20153103201591119132FFED1270-FFBF-FFA4-FFF1-FFA52E15E312E63C4064-560F-41FB-941C-B8220BA5C3CE5755252411201421012015Anju Shamurailatpam, Latha Madhavan, Shrirang Ramachandra Yadav, Kangila Venkatraman Bhat, Satyawada Rama RaoThis is an open access article distributed under the terms of the Creative Commons Attribution License (CC BY 4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.http://zoobank.org/E63C4064-560F-41FB-941C-B8220BA5C3CE
Chromosome studies along with heterochromatin distribution pattern analysis have been carried out in two domesticated species of Vigna Savi, 1824 which grow in contrasting geo-climatic conditions of India: Vignaumbellata Thunberg, 1969, a legume well acclimatized to subtropical hilly regions of North-east India and V.aconitifolia Jacquin, 1969, a species of arid and semi-arid regions in desert plains of Western India. Karyo-morphological studies in both species reveal 2n = 22 chromosomes without any evidence of numerical variation and the overall karyotype symmetry in chromosome morphology suggest that the diversification at intraspecific level in genus Vigna has occurred through structural alteration of chromosomes, rather than numerical changes. Heterochromatin distribution as revealed by fluorochrome binding pattern using CMA3 and DAPI, confirms the occurrence of relatively more GC content in V.aconitifolia as compared to V.umbellata. However, AT content was found to be comparatively higher in V.umbellata which perhaps play a role in species interrelationships.
Shamurailatpam A, Madhavan L, Yadav SR, Bhat KV, Rao SR (2015) Heterochromatin distribution and comparative karyo-morphological studies in Vigna umbellata Thunberg, 1969 and V. aconitifolia Jacquin, 1969 (Fabaceae) accessions. Comparative Cytogenetics 9(1): 119–132. doi: 10.3897/CompCytogen.v9i1.9012
Introduction
The pantropical genus Vigna Savi, 1824 (Fabaceae) includes 104 described species (Lewis et al. 2005). Among its subgenera, only Ceratotropis Marechal, 1978 is known for its rich species diversity in Asia (Verdcourt 1970, Marechal et al. 1978, Tateishi 1996). Tomooka et al. (2002) recognized 21 species in the subgenus Ceratotropis, out of which six species are domesticated: azuki bean (V.angularis Willdenow, 1969), mung bean (V.radiata Linnaeus, 1954), black gram (V.mungo Linnaeus, 1956), rice bean (V.umbellata Thunberg, 1969), moth bean (V.aconitifolia Jacquin, 1969) and creole bean (V.reflexo-pilosavar.glabra Marechal, 1911). The genetic resources and diversity in cultivated and wild forms of subgenus Ceratotropis occurring in Indian subcontinent are extremely rich and interesting (Bisht et al. 2005). The domesticated V.aconitifolia is confined only to the tropical region of India, while V.umbellata is widely domesticated across the South-east Asia. The origin of V.umbellata is considered to be Indo-China region and also to a certain extent from South-east Asia (Marechal et al. 1978, Baudoin and Marechal 1988).
The structure and morphology of the chromosomes are of vital importance when studying the origin, evolution and classification of taxa (Yang et al. 2005) as well as distance or relatedness among diverse genomes (Stace 2000, Kumar and Rao 2002). Quite a few number of reports dealing with such studies are available for Vigna species (Rao and Chandel 1991, Rao and Raina 2004, Shamurailatpam et al. 2012).
Chromosome location and characterization of C-heterochromatin by fluorescence staining procedures which preferentially stain GC-rich DNA and DAPI, which localised AT-rich regions has been successfully applied in a large number of Fabaceae taxa including Cicerarietinum Linnaeus, 1753 (Galasso et al. 1996a); Phaseoluscalcaratus Roxburgh, 1832 (Zheng et al. 1991); Sesbaniatetraptera Hochstetter, 1871 (Forni-Martins et al. 1994, Forni-Martins and Guerra 1999); Viciafaba Linnaeus, 1753 (Greilhuber 1975); Vignaambacensis Welwitsch, 1978 (Galasso et al. 1996b).
