Ascertaining clonal fidelity of micropropagated plants of Dendrocalamus hamiltonii Nees et Arn. ex Munro using molecular markers

Dendrocalamus hamiltonii is a giant, evergreen, clumping, multipurpose bamboo with strong culms which are mainly used for construction, handicrafts and fuel. The tender shoots are also used as food. Overexploitation of existing natural stocks coupled with harvesting of culms before seed formation, a long flowering cycle, irregular and poor seed production, short seed viability, seed sterility, limited availability of offsets and rhizomes and seasonal dependence are some of the major bottlenecks in conventional propagation of this species. Therefore, alternative methods like micropropagation can fill the gap in demand and supply of true-to-type planting material. Recently, our micropropagation protocol for rapid multiplication of D. hamiltonii through axillary bud proliferation using nodal explants from mature culms was standardized, and more than 3,000 plants were transferred to the field. However, somaclonal variations are known to appear in the in vitro-derived clones due to culture-induced stresses. Therefore, the present investigation was conducted to ascertain the effect of the length of in vitro culture age on clonal fidelity of regenerated plants using random amplified polymorphic DNA (RAPD), inter-simple sequence repeat (ISSR), amplified fragment length polymorphism (AFLP) and simple sequence repeat (SSR) markers. The genomic DNA samples (i.e. mother plant, in vitro-raised shoots from the 3rd to 30th passage, and in vitro-raised plants transferred to the field) were subjected to PCR amplification using 90 primer combinations (25 each of RAPD, ISSR and SSR, and 15 AFLP primer combinations) of which 76 (23 RAPD, 24 ISSR, 21 SSR and 8 AFLP) markers showed amplified DNA fragments. The 23 RAPD primers produced 162 distinct amplified DNA fragments from 2 (OPE-5) to 16 (OPE-16) fragments per primer, while 24 ISSR primers produced 181 distinct amplified DNA fragments with an average of 7.5 fragments per primer. The number of bands generated by SSR primers varied from 3 (RM-7 and RM-240) to 14 (RM-44), and the eight combinations of AFLP primers produced 369 distinct and scorable amplified DNA fragments with an average of 46.1 fragments per primer. Appearance of monomorphic bands with all the tested primer combinations confirmed the true-to-type nature of the in vitro clones of D. hamiltonii and hence the suitability of the developed micropropagation protocol for commercial-scale plant production.     

Evaluation of the genetic fidelity of in vitro-propagated gerbera (<Emphasis Type="Italic">Gerbera jamesonii</Emphasis> Bolus) using DNA-based markers

The genetic fidelity of in vitro-raised gerbera clones was assessed by using random amplified polymorphic DNA (RAPD) and inter-simple sequence repeat (ISSR) markers. Out of 35 RAPD and 32 ISSR primers screened, only 12 RAPD and 10 ISSR primers produced clear, reproducible and scorable bands. The 12 RAPD primers produced 54 distinct and scorable bands, with an average of 4.5 bands per primer. The number of scorable bands for ISSR primers varied from 3 (ISSR-14) to 9 (ISSR-07), with an average of 5.5 bands per primer. The number of bands generated per primer was greater in ISSR than RAPD. All banding profiles from micropropagated plants were monomorphic and similar to those of the mother plant. A similarity matrix based on Jaccard’s coefficient revealed that the pair-wise value between the mother and the in vitro-raised plantlets was 1, indicating 100% similarity. This confirmed the true-to-type nature of the in vitro-raised clones.     

Evaluation of clonal integrity in desert date tree (Balanites aegyptiaca Del.) by inter-simple sequence repeat marker assay

Axillary shoot bud multiplication as a safest mode of micropropagation to obtain clonal progeny was revealed through the application of molecular marker technique in Balanites aegyptiaca. Inter-simple sequence repeat (ISSR) markers were used to evaluate the genetic constancy of micropropagated plantlets chosen from a clonal collection of shoots that originated from mature nodal explants (mother plant). Out of 20 ISSR primers screened, ten primers yielded reliable and reproducible patterns of amplified products in all the tested plants. In this study, on an average, 11.7 bands were amplified per primer. A total of 117 bands were scored for the tissue culture-raised plantlets; 115 amplification products were monomorphic and 2 bands were polymorphic. Based on the ISSR band data, 98.2 % genetic uniformity was detected among the regenerants. Thus, the amplification products validated that the plantlets were true-to-type in morphological or growth characteristics when compared with the mother plant.     

