadenā. (b) PEM induction on ovular nucellus of cv.
āKensington Prideā. (c) PEM suspension culture. (d) Isolated
protoplasts stained with Fluorescein Diacetate (FDA) under UV.
(e, f) PEG-induced binary protoplast fusion. (g) Early cell
division after protoplast culture. (h) PEM formation. (i) Globular
embryo production. (j) Heart and torpedo-shape embryo
production. (k) Mature embryos. (l, m) Germination of embryos
with elongated radicle. (n) Regenerated somatic hybrid plantlets.
(o) Plantlet at early acclimatization stage. (p) Acclimatized plant
after 5 months. 36
37. PEG-mediated protoplast
transformation. (a) Tobacco leaf
strips treated with protoplasting
enzyme solution. Protoplasts
prior to PEG treatment (b), and
recovery without selection for 1
(c), 2 (d), or 3 (e) weeks after
PEG treatment, with newly
formed cells lighter green in
color. For selection of
transformants, 2-week-old PEG-
treated protoplasts are typically
embedded in agarose for a
week prior to antibiotic
selection for another 6 weeks.
Putative resistant calli in
solution (f) or in embedded gel
(g, h) transferred to plates (i) for
shoot formation (j, k). Shoots
excised to root in tissue culture
boxes (l) 37
38. 38
PEG-induced fusion of citrus
embryogenic protoplasts with
leaf protoplasts
RAPD analysis
Root-tip cell
Rooted cutting of somatic
hybrid rootstock
Fruiting tree of somatic
hybrid breeding parent
somatic hybrid
39. Principle of Somatic Hybridization
ā¢ The principle of somatic hybridization is to combine the protoplasts of two species and "fuse" the two
protoplasts to produce a heterokaryon (a cell containing genetically different nuclei).
ā¢ The process of fusion is carried out in the presence of calcium ions either at high pH (10.5) or with the aid of
polyethylene glycol (PEG) at a concentration of 25070-30%. Often a high loss of viable cells occurs,
depending upon the genus, species, age of plant materials, and laboratory procedures, the principle problem
being microbial contamination. However, with cell concentrations (density) at 2 x 105 cells/milliliter, a
number of heterokaryons are still expected (Power et al., 1989).
ā¢ Following removal of the fusion media, the cells are transferred to a new medium for growth, and the cells
can be observed microscopically for fusion of the two species, viability, and for rate of growth. If the fused
cells are viable, the first mitotic division can be observed within 4 days.
ā¢ If this event does not occur, death of the heterokaryon ensues. Because plants vary widely in their need for
hormones, light, and temperature, every somatic hybrid cross must entail a thorough study of growth
requirements for success. Quite often the new somatic hybrid will develop a callus tissue (undifferentiated
tissue) which must be transferred to a suitable medium for bulb growth, root development, and subsequent
growth (power et al., 1989).
39
41. ā¢ For the development of stable inter-generic allohexaploid Brassica, we
have used B. juncea cv. RLM-198 as the cultivated germplasm with Indian S.
alba (Gene Bank Accession No. DRMR-2183) as a donor for the yellow seed
color and resistance to S. sclerotiorum. The B. juncea cv. RLM-198 was
selected as a fusion parent due to its excellent regeneration potential. The
three experiments included in this study were conducted using the same
fusion parents.
ā¢ The protoplast of hypocotyl cells of B. juncea cv. RLM-198 and mesophyll
cells of S. alba were isolated using the protocol of Kirti and Chopra (1990),
followed by protoplast fusion, regeneration, and acclimatization according
to Kirti et al. (1995). A total of five plants (clones) from each event were
transferred to pots filled with soil:solarite (1:1) under net house conditions
at the Indian Agriculture Research Institute (IARI), New Delhi, India and
maintained till harvesting.
41
45. SYMMETRIC HYBRIDS--PRODUCTION OF NEW SPECIES
ā¢ Symmetric hybrids can be produced between species, which cannot be hybridized sexually.
These hybrids can be readily used in breeding programs for transfer of useful genes to crops or
may be useful as new species.