A certain degree of chromosomal variation at inter-specific level of the genus Vigna has been documented using cytogenetic approaches by earlier workers (Rao and Chandel 1991, Shamurailatpam et al. 2012). Hence, it will be quite significant to see the extent of variation among the domesticated species of Vigna (Ceratotropis). V.umbellata is a species domesticated extensively in the subtropical hilly and moist regions of North-east India. On the other hand, V.aconitifolia has been adapted to the arid and semi-arid region of tropical Western plain of India. Analysis of karyo-morphological details in V.umbellata and V.aconitifolia, adapted to extremely contrasting environmental conditions, may ultimately help us to define their chromosome variation. Meaningful propagation programs can be developed from such information.
Materials and methods
Karyo-morphological studies were undertaken in ten accessions each of V.umbellata and V.aconitifolia. The germplasm has been obtained from Indian Council of Agricultural Research (ICAR), Baranapi, Meghalaya and also from National Bureau of Plant Genetic Resources (NBPGR), New Delhi. Actively growing root tips of about 1–2 cm long were excised from germinating seeds on moist filter paper in Petri dishes at 25 ± 2 °C, pre-treated with 0.025% colchicine (Himedia) for 3 h at room temperature (20 ± 2 °C). The root tips after pre-treatment were fixed in freshly prepared ethanol-acetic acid (v/v, 3:1) and subsequently stored at 4 °C until required. For slide preparation, the root tips were washed twice in distilled water, hydrolyzed in 1N HCl at 60 °C for 8 min and stained in Feulgen stain (leuco-basic fuchsin) for 45 min. The stained root tips were thoroughly washed and subsequently squashed in 1% acetocarmine. The micro-photographs of the metaphase plates were taken from both temporary and permanent preparations. At least 10–15 clear preparations of chromosome complements of each species were analyzed. Photo-idiograms were prepared from photomicrographs by cutting out individual chromosome and arranging them in descending order of their length and matching on the basis of morphology, the chromosomes were resolved into 11pairs. The standard method of chromosome classification given by Battaglia (1955) classification of metacentric / median (V), submetacentric/ submedian (L), subtelocentric (J) and telocentric (I) based on the arm ratio of 1:1, >1:1<1.3, >1:3<1:0 and 1:0 respectively was employed for comparison. The degree of asymmetry was estimated by means of the parameters proposed by Peruzzi and Eroğlu (2013): Coefficient of Variation of Chromosome Length (CVCL) and Mean Centromeric Asymmetry (MCA).
For heterochromatin characterization, root-tips were digested in 2% cellulase and 20% pectinase solution for 180 min at 37°C. Meristems were washed in distilled water, squashed in a drop of 45% acetic acid, and frozen in liquid nitrogen. The slides were stained with DAPI (2 µg/ml): glycerol (1:1, v/v) solution to allow selection of the best plates. Subsequently, they were destained in ethanol: glacial acetic acid (3:1, v/v) for 30 min and transferred to absolute ethanol for 1 h, both at room temperature. Slides were air-dried and aged for 3 days at room temperature. The slides were stained with CMA3 (0.5 mg/ml, 1 h) and DAPI (2 µg/ml, 30 min), mounted in McIlvaine’s buffer (pH 7.0): glycerol (1:1, v/v), and stored for 3 days (Schweizer and Ambros 1994). Slides were analyzed under Leica DM 4000 B microscope and photographs were carried out with different filter combinations using Leica CCD camera.
Results
The somatic chromosome number of all the accessions had consistently 2n = 2x = 22 (Fig. 1). The chromosome complements were resolved into 11 pairs which formed a graded series from longest to shortest within the idiograms. A noticeable difference in length between the longest and the shortest chromosomes within the complement was recorded (Table 1). The longest chromosome of the haploid complement was almost 2.5 times longer than the shortest one in V.aconitifolia accessions, while it was 2 times longer than the shortest one in V.umbellata accessions. Further investigated accessions belonging to V.umbellata and V.aconitifolia had metacentric, submetacentric and subtelocentric chromosomes in their respective chromosome complements. Submetacentric chromosomes outnumbered the metacentric ones in V.aconitifolia accessions while metacentric chromosomes outnumbered the submetacentric chromosomes in the case of V.umbellata accessions.
