RAPD analysis of sporting and chimerism in chrysanthemum

Summary The potential of colchicine and the microtubule depolymerizing herbicides trifluralin, oryzalin, and amiprophosmethyl (APM) for in vitro chromosome doubling during B. napus microspore culture was studied. Colchicine was administered during the first 6, 12 or 24 h of culture with 8 different concentrations up to 3 mM, and herbicides at 6 different concentrations up to 30 M for 12 h.Treatments with moderate concentrations of colchicine (3–100 M) produced a small increase in embryo production, while concentrations above 300 M were toxic. Colchicine treatment for 12 h resulted in higher embryo production than treatment for 6 and 24 h. Duration of treatment and concentration of colchicine both had a significant effect on the chromosome doubling. The highest diploidization rates (94% diploid regenerants) were seen after 24 h treatment with 1 mM colchicine.All three herbicides were similar to colchicine in terms of their effect on embryo formation and chromosome doubling comparable to the one of colchicine, but at concentrations approximately 100 times lower. APM was less toxic than trifluralin and oryzalin, but no significant difference in chromosome doubling efficiency was detected between the compounds. The 12 h treatment resulted in a maximum of approximately 65% diploid regenerants with all three herbicides, but APM may have an advantage because of its less toxic effects. Prolonged treatment with APM (20–24 h) may produce 95–100% diploid regenerants.Abbreviations APM amiprophos methyl - DMSO dimethyl sulfoxide     

Efficient in vitro Chromosome Doubling During Beta vulgaris Ovule Culture

The effect of in vitro colchicine treatment of sugar beet ovules, after 7 days culture, on embryo formation, regeneration and ploidy of regenerated plants was studied with 5 concentrations of colchicine and 5 durations of treatment arranged as a 5 × 5 factorial in incomplete blocks. The best results were obtained with the shortest duration of treatment (5 hours) and the highest concentration of colchicine (0.4 %) giving 5.0 diploid plants per 100 ovules with 62.1 % of regenerated plants being diploid. Statistical analysis revealed that treatment effects could be separated into a toxic effect reducing embryo formation and a chromosome doubling effect affecting percentages of diploid regenerated plants. Toxic effects on embryo formation could be explained by simple exponential decay models, toxicity of the drug (decay constant) increasing linearly with duration of treatment. Duration of treatment had no effect on chromosome doubling percentages. The effects of colchicine concentration on chromosome doubling were explained by an exponential saturation model with spontaneous chromosome doubling of 8.1 % and saturation at 51.4 % diploid plants at 0.2 % and higher colchicine concentrations. In addition, treatments increased percentages of 4N and 6N plants from 0 % without colchicine to 10 % on average for treated ovules. A response surface model fitted to the total yield of diploid plants per ovule indicated that shorter durations of treatment and higher colchicine concentration may improve results.     

Role of mitotic inhibitors and genotype on chromosome doubling of <Emphasis Type="Italic">Rosa</Emphasis>

Dinitroanilines represent a class of compounds that are widely used in herbicide formulations as they depolymerise plant microtubles, causing chromosome doubling. The potential of microtubule depolymerising herbicides trifluralin, oryzalin, and amiprophosmethyl (APM) for in vitro chromosome doubling of Rosa was studied. Five concentrations (0, 3, 6, 12 and 24 μM) and three exposure periods (12, 24 and 48 h) for each of the compounds were compared. Oryzalin, trifluralin and APM were not significantly different in their ability to induce chromosome doubling of R. hybrida cv Iceberg. At concentration of 6 μM and exposure period of 24 h, chromosome doubling of R. hybrida cv Iceberg was not significantly different with each of the polyplodising agents. At higher concentration (24 μM) and longer exposure period (48 h), 66.7% and 62.5% chromosome doubling was achieved with APM and trifluralin, respectively. However, the application of 6 μM oryzalin to R. persica (2n = 2x), R. hybrida cv Iceberg (2n = 3x) and R. hybrida cv Akito (2n = 4x), resulted in 60.0%, 6.3% and 0% chromosome doubling, respectively, which suggest that chromosome doubling is genotype dependent and plants with lower ploidy level have a higher propensity for chromosome doubling. Flow cytometry results at 18 and 24 weeks after herbicide treatment, indicated that the best time to test the treated plants was after 24 weeks.     

