CA2385416A1 - Fertility restorer gene for "polima" cytoplasmic male sterility - Google Patents

Abstract

The present invention provides a restorer (Rf) gene for the "Polima"
cytoplasmic male sterility in Brassica campestris (synonymus Brassica rapa) plants, and to a method of producing restorer lines in Brassica campestris.
The invention further reveals that the restoration of "Polima" CMS in B.
campestris is controlled by a single dominant gene. The identification of restorer of "Polima" CMS is potentially useful for the development of hybrid varieties in B. campestris.

Description

TITLE OF THE INVENTION
FERTILITY RESTORER GENE FOR 'POLIMA' CYTOPLASMIC MALE
STERILITY
FIELD OF THE INVENTION
The present invention relates to a fertility restorer (Rf) gene for 'Polima' cytoplasmic male sterility (CMS) in Brassica campestris and to a method of producing restorer lines for hybrid seed production.
BACKGROUND OF THE INVENTION
Breeding for yield improvement in the Brassica crops can be done by utilizing the phenomenon of hybrid vigour or heterosis. When two disparate parents having desirable agronomic characters, such as high yield potential, disease resistance, etc. are combined by traditional breeding methods, the F1 hybrid plants show higher yield than either of the parents. One of the most economical and convenient means for producing uniform heterotic population F1 hybrids is to utilize cytoplasmic male sterility (CMS). A CMS plant is rendered incapable of producing pollen grains (the male reproductive unit in plants) and therefore cannot get self-fertilized, thus ensuring cross pollination and the development of true hybrid seeds. Factors reasonable for imparting CMS reside in the cytoplasmic organelle the mitrochondria and are transmitted maternally. Therefore, the F1 hybrid plant obtained by crossing a CMS female parent with a pollen donor parent is sterile and incapable of setting seeds. This is a highly undesirable feature in a crop where seed is the harvested product. However, this problem is rectified by the presence of a genetic factor in the nucleus of the pollen donor parent. This genetic factor when present in its active form, suppresses the expression of CMS and restores male fertility. This fertility restoration factor (Rf) is an essential component for the production of viable hybrid seeds at commercial scale where seed is the harvested product.