Various accessions of these species have shown distinctive variation in the karyotype with respect to number of metacentric and submetacentric chromosomes (Fig. 2). Subtelocentric chromosomes were found in V.aconitifolia but not in V.umbellata accessions. Heteromorphic chromosome and nucleolar chromosomes are recorded in the accessions of both V.umbellata and V.aconitifolia.
440583D9-C71F-59A5-95C1-59ABFBCD2976
Mitotic complements of 10 accessions of V.umbellata. a–j:a BKSB 205 b TRB 160 c RBS 35 d IC 551699 e BKSB 192 f RBS 53 g IC 55440 h IC 176563 i EC 97882 j BKSB 194 k–t:k IC 36157 l VDV 6175 m IC 472147 n RM 040 o IC 39809 p IC 285159 q IC 36592 r IC 472173 s IC 39713 t IC 36562. Bar = 5 μm.
Photo-idiograms of a–j 10 accessions of V.umbellataa BKSB 205 b TRB 160 c RBS 35 d IC 551699 e BKSB 192, f RBS 53 g IC 55440 h IC 176563 i EC 97882 j BKSB 194 k–t 10 accessions of V.aconitifoliak IC 36157 l VDV 6175 m IC 472147 n RM 040 o IC 39809 p IC 285159 q IC 36592 r IC 472173 s IC 39713 t IC 36562. Heteromorphic groups marked above the short arm and nucleolar groups are marked below the long arm.
https://binary.pensoft.net/fig/41095
Karyomorphology and arm ratio in studied taxa of Vigna.
Sl. no.
Species
Accessions no.
2n
Chromosome arm length (L/S ratio)
Ratio of longest and shortest chromosome
Karyotype formula
I
II
III
IV
V
VI
VII
VIII
IX
X
XI
1
V.umbellata
BKSB 205
22
1.12 1.14
1.8
1.5
1.5
1.25
1
1.3
1.3
1.3
1.3
1.3
2.4
2V + 20L
2
V.umbellata
TRB 160
22
1.2 1.5
1.1 1.25
1.75
1.37
1
1
1
1.3
1.3
1
1
2.2
12V + 10L
3
V.umbellata
RBS 35
22
1.2
1.6
1
1
1
1
1
1.15
1.3
1.3
1
2.8
12V + 10L
4
V.umbellata
IC 551699
22
1 1
1.3
1.7
1.15
1.57
1.75
1.1
1
1
1
1
4.0
12V + 10L
5
V.umbellata
BKSB 192
22
1
1
1
1.25
1.12
1
1
1
1.3
1
1
2.0
16V + 6L
6
V.umbellata
RBS 53
22
1.2
1.1
1.25
1.25
1
1
1
1
1.3
1.3
1
2.3
12V + 10L
7
V.umbellata
IC 55440
22
1.57 1.42
1.2
1.35
1.12
1.12
1.12
1
1
1
1.15
1.3
3.0
6V + 16L
8
V.umbellata
IC 176563
22
1.14 1.28
1.6
1.1
1.25
1.6
1.3
1
1
1.6
1.3
1
2.6
8V + 14L
9
V.umbellata
EC 97882
22
1.7
1.47
1.2
1.37
1.2
1
1
1.65
1.3
1.3
1
2.3
8V + 14L
10
V.umbellata
BKSB 194
22
1
1
1
1.3
1.3
1.3
1.3
1.3
1
1
1
3.0
12V + 10L
11
V.aconitifolia
IC 36157
22
1.33
1.9
2
1.5
1.1 1.5
1.5
1.5
1.5
1
1
1
1.75
6V + 16L
12
V.aconitifolia
VDV 6175
22
1.5 1.66
2.5
1.33
2
1.5
1.5
1.5
1.5
1.25
1
1
2.5
4V + 16L + 2J
13
V.aconitifolia
IC 472147
22
2
2.5
2.5 2
1
1
1
1.5
1.75
1.5
1
1
2.25
10V + 12L
14
V.aconitifolia
RM 040
22
1.5
1.66
3 2
1.5
2
2
1.75
1.25
1.5
1.5
1
2.5
2V + 18L + 2J
15
V.aconitifolia
IC 39809
22
1.57
2
1.66
1.33
2
1.16
1
1.25
1.25
1.5
1
3.0
4V + 18L
16
V.aconitifolia