An Assessment of Genetic Integrity of Micropropagated Plants of Plumbago Zeylanica by RAPD Markers

Clones of Plumbago zeylanica were micropropagated using nodal culture. The application of random amplified polymorphic DNA (RAPD) in assessing the genetic integrity of the micropropagated plants was evaluated by polymerase chain reaction. Twenty arbitrary decamers were used to amplify genomic DNA from in vitro and in vivo plant material to assess the genetic fidelity. All RAPD profiles from micro-propagated plants were monomorphic and similar to those of field grown mother plants. No polymorphism was detected within the micropropagated plants.     

Determination of genetic stability of long-term micropropagated plantlets of Platanus acerifolia using ISSR markers

Inter-simple sequence repeat (ISSR) markers were used to assess the genetic stability of long-term micropropagated plantlets of London plane tree (Platanus acerifolia Willd.). Twenty micropropagated plantlets were chosen from a clonal collection of shoots that originated from a single mother shoot. This clonal collection had been maintained under in vitro culture conditions for at least 8 years, as achieved by axillary branch multiplication. Out of 38 ISSR primers screened, 16 primers were found to produce clear reproducible bands resulting in a total of 103 distinct bands with an average of 6.44 scorable bands per primer. Of these 103 bands, 86 were monomorphic across all 20 of the plants tested and 17 showed polymorphisms (16.5 % polymorphism). Based on the ISSR band data, similarity indices between the plantlets ranged from 0.92 to 1.00. These similarity indices were used to construct an UPGMA dendrogram and demonstrated that all 20 micropropagated plants grouped together in one major cluster with a similarity level of 91 %. A total of 1771 scorable bands were obtained from the full combination of primers and plantlets and only 51 (2.88 %) were polymorphic across the plantlets which indicates that this micropropagated line of P. acerifolia is genetically stable.     

Application of rapd in the determination of genetic fidelity in micropropagated Drosera plantlets

Summary Random amplified polymorphic DNA (RAPD) markers were used to verify the clonal fidelity of two micropropagated Drosera species, D. anglica and D. binata, which were regenerated by adventitious budding from leaf explants and shoot tips, respectively. Twenty arbitrary decamers were used to screen 15 randomly selected plantlets of each species. No genetic variation was detected among D. binata regenerants, whereas a 0.08% polymorphism frequency was estimated for D. anglica plantlets. These results indicate that the regeneration of plants through shoot-tip culture is a low-risk method for generating genetic variability, whereas material regenerated through leaf explants requires further verification.     

Assessment of genetic fidelity of micropropagated plants of <Emphasis Type="Italic">Simmondsia chinensis</Emphasis> (Link) Schneider using RAPD and ISSR markers

RAPD (random amplified polymorphic DNA) and ISSR (inter simple sequence repeat) markers were screened to test the genetic integrity of jojoba (Simmondsia chinensis) plants multiplied through axillary bud multiplication from nodal segments. The in vitro raised plantlets were maintained for up to 12 in vitro subcultures. During the study a total of 48 (32 RAPD and 16 ISSR) primers were screened, out of which 24 RAPD and 13 ISSR primers produced a total of 191 (126 RAPD and 65 ISSR) clear, distinct and reproducible amplicons. The amplified products were monomorphic across all the selected micropropagated plants and were similar to the mother plant. The micropropagation protocol developed by our group for rapid in vitro multiplication is appropriate for clonal propagation of jojoba. The outcome supports the fact that axillary bud multiplication can also be used as one of the safest modes for the production of true-to-type plants.     

Genetic stability in micropropagated Cleome gynandra revealed by SCoT analysis

A newly developed and novel DNA marker technique, i.e. start codon targeted (SCoT) polymorphic markers that target plant gene regions were used to assess genetic stability of in vitro raised plants of Cleome gynandra multiplied by enhanced bud proliferation from nodal segments. Seven randomly selected micropropagated plants, following at least 2 months of growth in the greenhouse along with mother plant were subjected to molecular analysis. Of 24 primers screened, 15 primers produced unambiguous and reproducible bands. All 15 primers generated a total of 65 fragments, with a mean of 4.3 ranging 2–7 per primer. No polymorphism was detected in regenerated plants and the mother plant, revealing the genetic fidelity of the in vitro raised plantlets. To verify the results of SCoT analysis, random amplified polymorphic DNA (RAPD) markers were also used for the assessment of genetic fidelity of tissue culture raised plants. The monomorphic banding pattern in micropropagated plants and the mother plant obtained from SCoT and RAPD analysis confirms the genetic stability of the in vitro raised plants and demonstrates the reliability of our micropropagation system for C. gynandra, an important C₄ plant.     