In Brassica plants a number of CMS systems are available which are reported to have originated either from Bras-sica species itself or from related genera. For example, 'Polima', one of the well known CMS systems in Brassica has been shown to have its origin in Brassica napus.
Another well worked out CMS system in Brassica is 'ogura' which derived its CMS cytoplasm from radish. Usually it has been observed that the restorer factors for the respective CMS systems come from the species that contribute the CMS inducing cytoplasm. The restorer for 'ogura' was transferred from radish to Brassica plants (Delourme et al. 1991, Proc 8th Int. Rapeseed Congr.5, 1506-1510). The restorer for 'Polima' was identified in B. napus itself.
Brassica campestris (synonymus B. rapa) is one of the edible oil seed producing Brassica type plant and is grown in Western Canada, parts of Sweden and Finland and north-west China where summer growing season is too short to accomodate other longer duration Brassica crops. In India, three distinct types of Brassica cam-pestris, namely brown sarson, yellow sarson and toria are grown in northern and eastern India. Although signi-ficant heterosis for yield in crosses between B. campes-tris cultivars has been reported from India (Rai and Singh 1994, Indian J genet. 54: 310-314; Varshney and Rao 1997, Indian J. Genet.57: 91-97) and Canada (Schuler et al. 1992, Can J. Plant Sci.72, 127-136; Falk et al. 1994, Can. J. Plant Sci. 74: 441-445), the develop-ment of hybrid cultivars has not been possible due to non-availability of suitable CMS-restorer systems.
A number of CMS systems such as Diplotaxis muralis (Hinata and Konno 1979), Japan J. Breed, 29: 305311), Oxy (Prakash and Chopra 1988, Plant Breeding 101: 253-255), Tour (unpublished result) and Eruca sativa (Matsu-zawa et al. 1999, Plant Breeding 118: 82-84) have been earlier identified in B. campestris. However, none of these have been used for hybrid seed production either due to chlorosis or lack of stability in CMS
lines or lack of proper restorer lines.
OBJECTS OF INVENTION
An object of this invention is to propose a restorer (Rf) gene for the 'Polima' cytoplasmic male sterility in Brassica campestris plants.
Another object of this invention is to propose a process for introducing the identified restorer (Rf) gene for the 'Polima' cytoplasmic male sterility in Brassica campestris.
SUMMARY OF THE INVENTION
According to this invention, there is provided a process of producing restorer (Rf) gene for 'Polima' CMS in Brassica campestris (syn. B.rapa) plant which comprises in the steps of .
i) Crossing 'Polima' CMS B. napus with B. campestris to produce F1 generation.
ii) Subjecting the F1 generation to successive steps of backcrassing with B. campestris and atleast upto BC3 to produce a stable male sterile line for 'Polima' CMS.
iii) Crossing said BC3 plant with 'Candle' or 'ATC
94211' to produce F1 plants which are male fertile.
Further, according to this invention, there is provided the identification of a restorer factor for 'Polima' CMS in Brassica campestris. The process also provides that the fertility restoration is governed by a single Mendelian locus. In accordance with this invention 'Polima' CMS was transferred from B. napus var. ISN
706 to B. campestris. To effect this transfer, inter-specific cross was made between 'Polima' CMS B. napus var. ISN 706 with B. campestris plants. The resultant F1 hybrid plant was repeatedly back-crossed to normal B. campestris (used as pollen donor) till at least BC3.
The BC3 generation B. campestris containing 'Polima' CMS cytoplasm was subsequently crossed with other B.
campeatris varieties such as long duration canola qua-lity 'Candle' or accession 'ATC 94211'. The F1 plants segregated for male fertility and male sterility. The fertile F1 plants were self-pollinated. The resultant F2 progeny plants were scored for the segregation of male fertile and male sterile plants in order to esta-blish the inheritance pattern of the fertility restorer factor.
BRIEF DESCRIPTION OF THE DRAWING
The accompanying drawing .
Fig.l is a schematic flow diagram showing the breeding methodology for the identification of restorer lines for 'Polima' CMS B. campestris. It comprises the prepa-ration of Fl hybrid by making inter-specific cross between 'Polima' CMS B. napus var. ISN 706 and B. cam-pestris var. 'Pusa kalyani' followed by three back-crosses of the said F1 hybrid to B. campestris var.
'Pusa kalyani'. Subsequently, BC3 'Polima' CMS B. cam-pestris var. 'Pusa kalyani' was crossed with 'Candle' and 'ATC 94211'. Fertile Fl plants were self pollinated to raise F2 progeny.
DETAILED DESCRIPTION OF THE INVENTION
The present invention relates to a plant of the species B. campestris, characterised in that it contains a Brassica nucleus and the cytoplasm having 'Polima' CMS organelles. Example of Brassica campestris plant WO 01/22804 CA 02385416 2002-03-20 PCT/j11J99/~~051 usable in the present method include any plant line or cultivar that includes the Rf factor for the 'Polima' CMS.
According to the present invention, the 'Polima' CMS
B. campestris is initially developed through conven-tional breeding method by crossing 'Polima' CMS B.
napus var. ISN 706 with a B. campestris plant.
Thus according to this invention, there is provided a breeding process for producing a stable 'Polima' CMS line in B. campestris which comprises in the steps of .
Making an inter-specific cross between 'Polima' B.
napus var, ISN 706 with B. campestris to produce Fl generation. Normal fertile B. napus ISN 706 is a synthe-tic Brassica napus the seeds of which were obtained from Indian Agricultural Research Institute, New Delhi, India. 'Polima' CMS was introduced in B. napus ISN
706 from a unknown French variety containing 'Polima' cytoplasm (Sodhi et al. 1993, Plant Breeding 110: 334-337). After crossing, siliqua (seeds) were developed.
The siliqua were collected, examined for the seeds and the seeds were planted.
The resulting F1 plants were male sterile and partially female fertile and hence, upon back-crossing to B.
campestris produced a few seeds. The seeds were planted to raise BCl generation.
Subjecting the BC1 generation to successive steps of back-crossing with B. campestris and at least upto BC3 to produce a stable 'Polima' CMS B. campestris.
Preferably, but without implying any limitation, Fls of B, napus ISN 706 a.re back-crossed with B. campestris till BC6 generation. Specifically, B, campestris, variety used in the present invention is, for example, B, campestris var. 'Pusa kalyani'. B. campestris var.
'Pusa kalyani' is a released cultivar in India. It is self-incompatible, brown sarson type, and has high contents of erucic acid ( 500) and glucosinolates ( 70 umoles/g deoiled meal). The seeds of this variety were obtained from Indian Agricultural Research Institute, New Delhi, India.
From BC3 generation onwards, the progeny plants have the appearance of 'Pusa kalyani' and are completely male sterile show floral features typical of 'Polima' CMS, ie. crinkled petals and short stamens bearing small conical anthers. The pollen grains are shriveled and do not stain with fluorescein diacetate (FDA), a specific stain for accessing the pollen viability.
The staining procedure is according to the protocol described by Sodhi et al. (1994, Plant Breeding 112:
223-227). In all the subsequent back-cross generations, the 'Polima' CMS in 'Pusa kalyani' remain completely stable.
'Polima' CMS B. campestris var. 'Pusa kalyani' BC3 is crossed with two other lines of B. campestris namely, 'Candle' and 'ATC 94211'. The F1 plants of 'Polima' 'Pusa kalyani' x 'Candle' and 'Polima' 'Pusa kalyani' x 'ATC 94211' segregated for male fertility and male sterility. The fertile Fl plants had normal floral features with respect to flower opening and floral organ development. The pollen viability of the male fertile F1 plants of these two crosses are 99o and the production of the viable pollen are similar to that of normal B. campestris var. 'Pusa kalyani' (Table 1). The F1 plants showed normal seed set under open pollination.
Fertile F1 plants of the crosses mentioned above were self pollinated to obtain F2 seeds. The seeds were planted to raise F2 generation. Segregation for male fertility and sterility was also observed in the F2 generation of these crosses. Segregation pattern for fertility and sterility in F1 and F2 generations indi-cate that the fertility restoration is controlled by WO 01/22804 CA 02385416 2002-03-20 pCT/IN99/00051 a single dominant gene and the parental population of 'candle' and 'ATC94211' are heterozygous for the fertility restorer gene (Table 1). The fertile restored F2 plants in both these crosses have normal floral features. The sterile segregants exhibit floral features typical of 'Polima' CMS ie. crinkled petals and short stamens bearing small conical anthers. The pollen grains were shriveled and did not stain with FDA. 'Candle' is a Canadian 'Canola' quality cultivar having low erucic acid and low glucosino-late. The seeds of 'candle' were obtained from Agriculture Canada, Saskatoon, Canada. 'ATC94211' is an Australian low erucic acid line and seeds were obtained from Brassica germplasm bank from Australia.
Although the invention has been described primarily in connection with the special and preferred embodiments, it will be understood that it is capable of modification without departing from the scope of the invention. The following claims are intended to cover all variations, uses of adaptations of the invention, following, in general, the principles thereof and including such departures from the presented disclosure as come within known or customary practice in the field to which the invention pertains, or as are obvious to persons skilled in the field.
Table 1. Pollen production and viability* and inheritance of fertility restorer gene in 'Polima' CMS B. campestris Cross Generation Phenotype E ~ Pollen Pollen of plant viabi- produc-bility tion in fer- mean tile tSDx104 3 0 Fertile St~le plants 'Polima' 'Pusa F1 37 35 1:1 0.0555 99 10.8~3.7 kalyani' x F2 235 88 3:1 0.8679 - -'Candle' ~Pol~ma " Pusa F1 30 42 1:l 2.000 99 10.6~3.3 kalyani' x 'ATC94211' F2 220 70 3.1 0.1143 - -*Control 'Pusa kalyani' showed pollen viability of 97°s and pollen pro-duction mean 10.2~3.1 The following examples are provided to further illustrate the present invention and are not to be confused as limi-ting thereof.
r,v-n.wrr r, ~
The present invention involves conventional field breeding techniques. The breeding experiments were conducted twice in a year, utilizing the winter growing season (October-April) in the plains (Delhi) and summer growing season (May-September) in the higher altitude areas of Northern Himalayas (Leh, J&K). The plants were grown by sowing seeds in 3m long rows with 40cm spacing between rows and l5cm spacing between plants within the rows.
Transfer of 'Polima' CMS from B. napus to B, campestris:
An inter-specific cross was made between 'Polima' CMS b.
napus var. ISN706 and B. campestris. Ten inflorescence on 'Polima' CMS B. napus var. ISN706 were randomly selected and 10-12 buds from each of these inflorescence were emas-culated and pollinated with B. campestris var. 'Pusa kalyani'.
Pod development was normal but the number of seeds per pod was less, around 8-10/pod as against 18-20 in normal cases. About 100 Fl seeds were harvested.
F1 seeds were planted in the next growing season. Germina-tion occurred within 5-7 days. Standard intercultural prac-tices were followed. Plants were intermediate between B.
napus and B. campestris in their morphology and were uniform in appearance. The plants flowered after 70 days and flowe-ring was uniform. All the plants were male sterile and partially female sterile. Flowers had short stamens bearing conical whitish anthers, which were devoid of pollen grains.
The said F1 plants were back-crossed with B. campestris var. 'Pusa kalyani'. About 100 crosses were made, each cross comprising about 10-12 buds. Siliqua developed in situ.
The development was however retarded as compared to that of normal siliqua and only 2-3 siliqua developed per cross (1.5-2.5cm having 2-3 seeds as against around 5.Ocm and 16-18 seeds in normal case).
The BCl seeds were harvested and sown in the next growing season. Plants showed variation in their morphological features. Some were intermediate between B. napus and B.
campestris and some resembled B. campestris more closely.
These plants segregated for initiation of flowering. The plants having closer resemblance with B. campestris flowered early. All the plants were male sterile. Three of the BC1 plants having closer resemblance with B. campestris were selected for further back-crossing. About 20 crosses were made each having 10-12 buds. Female sterility and siliqua development showed discrete improvement over Fl. Number of seeds was around 6-8/siliqua, which was still low as compared to the normal pods.
BC2 seeds were harvested and sown in the next growing season.
Resemblance of the plants to B. campestris was more percep-tible in this generation and majority of them came to flowe-ring within 60 days of sowing. Flowers were completely male sterile and female fertility was normal. About 15 crosses were made each having 10-12 buds. Siliqua develop-ment was almost normal, with each siliqua having on an average 12 seeds.
The BC3 seeds were harvested and sown during next growing season. The plants completely resembled B. campestris var.
'Pusa kalyani' phenotypically and came to flowering within 60 days. The flowers were completely male sterile with crinkled petals, short stamens and small whitish conical anthers. The female fertility was normal and the siliqua developed normally upon back-crossing to B. campestris var. 'Pusa kalyani' and were about 5cm long. Tt~ number of seeds per pod varied between 12-15/pod. Seed setting was normal on open-pollination.