IC 285159
22
1.33
2
1.5
1.5
1
1.5
1.25
1
1
1
1
3.5
10V + 12L
17
V.aconitifolia
IC 36592
22
1.75 1.6
1.62
1
1
1.66
1
1
1.33
1.33
1
2
2.16
10V + 12L
18
V.aconitifolia
IC 472173
22
2.4 1.8
1.83 2
1.86
1.25
1.12
1
1
1
1
1
1
4.25
14V + 8L
19
V.aconitifolia
IC 39713
22
2
2.5
1
2
1
1.5
1.5
1.5
1.5
1.5
1
2.25
6V + 16L
20
V.aconitifolia
IC 36562
22
1.58
3
1.49
1.33
1
1
1
1.5
1.5
1.5
1
2.5
8V + 14L
Karyotype formulae and characteristics in the studied taxa of Vigna. SC the shortest chromosome length; LC the longest chromosome length; CL mean length of chromosome; CI mean centromeric index; SD standard deviation; CVCL component expressing the relative variation in chromosome length; MCA mean centromeric asymmetry.
Sl. no.
Accessions no.
2n
Range SC-LC (μm)
Ratio LC/SC
CL (μm) Mean (± SD)
CI Mean (± SD)
CVCL
MCA
1
BKSB 205
22
17-7
2.4
9.13 (± 2.76)
42.87 (± 3.47)
30.25
14.30
2
TRB 160
22
11-5
2.2
7.95(± 1.55)
45.22 (± 4.65)
19.59
9.09
3
RBS 35
22
17-6
2.8
9.18(± 2.95)
46.93 (± 3.85)
32.19
6.18
4
IC 551699
22
24-6
4
11.5(± 4.3)
45.59 (± 5.03)
37.4
9.06
5
BKSB 192
22
12-6
2
8.45(± 1.78)
48.57 (± 2.49)
21.16
2.81
6
RBS 53
22
14-6
2.3
8.40(± 1.74)
47.09 (± 2.91)
20.72
5.78
7
IC 55440
22
18-6
3
9.31(± 2.99)
46.55 (± 2.92)
32.13
6.49
8
IC 176563
22
16-6
2.6
9.18(± 2.66)
44.29 (± 4.65)
29.02
11.37
9
EC 97882
22
14-6
2.3
9.18(± 2.27)
44.94 (± 3.94)
24.82
55.07
10
BKSB 194
22
18-4
3
7.09(± 1.62)
46.75 (± 3.55)
22.86
6.49
11
IC 36157
22
7-4
1.75
5.22 (± 1.04)
42.44 (± 6.07)
19.92
15.32
12
VDV 6175
22
10-4
2.5
5.68 (± 1.54)
40.76 (± 7.06)
27.25
18.55
13
IC 472147
22
9-4
2.25
5.81 (± 1.36)
41.61 (± 8.54)
23.54
16.51
14
RM 040
22
10-4
2.5
6.09 (± 1.67)
38.78 (± 6.45)
27.52
22.88
15
IC 39809
22
12-4
3
6.72 (± 2.02)
42.04 (± 6.17)
30.12
16.22
16
IC 285159
22
7-2
3.5
4.68 (± 1.25)
43.63 (± 5.72)
26.85
10.8
17
IC 36592
22
11-6
2.16
7.95 (± 1.60)
43.89 (± 6.32)
20.22
12.21
18
IC 472173
22
17-4
4.25
8.59 (± 3.66)
44.99 (± 7.29)
42.64
10.14
19
IC 39713
22
9-4
2.25
5.72 (± 1.28)
40.47 (± 6.85)
22.44
19.05
20
IC 36562
22
10-4
2.5
6.22 (± 1.47)
43.34 (± 8.09)
23.68
15.13
Telocentric chromosomes were absent in both the taxa studied. Heteromorphic chromosomes were observed in some of the V.umbellata accessions: BKSB 205 (1st pair, Fig. 2a), TRB 160 (1st and 2nd pair, Fig. 2b), IC 551699 (1st pair, Fig. 2d), IC55440 (1st pair, Fig. 2g) and IC 176563 (1st pair, Fig. 2h). In V.aconitifolia heteromorphic chromosomes were found in IC 36157 (5th pair, Fig. 2k), VDV 6175 (1st pair, Fig. 2l), IC 472147 (3rd pair, Fig. 2m), RM040 (3rd pair, Fig. 2n), IC 36592 (1st pair, Fig. 2q) and IC 472173 (1st and 2nd pair, Fig. 