ā¢ The first symmetric somatic hybrid of Citrus was created by protoplast fusion of C. sinensis
and Poncirus trifoliata (Ohgawara et al., 1985) and the production of hybrid plants between two
sexually incompatible Citrus genera was first reported in 1988, where C. sinensis L. Osb. cv.
āHamlinā protoplasts were fused with Severinia disticha (Blanco) Swing protoplasts (Grosser et
al., 1988).
Merits
45
46. Family Brassicaceae
ā¢ Model family for somatic hybridization
ā¢ Hybridization have been performed in Brassica genus
ā¢ Resynthesis of Brassica napus, an intergeneric hybrid
ā¢ Intertribal hybrid are also produced e.g., Raphanus x B.napus
46
47. Family Fabaceae
ā¢ Regeneration of plants was initially
troublesome
ā¢ Now achieved in several genera like
Pisum,Trifolium,especially in Medicago
ā¢ Flowering hybrids b/w Medicago sativa &
Medicago falcate
ā¢ Intergeneric fusion b/w Onobrychis
viciifolia, Sanfoin & Alfalfa
47
48. Family Poaceae
ā¢ Somatic hybridization was initially
difficult
ā¢ Now several intergenric and
intrageneric have been produced
ā¢ e.g., Panicum maximum (+)
Pennisetum americanum, Saccharum
officinarum (+) P. americanum etc
ā¢ Much work has been done on
Saccharum spp.
48
49. Family Solanaceae
ā¢ For disease & insect resistance in eggplant,
Solanum melongena
ā¢ To restore the ploidy level and for viral resistance
in potato
ā¢ In Tomato, several interspecific hybrid plants have
been produced
ā¢ E.g., Tomato + Solanum tuberosum,
ā¢ Tomato + Nicotiana tabacum,
ā¢ Tomato + S. tuberosum etc
49
50. CYTOPLASMIC TRANSFERS ARE TIME SAVING : Cytoplasm transfers can be affected in one year, while
backcrossing may take 15-16 years. Even where backcrossing is not applicable, cytoplasm transfers can be made using this
approach.
ā Somatic Hybrids for Cytoplasmic Male Sterility Methods have been developed to substitute the nucleus of one species
into the cytoplasm of another species, whose mitochondria are inactivated. This type of substitution in some cases, led to
generation of cytoplasmic male sterility.
ā For this purpose, a report by Melchers (1992); and his coworkers, the two types of protoplasts, used for the production
of, somatic hybrids, and were treated differently, as follows:
ā mesophyll protoplasts of tomato (Lycopersicon esculentum) were treated with iodoacetamide (IDA) to inactivate
mitochondria and mesophyll protoplasts of Solanum acaule (or S. tuberosum = potato) were irradiated with Ī³ or x-rays
to inactivate nuclei. (see figure)
ā The protoplasts were mixed in 1: 1 ratio and induced to fuse using Ca2+ and PEG, leading to the production of
heterologous hybrids. Among the fusion products, some hybrid tomato plants were indistinguishable from the original
cultivars, with respect to morphology, physiology and chromosome number (2n=24), but exhibited various degrees of
male sterility. The variation included (Melchers,1992)
MITOCHONDRION-CHLOROPLAST FUSION (RECOMBINANT ORGANELLAR GENOMES) : Mitochondria of one
species can be combined with chloroplasts of another species. This may be very important in some cases, and is not
achievable by sexual means even between easily crossable species. Recombinant organellar genomes, especially of
mitochondria, are generated in somatic hybrids and cybrids. Some of these recombinant genomes may possess useful
features.
50
51. Melchers (1992); and
his coworkers, the two
types of protoplasts,
used for the production
of, somatic hybrids,
and were treated
differently with
iodoacetamide (IDA) ,
Ī³ or x-rays
51
52. Production Of Novel
Interspecific And Intergenic
Hybrid
ā¢ Pomato (Hybrid of potato and tomato)
(Melchers,1978)
ā¢ Protoplasts arisen by fusion of tomato and
potato protoplasts. The cytoplasmic part of
the tomato (Lycopersicon esculentum var.
cerasiforme mut. yellow green 6) is
recognizable by the green chloroplasts present
in the tomato mesophyll protoplasts. The
cytoplasmic part of the potato (Solarium
tuberosum, dihaploid stock HH 258) is
colourless as the potato protoplasts were
made from submersed cultured callus cells
with proplastids.