VVD 01/22804 CA 02385416 2002-03-20 pCT/IN99/00051 T~'YTMDT F~ 7 Identification of restorer gene for 'Polima' CMS in B.
campestris and its mode of inheritance .
Inter-varietal crosses were made between 'Polima' CMS B.
campestris var. 'Pusa kalyani' with two other varieties namely 'Candle' and 'ATC 94211'. Siliqua development and seed set were normal and 16-18 seeds per pod were obtained.
The Fl seeds were harvested.
The F1 seeds were space planted in eight rows at a distance of approximately 25cm between plants for each of the crosses.
F1 plants derived from both 'Pusa kalyani' x 'Candle' and 'Pusa kalyani' x 'ATC 94211' displayed unit phenotype and floral morphology intermediate between the respective parents.
The plants showed 1:l segregation for male fertility and sterility. The pollen viability of the male fertile F1 plants of these two crosses are 990 and the production of the viable pollen are similar to that of normal B. cam-pestris var. 'Pusa kalyani' (Table 1). The F1 plants showed normal seed set under open pollination. The fertile F1 plants were selfed. Prior to the opening of the buds the inflorescence were covered securely with butter paper bags to prevent cross-pollination. The siliqua were allowed to develop within the confine of the bag till the grain filling stage. On an average, 12 seeds per siliqua were obtained. The selfed seeds were harvested.
F2 seeds of each cross were space planted with a distance of about 20cm between plants in 22 rows each. Segregation was observed for plant morphology and flowering duration.
At the time of flowering plants were scored in the field for male fertility and male sterility. The segregation pattern was recorded as 3 male fertile: 1 male sterile.
Plants were female sterile since seed setting was normal on open pollination.