2r) accessions. Nucleolar Organizing Regions (NORs), as a secondary constriction/satellites, were observed in V.umbellata accessions RBS 35 (1st pair, Fig. 2c), IC 551699 (2nd pair, Fig. 2d), and EC 97882 (3rd and 4th pair, Fig. 2i). Vignaumbellata was characterized by the presence of both metacentric and submetacentric chromosomes and two V.aconitifolia accessions (VDV 6175 and RM 040) were characterized by the presence of distinct subtelocentric chromosome, though their position differed in karyotype. The remaining accessions were devoid of any subtelocentric chromosome.
According to the scatter plot obtained by CVCL vs. MCA, BKSB 192 (V.umbellata) and EC 97882 (V.umbellata) showed the lowest (2.81) and highest (55.07) MCA respectively (Fig. 4). Furthermore IC 285159 (V.aconitifolia) and RM 040 (V.aconitifolia) showed lowest (10.8) and highest (22.88) MCA values. In V.umbellata TRB 160 and IC 551699 exhibited lowest (19.59) and highest (37.4) CVCL values. Among V.aconitifolia accessions IC 36157 and IC 472173 had shown lowest (19.92) and highest (42.64) CVCL values.
A comparative account of heterochromatin distribution pattern within the chromosome complements in V.umbellata and V.aconitifolia has been summarized in Table 3 and the data have been illustrated in Fig. 3. The CMA3+ and DAPI+ binding sites were found either in terminal or in interstitial regions, in both the taxa studied. V.umbellata had more of DAPI+ sites 3.1(± 1.9) in the interstitial region of the chromosomes and the terminal binding sites were 1.8(± 0.6). The number of chromosomes showing different CMA+ and DAPI+ sites also ranged from 2–7 in this species. On the other hand, in V.aconitifolia the heterochromatin block comprised more of CMA+ binding sites 2.9(± 1.3), which were found in the terminal region of the chromosomes while 2(± 1.2) binding sites were interstitial in position. The number of chromosomes showing CMA+ sites ranged from 3–7, while those showing the DAPI+ sites ranged from 3–8.
4BAEC639-C46F-57B0-8952-6B63CF7A6F05
Differentially stained mitotic chromosomes complements a–bV.umbellatac–dV.aconitifolia. Arrows indicate CMA+ and DAPI+ sites. Scale bar = 5 µm in all the figures.
Scatter plot based on the karyotype parameters MCA (x axis) vs. CVCL (y axis) a BKSB 192 b RBS 53 c RBS 35 d BKSB 194 e IC 55440 f IC 551699 g TRB 160 h IC 472173 i IC 285159 j IC 176563 k IC 36592 l BKSB 205 m IC 36562 n IC 36157 o IC 39809 p IC 472147 q VDV 6175 r IC 39713 s RM 040 t EC 97882.
https://binary.pensoft.net/fig/41097
Distribution of CMA+ and DAPI+ sites in the chromosomes of Vigna species.