Doubling the chromosome number of bahiagrass via tissue culture

Crop improvement in bahiagrass (Paspalum notatum Flüggé) is limited by apomixis in most natural tetraploids, however, diploid sexual types occur. Production of sexual tetraploids by chromosome doubling will allow hybridization with apomictic tetraploids. Diploid bahiagrass (Paspalum notatum Flüggé) embryogenic callus tissue was exposed to three concentrations of three antimitotic chemical agents, colchicine, oryzalin and trifluralin. Callus was generated to plants and ploidy was evaluated by stomata size, mitotic chromosome counts, and flow cytometry. A total of 310 plants were verified as tetraploid of 1,432 plants that reached transplanting size. All treatments yielded 4x plants. The mean percentage success over all treatments was 22%, with means of 31% for oryzalin, 24% for colchicine and 16% for trifluralin. The high rates of success indicate that all agents can be successfully used to double chromosome numbers in bahiagrass. The percentage of 4x plants ranged from 9% (20 μM trifluralin) to 43% (20 μM oryzalin). Several treatments adversely affected regeneration. Mitotic chromosome counts are difficult and labor intensive in bahiagrass. Therefore, leaf stomata measurements were used as a preliminary screen. Data gave a bimodal distribution with overlapping tails and based on chromosome counts would have given an error rate of 12%. Flow cytometry analysis of regenerated plants resulted in mean nucleus fluorescence distributions consistent with control diploid or tetraploid values. These values agreed with chromosome counts, and this method is recommended for determining bahiagrass ploidy level. Research goals and available resources should be taken into consideration when selecting a treatment for chromosome doubling in bahiagrass.     

In vitro induction of tetraploids in ornamental <Emphasis Type="Italic">Ranunculus</Emphasis>

This study investigates the capacity of the antimitotic agents colchicine, oryzalin and trifluralin for inducing polyploidisation of Ranunculus asiaticus ‘Alfa’ in vitro shoots. Flow cytometry was used to evaluate the optimal concentration of each antimitotic agent for polyploidisation. Trifluralin at a concentration of 2 μM resulted in the highest percentage of polyploidisation (27.5%), followed by a colchicine treatment of 200 μM, which induced 23.3% of polyploids. For oryzalin the highest percentage was achieved using a concentration of 1 μM. Different exposure periods were tested and turned out to be an important factor. The maximal exposure period tested (10 weeks) resulted in a significant increase in polyploidisation by oryzalin and trifluralin. In contrast, for colchicine (100 μM) exposure times of either 16 or 24 h did not significantly influence polyploidisation. Additionally the effect of the antimitotic agents on the viability was analysed. For colchicine no significant effect on the survival rate was observed, for trifluralin only a concentration of 10 μM affected viability whereas for oryzalin, concentration as well as exposure period were significant parameters. Flow cytometric data were confirmed by counting chromosomes in root tip cells.     

Efficient production of doubled haploid wheat plants by in vitro treatment of microspores with trifluralin or APM

Isolated microspore cultures from two doubled haploid (DH) lines of wheat, Triticum aestivum L., were used to develop an in vitro chromosome-doubling protocol. During the initial 24 h or 48 h of culture the microspores were treated with either of the two antimicrotubule herbicides trifluralin or amiprophos-methyl (APM) in concentrations ranging from 0.1 μM to 10μM. Untreated control cultures yielded 209 embryos per 100000 microspores, which is the equivalent of one spike. Among the regenerated plantlets 67% were green, and 15% of the flowering plants were spontaneously chromosome doubled. Treatments with both the herbicides had a significant effect on chromosome doubling, measured as the percentage of fertile regenerants. With the best combination of treatment duration (48 h) and herbicide concentration (10/μM) the percentage of fertile plants among regenerants could be increased up to 74% with APM and up to 65% with trifluralin. The largest numbers of DH plants per spike could be obtained with herbicide concentrations at 1–3 μM. Treatments with either herbicide at these concentrations resulted in an estimated average between the two genotypes of 27 DH plants per 100 000 microspores. These results demonstrate the high potential of APM and trifluralin as chromosome-doubling agents in isolated microspore cultures. The in vitro treatment integrated into tissue culture procedures will constitute an efficient method for chromosome doubling in future wheat breeding     

Short-duration colchicine treatment for in vitro chromosome doubling during ovule culture of Beta vulgaris L.