52
53. ā¢ Production Of Fertile Diploids And Polyploids From Sexually Sterile Haploids, Triploids And
Aneuploids: Anssour et al. (2009) examined both allo- and auto-tetraploid Nicotiana species, and
showed that there were substantial changes both in morphology and in the genome which are
found in the hybrid species compared with their ancestral diploids.
ā¢ GENE TRANSFER Gene Transfer for disease resistance (e.g. TMV, Potato Virus X, Club Root
Disease), abiotic stress resistance (cold tolerance gene in tomato), herbicide resistance and many
other quality characters. Asymmetric hybridization is very promising as it allows partial genome
transfer (Derks et al., 1992; Trick et al., 1994; Liu & Deng, 2002), which may be better tolerated
than a whole-genome transfer (Ramulu et al., 1996a,b). As in other agricultural species, trait
introgression from āwildā species of the genus Nicotiana has been used to improve the cropped
species, and characters from at least 13 different species have been transferred into tobacco
(Lewis, 2011).
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54. ā¢ PRODUCTION OF HETEROZYGOUS LINES : Production of heterozygous
lines in the single species which cannot be propagated by vegetative means.
ā¢ FATE OF PLASMA GENES : Somatic cell fusion is useful in the study of
cytoplasmic genes (plasma genes) and their activities and this information can
be applied in plant-breeding experiments.
ā¢ PRODUCTION OF UNIQUE HYBRIDS OF NUCLEUS AND
CYTOPLASM : Cybridization has made it possible to transfer cytoplasmic
male sterility.
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55. DEMERITS
ā¢ CEREALS & PULSES : Techniques for protoplast isolation, culture and fusion are not
available for many important crop species like many cereals and pulses.
ā¢ CHROMOSOMAL ELIMINATION : In many cases, chromosome elimination occurs from
somatic hybrids leading to asymmetric hybrids. Such hybrids may be useful, but there is no
control on chromosome elimination.
ā¢ GENETIC INSTABILITY : Many somatic hybrids show genetic instability, which may be an
inherent feature of some species combinations.
ā¢ ABNORMALITIES : Many somatic hybrids either do not regenerate or give rise to sterile
regenerants. Such hybrids are useless for crop improvement. All interfamily somatic hybrids
are genetically unstable and/or morphologically abnormal, while intergeneric and intertribal
hybrids are genetically stable but produce abnormal and/or sterile plants or only teratomata.
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56. ā¢ POOR REGENERATION : Poor regeneration of hybrid plants
ā¢ NON-VIABILITY : Non-viability of fused products.
ā¢ INEFFICIENT SELECTION METHODS : There are limitations in the
selection methods of hybrids, as many of them are not efficient. Not very
successful in all plants.
ā¢ NO CONFIRMATION OF EXPRESSION OF PARTICULAR TRAIT : No
confirmation of expression of particular trait in somatic hybrids. Techniques
for protoplast isolation, culture and fusion are very complicated.
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57. CONCLUSION
āŗProtoplast technology has various applications other than regeneration of complete plants and production of
hybrids of sexually incompatible species. These techniques have been instrumental in generating basic
scientific information on cell biology, plant incompatibility, membrane functions, cell organelle studies, cell
wall regeneration, ultrastructure and molecular architecture of plant cells. These techniques are now being
used for transfer of cytoplasmic male sterility. Protoplasts can take up macromolecules (nucleic acids and
proteins), viruses, cell components like chromosomes and chloroplasts by phagocytosis. Somatic
hybridization allows transfer of cytoplasmic organelle in a single generation and offer unique opportunities
for combining mitochondria of one species and chloroplast of another species in a single hybrid. This
technique in the future will be one of the most frequently used research tools for tissue culturists, molecular
biologists, biochemical engineers and biotechnologists.
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