Chromosome studies and soluble protein profiles, fractionated by reducing and non-reducing SDS-PAGE, were carried out in dioecious Trichosanthes bracteata. Somatic chromosome no. 2n = 22 was recorded in both sexes. The karyotype of male and female plant shows high homogeneity and the absence of any heteromorphic pair of chromosomes negates the possibility of XY mechanism. Soluble protein profiles from the tuberous roots of the male and female plants, frac tionated by reducing SDS-PAGE, did not show any qualitative distinction. Whereas the protein profile in non-reducing SDS-PAGE reveals a clear distinction when compared on a single gel. The difference is marked by the presence of a disulphide linked tertiary or folded protein at 19 k D region detected in male sex. However, at the level of primary structure the qualitative expression is similar indicating a common ancestry.
Most of the flowering plants are bisexual having flowers with both male and female reproductive organs and only less then 4% plant species are dioecious in nature i.e., strictly maintain their sexual phenotypes [
In Trichosanthes bracteata, male and female plants strictly maintain their respective sexual phenotypes and every year sprouting occurs, from their respective vegetative reproductive structure i.e., the tuberous root, without failing to reproduce their own kind. Limited cytogenetic studies had so far been made in this taxon and there is a record of polyploid series from diploid to hexaploid [11-15]. However, comparative analysis of the detailed karyotype of the sex forms of T. bracteata was not carried out till date probably due to its ecological distribution and extreme difficulty in obtaining suitable chromosome spreads needed for thorough analysis.
In the absence of information on chromosomal basis of sex determination, electrophoretic study of soluble protein profile of the vegetative propagules could be useful in understanding the genic expression of sexual phenotypes. The present investigation has, therefore, been aimed at karyotype and SDS-PAGE analysis with or without 2-mercaptoethanol to resolve the differences, if any, between the sexes of T. bracteata.
The tuberous roots of the sex forms of T. bracteata growing in wild condition collected from west Tripura were grown in the experimental garden of the Department of Botany, Tripura University.
Young leaf tips of the sex forms of Trichosanthes bracteata were pre-treated in saturated solution of para-dichlorobenzene at 10˚C - 15˚C for 4 hours followed by overnight fixation in 1:3 acetic-ethanol mixture. The leaf tips were then stained overnight in 2% aceto-orcein after hydrolysis in 5(N) HCl at cold for 20 minutes and finally squashed in 45% acetic acid. While preparing the karyotype, five well spread metaphase plates were compared and in cases where the length and arm ratio varied the mean was taken to calculate the F%.
Two grams of fresh tuberous tissue were homogenized in 4 ml of extraction buffer containing 0.25 M sucrose and 1mM EDTA in 0.1 M Tris-HCl buffer (pH 6.8). The homogenates were then centrifuged at 12,000 rpm for 45 minutes at cold. The supernatants were collected and immediately used for electrophoresis. The protein concentration was estimated by the method of Lowry et al. [
The soluble protein obtained in extraction buffer was boiled with equal amount of 1 X strength electrophoresis sample buffer (12.5% glycerol, 1.25% SDS, 0.005% bromophenol blue, 62.5% Tris-HCl, pH 6.8) in presence and absence of 178 mM 2-mercaptoethanol for 5 minutes & allowed to cool at room temperature before proceeding to the next step. All the reagents used were of electrophoresis grade (SRL & MERCK). Electrophoresis in 12% polyacrylamide slab gel containing 0.1% SDS [
The position of the bands was expressed as relative mobility (Rm) and was determined by measuring the ratio of the distances traveled by a particular band and the indicator Bromophenol Blue. The different Rm values of the protein bands were numbered serially. Using five cycle semi log graph paper their molecular weights were determined from the standard curve.
The sexual phenotypes of T. bracteata differ and it has been observed that the male flowers of T. bracteata are in racemes and having bracts 3 - 4 cm long whereas female flowers are solitary and without any bract (Figures 1(a) and (b)).
The somatic chromosome number 2n = 22 (Figures 2(a) and (b)) was found in both sexes of T. bracteata having two pairs of chromosomes bearing secondary constrictions. In general, chromosomes are short to medium in size and could be classified [
Type A: Short chromosomes (1.68 µm) bear 2 constrictions, primary and secondary, one is nearly sub-median and the other is sub-terminal in position;
Type B: Chromosomes are short (2.13 µm) having 2 constrictions, primary and secondary, both are nearly sub-median in position;
Type C: Short chromosomes (1.06 µm - 1.60 µm), the constriction of chromosomes are median and or nearly median in position;
Type D: The chromosomes (2.96 µm) are medium in size and the constrictions are nearly sub-terminal in position.
The biggest chromosome of the somatic chromosome complements is a medium sized acrocentric chromosome with sub-terminal constriction and does not bear any secondary constriction. The TF% of male and female plants is 36.04 and 35.93 respectively. According to Stebbin’s categorization, the karyotype of both male and female plants falls under category 2B.
Soluble protein profile of tuberous roots of male and female plants showed differential expression in reducing SDS-PAGE and non-reducing SDS-PAGE (Figures 3(a) and (b)) profiles. The reducing SDS-PAGE of both the sex forms showed 25 common bands in all the experimental set studied. In the non-reducing SDSPAGE protein profile the female sex showed 28 bands
and the male plant showed an additional band when lesser amount of protein (15 µg/lane) protein was loaded on to gel (Figures 3(e) and (f)).
Somatic chromosome count 2n = 22 are found constant in both sexes of Trichosanthes bracteata which corroborates the findings of Verghese [
The soluble protein profiles of the sex forms of T. bracteata fractionated by reducing SDS-PAGE did not show any marked distinction and only a variation in the intensity of staining pattern was observed in all experimental set (Figures 3(a) and (b)). A different result in protein profile was however obtained when subjected to non-reducing SDS-PAGE analysis. A total of 28 bands were found to be common in male and female plants in non-reducing profile when ~30 µg proteins were loaded (Figures 3(c) and (d)). On the contrary when ~15 µg proteins were loaded onto each lane a single band difference was observed along with a significant variation in the intensity of the band patterns between the sexes. The electrophoretic distinction between two sexes is, therefore, marked by the presence of disulphide linked tertiary or folded protein at the 19 K D region in male sex. The variability thus obtained suggests that such tertiary or folded proteins are formed in the vegetative propagules of male sex which is not found in female plant. But eventually in the primary structure the qualitative expression is similar (Figures 3(e) and (f)) in both sexes indicating a common ancestry.
The karyotype of male and female plants of dioecious T. bracteata, analysed separately for the first time, is identical and no heteromorphicity is recorded in relation to sex. Obviously, the sex expression is under genic control. The present study also suggests that non-reducing SDSPAGE profile could be used to resolve the distinction between the sexes of dioecious Trichosanthes bracteata.
*Mean of 5 plates.
Financial assistance by UGC to the first author for NonNET Ph.D. scholarship is duly acknowledged.