Colchicine uptake into ovules of sugar beet after 7 days of culture and its chromosome-doubling effect on ovule-derived plants were studied with high colchicine concentrations (0.4–6.0%) and short treatment duration (0–5 h). The best result of 4.2 diploid plants per 100 ovules was produced by treatment with 0.4% colchicine for 2.5 h. Both colchicine concentration and treatment time of ovules showed toxic effects on embryo formation, but it was stabilized at a low level with short exposure. The chromosome-doubling effect, by contrast, was unchanged with the colchicine concentrations used, but highly affected by the duration of exposure studied. A maximum percentage of 60% diploid plants was obtained after 3–5 h of uptake, which corresponds to only 31–39% of the total capacity for colchicine uptake in the ovules. Further uptake of the drug produced mainly toxic effects. Flow-cytometric measurements of the ploidy level in plantlets in vitro and of the same plants before flowering in soil were similar in about 80% of cases. Thus, flow-cytometric selection of diploid plants in vitro may be an efficient tool.     

Embryo rescue and plant regeneration following interspecific crosses in the genus <Emphasis Type="Italic">Hylocereus</Emphasis> (Cactaceae)

The aim of this study was to develop an efficient methodology to rescue embryos following interspecific crosses in the genus Hylocereus. Crosses between the diploids Hylocereus polyrhizus and H. undatus in both directions were performed. Fertilized ovules carrying embryos at very early pro-embryonic stages were excised from ovaries 5 days after pollination (DAP) and placed on half-strength basal MS medium containing 680 μM glutamine, 0.55 μM α-naphthaleneacetic acid (NAA), 0.45 μM thidiazuron (TDZ) and various concentrations of sucrose. After 30 days in culture, ovules were isolated from the surrounding tissue and transferred to the same fresh medium. Significant differences were found between the main effects (cross and sucrose concentration) in ovule response, i.e., increased ovule size and callus formation. The best responses were obtained in the cross: H. polyrhizus × H. undatus; and sucrose concentration of 0.09 M. In terms of embryo conversion, polyembryony and number of regenerated plants, the highest responses were observed on the culture medium supplemented with 0.17 M sucrose in both interspecific crosses. All tested plants were found to be diploid by flow cytometric analyses. Fluorescent amplified—fragment length polymorphism (fAFLP) confirmed the hybrid origin of the regenerated plants. This study reports on the success of a three-step embryo rescue procedure for Hylocereus species. The procedure developed here provides the means for producing plants from very-early embryo stage, thus expanding the prospects for vine-cactus breeding programs.     

不同除草剂加倍玉米单倍体的效率

通过比较3种除草剂加倍玉米单倍体的效率,提出了利用除草剂加倍玉米单倍体的新方法。以先玉335、中农大4号和8607×8609三个基因型诱导的单倍体籽粒为材料,利用20、40、80和160 μmol L^-1浓度的甲基胺草磷、炔苯酰草胺和氟乐灵作为加倍药剂,在单倍体植株生长到三叶期和五叶期时,用滴心法处理幼苗,选择有花粉的单株自交,收获后调查果穗加倍率;采用细胞学方法观察单倍体的染色体数目和花粉的活性。结果表明,20~160 μmol L^-1的3种除草剂对玉米单倍体加倍均有效果,加倍率在3.42%~26.32%之间。甲基胺草磷、炔苯酰草胺和氟乐灵的加倍率分别为4.29%~26.32%、3.85%~20.81%和3.42%~17.61%;其中80 μmol L^-1甲基胺草磷的加倍效果最佳,使用80 μmol L^-1甲基胺草磷处理3个杂交种的单倍体,平均加倍率分别为25.02%、20.13%和14.99%。方差分析表明,3个基因型间的单倍体加倍率均呈极显著差异,可见使用甲基胺草磷、炔苯酰草胺、氟乐灵可以提高玉米单倍体的加倍频率,但不同基因型单倍体对除草剂的敏感性存在差异。     

Chromosome doubling of androgenic haploid plantlets of rice (Oryza sativa) using antimitotic compounds

The regeneration of haploid plantlets is considered as a bottleneck in rice anther culture. In this study, an antimitotic chromosome doubling method, simple and efficient, of androgenic haploid plantlets resulted in an efficient doubled haploid obtainment. Through chromosome doubling capacity comparison of the three antimitotic compounds (colchicine, trifluralin and oryzalin), colchicine at 500 and 625 mg/L without supplementing with DMSO was found to be the best antimitotic treatment, with a chromosome doubling capacity of 40%. Furthermore, the in vitro growth of plantlets was followed to analyse the effects of antimitotic compounds. Colchicine treatments were more toxic than dinitroanilines, and colchicine DMSO-supplemented treatments had significant lower values on shoot growth. On the other hand, dinitroaniline compounds impeded root growth, provoked helical growth of shoot and caused the apparition of white nodules in the base of the plantlet due to sprouting abortion. In this study, a protocol for doubled haploid plant recovery was established taking advantage from androgenic haploid plantlets in order to increase the number of doubled haploid plantlets produced after an anther culture protocol.     

