Secondary Chromosome Associations in Uraria picta (Jacq.) DC (Family: Leguminosae)

Bhattacharya, Arnab; Datta, Animesh

doi:10.1508/cytologia.75.37

Cited by 13 publications

(5 citation statements)

References 20 publications

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“…of West Bengal, India; moisture content 11.6%; treated with ethyl methane sulphonate (EMS), diethyl sulfate (dES) and hydroxylamine (HA); treatments: 0.25%, 0.50% and 1.00% for 3 and 6 h durations each), a dwarf plant (1.00% EMS, 6 h; 0.16% over the M 2 mutant population) possessing 100.0% sterile pollen grains (assessed following 1.0% acetocarmine staining technique, (Marks 1954); fully stained pollen grains were considered fertile) was screened. Meiotic configurations assessed (as suggested by Bhattacharya and Datta 2010a) in the marked plant were cytologically normal and alike to control. The male sterile plant formed pods (grey pods yielded viable seeds and black pods set nonviable seeds (Bhattacharya and Datta 2010b)) and set viable seeds on open pollination (controlled pollination is rather difficult due to its reproductive biology), thereby indicating female fertility of the marked plant.…”

Section: Methodsmentioning

confidence: 78%

A Report on Genetic Male Sterility in Uraria picta (Jacq.) DC.

Bhattacharya

Datta

2011

cytologia

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Summary A male sterile-female fertile mutant of Uraria picta (Jacq.) DC. (Family-Leguminosae, Papillionoidae), possessing dwarf habit, normal chromosome behaviour at meiosis and 100.0% sterile pollen grains (1.00% EMS, 6 h; 0.16% over the M 2 mutant population), was identified and it segregated into 4 normal and 3 mutant plants at M 3 (70 seeds sown, 11 plants germinated, but 7 survived till maturity). Out of 3 mutants, 1 plant showed abnormal meiosis, 100.0% sterile pollen grains with size variations and in some cases pollen grain agglutination, and the other 2 plants instead showed normal meiosis and 100.0% sterile pollen grains; these were designated as MS 1 and MS 2 respectively. Meiotic chromosome analysis and studies of pollen grains (pollen viability tests: Lugol's Iodine, Aniline blue, x-gal, Amido black, TTC, Neutral red and Methylene blue; DAPI staining for pollen nuclei; SEM analysis) in relation to untreated control revealed possible differential gene behaviour in MS 1 (evident in microsporogenesis as well as microgametogenesis) and MS 2 (microsporogenesis only). Male sterility is a non-structural nuclear type (monogenic recessive-ms 1 ms 1 ) and is being reported for first time in the species.Key words Uraria picta, Male sterility, Pollen viability staining, DAPI, SEM analysis, Differential gene action.Genetically controlled male sterile-female fertile plants, natural or induced, are widely reported in different plant species stating their implications for efficient breeding and crop improvement. Further, such plant types, depending upon their crossability, would be useful for the conservation of desirable gene(s). Genetic male sterility arising as the consequence of mutation was reviewed in angiosperms and it was reported that the male sterile lines of different plant species, though morphologically non-differential to wild, formed totally sterile pollen grains due to the action of genes at pre-meiotic, meiotic or post-meiotic stages (Gottschalk and Kaul 1974, Skibbe et al. 2002). Daskalov et al. (2007) reported sporogenous male sterility in tomato and pepper and the mutants deviate from wild genotype in the absence of fertile pollen grains, and pollen abortion or breakdown was due to gene action controlling meiosis. The uniqueness of meiosis is that it is genetically programmed by a set of gene(s) which are sex-, time-, site-and stage-specific (Graybosch and Palmer 1988, Kaul 1988, Skorupska and Palmer 1990, Twell et al. 1991, Nirmala and Kaul 1993, Palmer 2000, Datta and Saha 2001, Ranganath 2005, and mutations distorting the harmonious combination of the universality of male meiotic gene(s) may result in the non-development of functional pollen grains. The present communication describes an EMS-induced male sterile-female fertile mutant screened at M 2 and its progenies at M 3 of Uraria picta (Jacq.) DC. (Family-Leguminosae, Papillionoidae), an important herb in Ayurvedic medicine (Ayurvedic name: Prishni parni). The basic objective of the work is to study the expression of male sterility in re...

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Section: Methodsmentioning

confidence: 78%

A Report on Genetic Male Sterility in Uraria picta (Jacq.) DC.