Species
Mean± SD of CMA+ sites in chromosomes
Mean± SD of DAPI+ sites in chromosomes
Range of CMA+ sites Terminal
Range of DAPI+ sites Interstitial
Terminal
Interstitial
Terminal
Interstitial
V.umbellata
1.7 ± 0.8
2.1 ± 0.8
1.8 ± 0.6
3.1 ± 1.9
1.7 ± 0.8
2.1 ± 0.8
V.aconitifolia
2.9 ± 1.3
2 ± 1.2
2.7 ± 0.7
2.3 ± 0.8
2.9 ± 1.3
2 ± 1.2
Discussion
The present data, combined with the chromosome counts available from the literature confirm the somatic chromosome number of 2n = 22 for both species, V.umbellata and V.aconitifolia. Such observation received support from reports of Singh and Roy (1970), Rao and Chandel (1991), Rao and Raina (2004), Shamurailatpam et al. (2012). The presence of subtelocentric chromosomes in V.aconitifolia accessions is in agreement with the earlier report of Sinha and Roy (1979).
All the accessions of V.umbellata and V.aconitifolia have shown no deviation in somatic chromosome numbers and overall karyotype appearance. However, V.umbellata had a higher degree of karyotype asymmetry as compared to V.aconitifolia, suggesting structural rearrangements in karyotypes. Hence, the observed karyotype variation is likely to have originated by structural changes in chromosomes vs. duplication, deletions, interchanges and inversions (Stebbins 1971, Rao and Chandel 1991). Thus, structural alteration of the chromosomes involving centric fusion and centromere repositioning might have influenced the speciation in genus Vigna.
Due to the very small size of chromosomes accompanied by technical difficulties, the nucleolus organisers among the chromosome complements could not be clearly resolved. Other cytogenetic techniques such as silver staining and fluorescence in situ hybridization (FISH) can be useful in detecting NOR-loci on chromosomes.
The DAPI+ binding sites in chromosomes, which are indicative of AT-rich region, were recorded in the interstitial regions of chromosomes in V.umbellata. However CMA+ sites, found mostly in V.aconitifolia chromosomes, suggest that the heterochromatin blocks were rich in GC base composition at terminal regions of chromosomes. The higher distribution of AT- and GC- repetitive sequence in heterochromatin blocks is probably reflecting the processes of divergent evolution of repetitive sequences, in heterochromatin regions of Vigna species (Shamurailatpam et al. 2014).
In the course of evolution, most of the heterochromatin regions tend to increase (Ikeda 1988), this phenomenon is also observed in Vigna (Shamurailatpam et al. 2015). Certain genera such as Vicia, Phaseolus, Sesbania, Cicer and Vigna (Greilhuber 1975, Zheng et al. 1991, Forni-Martins et al. 1994, Galasso et al. 1996a, b, Forni-Martins and Guerra 1999) showed a heterochromatin-rich chromosome configuration, that might have been involved in diversification of this genus. Vignaumbellata, which is domesticated extensively in the sub tropical hilly and moist regions of North-east India, had its heterochromatin blocks rich in AT content with fewer GC base pairs. On the contrary, more GC content in heterochromatin blocks was observed in V.aconitifolia, which is acclimatized to the arid and semi-arid region of tropical Western plains of India, helping the species to overcome adverse climatic conditions of Indian desert. Our observations in this regard constitute a first attempt to probe the role of heterochromatin distribution pattern, if any, in species differentiation of plant groups.
Acknowledgements
The present work is supported by a grant from the World Bank funded by Indian Council of Agriculture Research (ICAR) project received through National Agriculture Innovation Program (NAIP). We thank the Head, Department of Biotechnology and Bioinformatics, North Eastern Hill University (NEHU), Shillong for providing facilities. Sincere thanks are also due to members of the Plant Biotechnology Laboratory for their help. The generous support for germplasm of V.umbellata extended by Dr. A. Pattanayak, Division of Biotechnology, ICAR complex for North Eastern Hill Region, Barapani, Meghalaya is duly acknowledged.