Oryzalin as an Efficient Agent for Chromosome Doubling of Haploid Apple Shoots in vitro

In an outbreeding species such as apple, haploid plants may be especially useful in breeding programmes for the production of homozygous material. However, methods must be available to induce chromosome doubling in the haploid plants. Two antimitotic agents, colchicine and oryzalin, were compared as regards their efficiency in inducing chromosome doubling of in vitro haploid apple shoots. Three colchicine levels (0.025, 0.25 and 1.25 mM) and three oryzalin levels (5, 15 and 30 μM) were evaluated. Three techniques were also used and compared. Survival rate and chromosome counts were determined. Differences were observed between the two antimitotic agents and between the three techniques. This study demonstrates that oryzalin could be a better choice than colchicine for chromosome doubling on haploid apple shoots in vitro.     

In vitro polyploidisation of <Emphasis Type="Italic">Helleborus</Emphasis> species

Helleborus species are members of the family of the Ranunculaceae. These popular perennials are all diploids (2n = 2x = 32). This study investigates polyploidy induction by different antimitotic agents. Colchicine, oryzalin and trifluralin were tested in vitro on shoots of Helleborus niger, H. orientalis and H. × nigercors. Furthermore the effect of the antimitotic agents on the viability and the multiplication rate of cultured plantlets were analyzed. Flow cytometry demonstrated that polyploidisation was genotype dependent: using H. niger, tetraploids were obtained using either oryzalin (3 μM) or trifluralin (3 or 10 μM), whereas for H. × nigercors only trifluralin (3 or 10 μM) induced polyploidisation. For H. orientalis neither treatment was effective to produce tetraploids or mixoploids. For these three species, colchicine (100 μM) was ineffective. The polyploidisation events in H. niger and H. × nigercors were confirmed by chromosome counts of mounted nuclei derived from root tips (2n = 4x = 64).     

Effect of chromosome-doubling agents on somaclonal variation in the progeny of doubled haploids of maize

This study was carried out to determine whether the treatment of anther-culture-derived haploid callus of maize (Zea mays) with chromosome-doubling agents, such as colchicine or the herbicides pronamide and amiprophos-methyl (APM), induces higher than normal levels of somaclonal variation. A total of 79 R₁ families produced by diploid regenerated plants resulting from chromosome-doubling treatments were evaluated in the field in comparison with the three parental inbreds. Four qualitative variant phenotypes — male sterility, chlorophyll deficiency, earless plants, and short plants with narrow leaves and thin stalks —– were observed. The last phenotype (narrow leaves and thin stalks) was also found in the inbreds FR16 and H99 grown from seed, so it may not be directly related to the tissue-culture conditions or the anti-microtubule-agent treatments. The frequency of R₁ families segregating for the other three mutations was 3.8%, which is no higher than the somaclonal variation frequencies observed previously in tissue-culture-derived maize plants. Observations of three quantitative traits—–days to anthesis, days to silk emergence, and plant height—– also failed to detect any extra variation that could be related to the treatments with anti-microtubule agents. These studies indicate that the anti-microtubule agents APM, pronamide and colchicine can be used to induce chromosome doubling of anther-culture-derived callus to produce a high proportion of doubled haploid plants without causing increased rates of mutation (somaclonal variation).     

In vitro chromosome doubling of Miscanthus sinensis

The aim was to develop an efficient chromosome doubling method for Miscanthus sinensis to enable the production of triploids and so avoid seed dispersal to the environment. Antimitotic treatments with colchicine or oryzalin were tested in M. sinensis cl. MS‐88‐110 on: (1) in vitro shoots and plants established in soil; (2) during propagation of embryogenic callus; and (c) during the initial stages of callus induction. All systems produced chromosome‐doubled plants. A higher percentage of tetraploids was found after antimitotic treatment at the explant or callus level compared with treatment of in vitro shoots or plants established in soil. In general, oryzalin was more toxic to plant material than colchicine. A higher frequency of chimeras was found among plants with altered ploidy level when the target was formed shoot buds compared with adventitious shoot formation from callus. Antimitotic treatment of embryogenic callus from shoot apices also resulted in a high degree of albinism.     