Claims (12)

WE CLAIM:

1. A process of producing restorer (Rf) gene for 'Polima' CMS in B. campestris plant which comprises in the steps of :
i) crossing 'Polima' CMS with B. campestris to produce F1 generation, ii) subjecting the Fl generation to successive steps of back-crossing with B. campestris and at least upto BC3 to produce a stable male sterile line for 'Polima' CMS, iii) crossing said BC3 plant with B. campestris plants other than that subjected under step (ii) to produce F1 plants which are male fertile, iv) self-pollinating the fertile F1 plants of the above said crosses to produce F2 plants segregating 3 male fertile : 1 male sterile.

2. A process as claimed in claim 1 wherein B. campestris of step (ii) is selected from B. campestris 'Pusa kalyani'.

3. A process as claimed in claim 1 wherein step (iii) com-prises crossing said BC3 plant with B. campestris selected from 'Candle' or 'ATC94211'.

4. A process as claimed in claim 1 or 2 wherein the Fl generation is subjected to successive steps of back-crossing with B. campestris to produce BC6.

5. A process as claimed in claim 1 or 2 wherein Fl genera-tion is subjected to the step of back-crossing with B.
campestris to produce BC1.

6. A process as claimed in claim 5 wherein BC1 is subjected to the step of back-crossing with B, campestris to produce BC2.

7. A process as claimed in claim 6 wherein BC2 is subjected to the step of back-crossing with B, campestris to produce BC3.

8. A process as claimed in claim 1 wherein 'Polima' CMS
is 'Polima' CMS b. napus var. ISN 706.

9. A fertility restorer (Rf) gene for polima cytoplasmic male sterility in B. campestris comprising B. campestris modified with 'Polima' CMS by interspecific crossing fol-lowed by intervarietal crossing.

10. A fertility restorer (Rf) gene as claimed in claim 9 wherein said 'Polima' CMS is 'Polima' B. napus ISN 706.

11. A fertility restorer (Rf) as claimed in claim 9 wherein said B. campestris modified by interspecific breeding is B. campestris 'Pusa kalyani'.

12. A fertility restorer (Rf) as claimed in claim 9 wherein said variety of B. campestris for intervarietal crossing is selected from 'Candle' and 'ATC 94211'.