Bhattacharya

Datta

2011

cytologia

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“…Hirayoshi (1957) disagreed with the hypothesis which considers the involvement of homologous chromosome in secondary association and after examining careful results in Oryzeae and Zizanieae gave the conclusion that the secondary association may be a phenomenon operating under bio-and physico-chemical reactions and has no relation to the true homology of chromosomes. Secondary pairing between bivalents has been considered as an indicator of polyploid nature of a species as reported in Ocimum (Mukherjee and Datta, 2005), and Uraria picta (Bhattacharya and Datta, 2010). According to Stebbins (1950), secondary association can be considered a phenomenon which depicts the polyploid nature of a species or genus, but elaborate phylogenetic predictions cannot be drawn from this as the secondary pairing between bivalents is considerably modified by other chromosomal changes.…”

Section: Discussionmentioning

confidence: 99%

“…According to Stebbins (1950), secondary association can be considered a phenomenon which depicts the polyploid nature of a species or genus, but elaborate phylogenetic predictions cannot be drawn from this as the secondary pairing between bivalents is considerably modified by other chromosomal changes. But amidst these explanations, Bhattacharya and Datta (2010) concluded that no inferences should be drawn regarding the polyploidy origin of species solely on the basis of secondary pairing. As an alternative, the cytological data must be co-related with locus specific molecular markers using FISH (Fluorescent in situ hybridization) to get a precise decision (Litcher, 1997).…”

Section: Discussionmentioning

confidence: 99%

Secondary Chromosomal Association in Kidney Bean ( Phaseolus Vulgaris L. )

Kumar¹,

Chaudhary²

2014

JJBS

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The present study documents the mutagenic efficacy of gamma ray and sodium azide on the chromosomal association pattern of bivalents and meiotic behavior in Phaseolus vulgaris L. The seeds were irradiated with different doses of gamma rays viz.10 krad, 20 krad, and 30 krad from a 60 Co source and thereafter, the seeds were treated with 0.3% of freshly prepared sodium azide solution for three hours, respectively. The results clearly show the formation of various types of secondary chromosomal association among bivalents. Secondary association is defined as the tendency of bivalents to lie in pairs having diffused connections. The phenomenon of secondary pairing manifested from metaphase I stage and persisted upto metaphase II stage. The bivalents lie side by side and end to end to form secondary pairing. A secondary association between bivalents is considered to be of great significance as it is being taken as an indicator of ploidy in plants. Apart from secondary chromosomal association, other meiotic abnormalities were also noticed. These include precocious movement of chromosomes at metaphase I/II (2.83%), stickiness at metaphase I/II (3.45%), stickiness at anaphase I/II (2.20%), bridge (1.25%), unorientation (0.94%), micronuclei (1.88%) etc. This phenomenon, along with other meiotic aberrations affects the pollen fertility considerably.

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“…Since then, it is often encountered in meiotic processes of different plant species in tracing basic chromosome numbers and the polyploid nature of the species (Kempanna and Riley 1964, Gupta and Roy 1973, Agarwal 1983, Sengupta and Datta 2003, Mukherjee and Datta 2005, Iqbal and Datta 2007, Das et al 2009, Bhattacharya and Datta 2010, Mandal and Datta 2011, Halder et al 2012, Kumar and Singhal 2013. The present investigation describes meiotic configurations documenting secondary chromosome association in Indigofera tinctoria L. (Family: Fabaceae), an annual, biennial, or perennial shrub, based on the climate under which it is grown (Gaboriaud- Kolar et al 2014).…”

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confidence: 88%

Meiotic Configurations and Secondary Chromosome Associations in <i>Indigofera tinctoria</i> L. (Family: Fabaceae)

Ghosh

Datta

Mandal³

et al. 2016

CYTOLOGIA

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Summary Meiotic analysis performed in Indigofera tinctoria L. (Family: Fabaceae) reveals n=8 chromosomes with an average chromosomal association of 7.79II+0.44I at metaphase I (MI). Predominance of 8II formation (87.86%) has been noted. The bivalents form rods (mean per cell -rod: 5.88 0.21; ring: 1.87 0.19; association: 7.75II+0.50I) mostly at diplotene with a mean chiasma of 9.62 0.21 per cell. Anaphase I cells (94.12%) are mostly cytologically balanced (8/8) with an average pollen fertility of 93.60%. A persistent feature (89.39%) in MI cells has been the presence of secondary association of chromosomes and the chromosomes assort themselves into variable groups of two (6.04%), three (7.04%), four (25.50%), five (56.71%), six (4.02%) and seven (0.67%). Out of 25 different associations studied among the group classes, 3II(1)+2II(1)+1II(3) under the five group class (25.83%) was the most frequent. Statistical analysis of cytological data reveals that the probable basic chromosome number in the species is x=5, suggesting polyploid lineage.

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Secondary Chromosome Associations in Uraria picta (Jacq.) DC (Family: Leguminosae)

Cited by 13 publications

References 20 publications

A Report on Genetic Male Sterility in Uraria picta (Jacq.) DC.

A Report on Genetic Male Sterility in Uraria picta (Jacq.) DC.

Secondary Chromosomal Association in Kidney Bean ( Phaseolus Vulgaris L. )

Meiotic Configurations and Secondary Chromosome Associations in <i>Indigofera tinctoria</i> L. (Family: Fabaceae)

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