In vitro chromosome doubling with colchicine during microspore culture in wheat (Triticum aestivum L.)

Isolated microspores of two DH lines of wheat were treated with 8 different colchicine concentrations up to 3 mM for either 24 h or 48 h during microspore culture. Untreated control cultures produced on average 220 embryos per spike (100,000 microspores), 68% of the regenerated plantlets were green, and 15% of the flowering plants were fertile. The colchicine treatments had a significant effect on chromosome doubling as measured by the percentage of fertile regenerants. Using colchicine concentrations around 1 mM the percentage of fertile plants among the regenerants was increased up to 53%. The highest number of embryos and regeneration rates were observed after 24 h colchicine treatment, while the highest frequencies of green plants and fertile plants were obtained with 48 h colchicine treatments. The highest number of DH plants per spike was found after treatment with colchicine concentrations of 300 to 1000 μM. Such treatments resulted in an estimated average between the two genotypes of 23 doubled haploid plants per spike. This revised version was published online in July 2006 with corrections to the Cover Date.     

Genetic and environmental effects on chromosome doubling of sugarbeet (Beta vulgaris L.) haploids

Summary Chromosome doubling has been a limiting factor for production of doubled-haploids, a means of obtaining fruly homozygous individuals, and a time-saving alternative to repeated selfing for the creation of inbred lines. The existence of genetic, environmental and genotype × environment interaction effects on chromosome doubling ability of sugarbeet (Beta vulgaris L.) haploids was investigated. Haploids were derived from four distinct, highly heterozygous diploid populations through in vitro culture of unpollinated ovules. Ovule-derived plants were treated with colchicine to double their chromosome complement. Environmental effects were determined from replication of the experiment at seven dates. Both genetic and environmental factors were found to affect chromosome doubling ability of sugarbeet haploids. No significant interaction between genotype and environment was identified. The presence of genetic effects on chromosome doubling ability is discussed with regard to its implications on breeding programs.     

Improving in vitro induction of autopolyploidy in grapevine seedless cultivars

The efficiency of in vitro polyploidization depends on several variables associated to the plant, the antimicrotubule agent and the interactions between them. In the present work, we have used response-surface methodology to determine the best operating conditions for plant recovery in polyploidization assays for shoot apices and somatic embryos of two seedless grape cultivars, employing colchicine and oryzalin. Explant type, tubulin-interfering compound and concentration were the critical factors determining plant recovery. Linear reduction in viable plant regeneration via organogenesis and somatic embryogenesis was obtained by increasing oryzalin concentrations and treatment time, whereas the effects of colchicine were better described by a quadratic design for both explants types. The conditions promoting higher rates of plant recovery were used in chromosome doubling experiments with oryzalin and colchicine for shoot apices and somatic embryos of ‘Crimson seedless’ and ‘BRS Clara’. The established protocols allowed the recovery of non-chimerical autotetraploid plants at rates higher than 30 % for both cultivars. Stomata size parameters statistically correlate to the ploidy level of the regenerants and were effective for preliminary polyploidy screening. Autotetraploid lines of seedless grapes were incorporated into the Vitis germplasm bank for further agronomical evaluations. To our knowledge, this is the first report of in vitro oryzalin induced polyploidization of grapevine and of the use of mathematical modeling to optimize chromosome doubling in plants.     

Analysis of reproductive isolation between pearl millet (Pennisetum glaucum (L.) R.Br.) and P. ramosum, P. schweinfurthii, P. squamulatum, Cenchrus ciliaris