ReferencesBattagliaE (1955) Chromosome morphology and terminology.6: 179–187. doi: 10.1080/00087114.1955.10797556BishtISBhatKVLathaMAbrahamZDikshitNShashiBLoknathanTR (2005) Distribution, diversity and species relationships of wild Vigna species in mungo-radiata complex.18(2): 169–179.BoudoinJPMarechalR (1988) Taxonomy and evolution of genus Vigna. In: . Asian Vegetable Research and Development Centre, Taiwan, 2–12.Forni-MartinsERFranchi-TanibataNCardelli de LucenaMA (1994) Karyotype of species of Sesbania Scop. species (Fabaceae).59: 479–482.Forni-MartinsERGuerraM (1999) Longitudinal differentiation in chromosome of some Sesbania Scop. species (Fabaceae).52: 97–103. doi: 10.1080/00087114.1998.10589160GalassoIFredianiMCremoniniRPignoneD (1996a) Chromatin characterization by banding techniques, in situ hybridization, and nuclear DNA content in Cicer L. (Leguminosae).39: 258–265. doi: 10.1139/g96-035GalassoISaponettiLSPignoneD (1996b) Cytotaxonomic studies in Vigna. III. Chromosomal distribution and reacting properties of the heterochromatin in five wild species of the section Vigna.49: 311–319. doi: 10.1080/00087114.1996.10797375GreilhuberJ (1975) Heterogeneity of heterochromatin in plants: comparision of Hy- and C- bands in Viciafaba.124: 139–156. doi: 10.1007/BF00985499IkedaH (1988) Karyomorphological studies on the genus Crepis with special reference to C-banding pattern.22: 65–117.KumarARaoSR (2002) Cytological investigations in some important tree species of Rajasthan I. Karyomorphological studies in some species of Anogeissus (DC.) Guill., Perr. & A. Rich.51: 100–104.LewisGPSchrineBMackinderBLockJM (2005) . Royal Botanic Gardens, Kew.MarechalRMascherpaJMStainerF (1978) Etude taxonomique d’un groupe complexe d’espe`ces des genres Phaseolus et Vigna (Papilionaceae) sur la base de donne´es morphologiques et polliniques, traite´es par l’analyse informatique.28: 1–273.PeruzziLEroğluHE (2013) Karyotype asymmetry: again, how to measure and what to measure.7(1): 1–9. doi: 10.3897/compcytogen.v7i1.4431RaoSRChandelKPS (1991) Karyomorphological studies in the cultivated and wild Vigna species in Indian gene centre.56: 47–57. doi: 10.1508/cytologia.56.47RaoSRRainaSN (2004) Studies on male meiosis in cultivated and wild Vigna species: In: SrivastavaPSNarulaASrivastavaS (Eds) . Springer, Netherlands, 331–345.SchweizerDAmbrosPF (1994) Chromosome banding. In: GosdenJR (Ed.) , vol 29. Humana press, Totowa, 97–112.ShamurailatpamAMadhavanLYadavSRBhatKVRaoSR (2012) Chromosome diversity analysis in various species of Vigna Savi from India.55: 107–114. doi: 10.1007/s13237-012-0063-3ShamurailatpamAMadhavanLYadavSRBhatKVRaoSR (2015) Heterochromatin characterization through differential fluorophore binding pattern in some species of Vigna Savi.252(2): 629–635. doi 10.1007/s00709-014-0708-ySinghARoyRP (1970) Karyological studies in Trigonella, Indigofera and Phaseolus.13: 41–54.SinhaSSNRoyH (1979) Cytological studies in the genus Phaseolus: Mitosis analysis of fourteen species.44: 191–199. doi: 10.1508/cytologia.44.191StaceCA (2000) Cytology and cytogenetics as a fundamental taxonomic resource for the 20th and 21st centuries.49: 451–477. doi: 10.2307/1224344StebbinsGL (1971) Edward Arnold Ltd., London, 216 pp.TateishiY (1996) In: SrinivesPKitbamroongCMiyazakiS (Eds) . Japan International Research Centre for Agricultural Sciences, 9–24.TomookaNVaughanDAMossHMaxtedN (2002) . Kluwer, Dorchet.VerdcourtB (1970) Studies in the leguminosae-papilionoideae for the flora of tropical east Africa, IV.24: 507–569. doi: 10.2307/4102859YangXSZhuWSHaoXJ (2005) The study of chemical component of Tu dang shen (C.javanica).36: 1144–11466.ZhengJYNakataMUchiyamaHMorikawaHTanakaR (1991) Giemsa C-banding patterns in several species of Phaseolus L. and Vigna Savi, Fabaceae.56: 459–466. doi: 10.1508/cytologia.56.459