Crosses between pearl millet lines and Pennisetum ramosum, P. schweinfurthii, P. squamulatum or Cenchrus ciliaris were observed for the frequency and development of zygotes, the possibility of embryo rescue, and the fertility of F1 hybrids obtained. Eight per cent of the ovules from diploid millet × P. ramosum crosses showed small embryos which could not be rescued. However, 59% of the ovules from tetraploid millet × P. ramosum crosses showed well-developed embryos that were easy to rescue 14 days after pollination. F1 hybrids were male sterile but female fertile when pollinated by diploid millet. Both diploid and tetraploid millet ovules showed the presence of hybrid zygotes after pollination with P. schweinfurthii at rates ranging from 25% to 45%. The diploid millet× P. schweinfurthii hybrid zygotes often developed almost normal seeds giving, without embryo rescue, totally sterile plants. The tetraploid millet × P. schweinfurthii hybrid embryos were normal but the endosperm was severely defective. A hybrid obtained by embryo rescue was totally sterile. A diploid millet-P. schweinfurthii amphidiploid was obtained by somatic embryogenesis associated with colchicine treatment during callogenesis. This amphiploid plant was male sterile, but gave many seeds when pollinated by a tetraploid millet and few seeds when pollinated by a diploid millet. P. squamulatum pollinating diploid millets produced proembryos with large undifferentiated endosperms in 73% of the ovules. A normal seed set was observed on tetraploid millets pollinated by P. squamulatum and the resulting F1 hybrids were partially male and female fertile. Backcrosses of these hybrids were much more fertile when pollination was from a tetraploid millet rather than from a diploid millet. C. ciliaris pollinating a diploid millet showed, in 60% of the ovules, proembryos and endosperms similar to those observed with P. squamulatum and no hybrid could be rescued. Crosses with a tetraploid millet could not be attempted due to the pistil-pollen incompatibility of tetraploid millets available with C. ciliaris. Ploidy levels of mating partners do not seem to influence pistil-pollen compatibility, but play a major role in post-zygotic abortion. With adequate ploidy levels of parents, and embryo rescue, it seems that the pearl millet gene pool can be considerably enlarged by germplasm from many other species.     

The effect of colchicine on triticale anther-derived plants: Microspore pre-treatment and haploid-plant treatment using a hydroponic recovery system

In cereals, chromosome doubling of microspore-derived haploid plants is a critical step in producing doubled haploid plants. This investigation was undertaken to study the effect of incorporation of colchicine in the induction medium for anther culture, and the effect of colchicine on anther culture-derived plants of triticale grown under controlled greenhouse conditions. In the latter case, chromosome doubling of adult sterile plants derived from anther culture of fourteen triticale populations was attempted, where androgenetic plants with non-dehiscent anthers were cloned and subjected to the colchicine treatment, and then grown with the aid of hydroponics. The hydroponic system provided optimal conditions for recovery of the affected haploids from the toxic effects of colchicine treatment and all colchicine-treated plants survived. A topcross-F₁ (TC₁F₁) population with timopheevii cytoplasm produced the highest percentage of plants with seed-set either due to chromosome doubling by colchicine (98%) or spontaneous doubling of chromosome number (15%). Colchicine-treated anthers performed inferior than control in both induction and regeneration phases. One of the key observation of this study was the reversal from reproductive stage back to the vegetative stage which in turn enabled further cloning of haploid plants under hydroponic conditions once they were identified as sterile. The one hundred percent survival rate of in vitro-derived plants, 100% survival rate of colchicine treated haploid plants and the high chromosome doubling success rate (X = 82.3) observed in this study imply that a temperature-controlled greenhouse with an hydroponic system provides an efficient environment for inducing chromosome doubling of haploid plants in cereals. This revised version was published online in August 2006 with corrections to the Cover Date.     

In vitro induction of tetraploid plants from callus cultures of diploid bananas (<Emphasis Type="Italic">Musa acuminata</Emphasis>, AA group) ‘Kluai Leb Mu Nang’ and ‘Kluai Sa’

Tetraploid plants were induced successfully from diploid bananas Musa acuminata (AA genome) ‘Kluai Leb Mu Nang’ and ‘Kluai Sa’ (2n = 2x = 22) with in vitro oryzalin treatment. Calluses from in vitro-grown shoot tips of both cultivars were treated with oryzalin at concentrations of 1.5 or 3 mg l⁻¹ for 24, 48 and 72 h, respectively. The oryzalin treatments produced tetraploids at a frequency of 15.6% in ‘Kluai Leb Mu Nang’ and 16.7% in ‘Kluai Sa’ as detected by flow cytometry. Chromosome counting showed that the tetraploid plant chromosome number was (2n = 4x = 44). The selected tetraploid plants were transplanted in the field and variations in the morphological characteristic of leaf shape and fruit bunch compared to normal diploid plants were found under the same growing condition even after 3 years of cultivation.