Assessments of somaclonal variation in micropropagated shoots of <Emphasis Type="Italic">Cedrus</Emphasis>: consequences of axillary bud breaking

Reversed-phase HPLC analysis and random amplified polymorphic DNA (RAPD) markers were used to monitor DNA methylation status and genetic stability of C. atlantica and C. libani shoots generated through axillary bud proliferation. Average DNA methylation in C. atlantica or C. libani seedlings and mature 200-year-old trees of C. libani was 19.8, 19.5 and 22.3%, respectively. These global amounts showed no significant variation after the in vitro establishment of seedling-originated shoot stocks. In contrast, in vitro culture caused a significant decrease in the amount of 5-methylcytosine in genomic DNA of the tissue culture (TC) progenies of one of the adult C. libani genotypes. This DNA demethylation event accompanied an enhancement of the regrowth capacity of this genotype. Detected RAPD variation between mother plants and their TC progenies was species-related, with C. libani TC progenies being genetically more stable than those of C. atlantica. Nevertheless, similarity indices ranged from 0.97 to 1 among mother plants and their TC progenies. Furthermore, the analyses of molecular variance (AMOVA) suggest that RAPD variation among the mother plants and their TC progenies might be considered as not significant. The application of various statistical approaches, including cluster-based genetic distance methods and AMOVA, demonstrates that RAPD markers discriminate C. atlantica and C. libani appropriately.     

Micropropagation of Tectona grandis: Assessment of Genetic Fidelity

Random amplified polymorphic DNA (RAPD) markers were used to analyze genetic fidelity of micropropagated teak (Tectona grandis L.) clones with respect to subcultural passage. Of the twenty primers screened, no variation in RAPD profiles was noticed in the in vitro clones of fifth, tenth, fifteenth and twentieth passage in comparison to the in vivo mother plants. Only one micropropagated plant of twenty-fifth subcultural passage, however, differed from the in vivo ones. It revealed the appearance of a new polymorphic DNA fragment (molecular mass 379 kb) in case of primer OPB-08. This primer, manifesting detectable variation, may be utilized as a diagnostic marker for assessing genetic fidelity of micropropagted teak plants. This revised version was published online in July 2006 with corrections to the Cover Date.     

Using AFLP markers for species differentiation and assessment of genetic variability of in vitro-cultured Papaver bracteatum (section Oxytona)

Summary Amplified fragment length polymorphism (AFLP) markers were employed to deteet genetic variation among species of Papever (section Oxytona) and assess genetic fidelity between in vitro cell lines of Papaver bracteatum and mature plants derived from the propagation of their callus cultures. Regenerated plants exhibited morphological and phytochemical characteristics dissimilar to those of their source material. Thebaine, the dominant alkaloid produced by Papaver bracteatum, was not detected in capsules from mature regenerated accessions, indicating that there may have been a loss of genetic uniformity. Instead, the dominant alkaloid produced by the regenerated plant was shown to be isothebaine (by TLC and GC/MS), a metabolic characteristic of P. pseudo-orientale. A Neighbor-Joining tree constructed from AFLP fingerprints distinetly separates the three species of Oxytona while firmly grouping the in vitro-cultured plants with P. pseudo-orientale. Additionally phytochemical data and chromosome counts indicate that the seed used to initiate cultures was of hybrid origin and ihat the loss in genetic uniformity was not due to somaclonal variation occurring during the in vitro culture process. AFLP fingerprinting was therefore able to differentiate Oxytona species and invesgigate allopolyploidy in closely related papaver species.     

Assessment of genetic fidelity of micropropagated <Emphasis Type="Italic">Swertia chirayita</Emphasis> plantlets by ISSR marker assay

Inter simple sequence repeat (ISSR) marker assay was employed to validate the genetic fidelity of Swertia chirayita plantlets multiplied in vitro by axillary multiplication upto forty-two passages. Sixteen ISSR primers generated a total of 102 amplicons among the tissue-cultured plants. Forty-eight amplicons were amplified in the outlier (a Swertia species). The outlier (negative control) was employed to rule out the possibility that the invariant fingerprint was due to chance alone and that the ISSR technique employed was not discriminatory enough to detect the off-types. A homogenous amplification profile was observed for all the micropropagated plants. The results confirmed the clonal fidelity of the tissue culture-raised S. chirayita plantlets and corroborated the fact that axillary multiplication is the safest mode for multiplication of true to type plants.     

Establishment of genetic fidelity of In vitro-raised Lilium bulblets through rapd markers

Summary Random amplified polymorphic DNA (RAPD) markers were utilized for screening the clonal fidelity of in vitro-raised bulblets of Lilium sp. (Asiatic hybrids) produced through adventitious mode of propagation. The first set of 14 bulblets was randomly chosen from about 175 micropropagated bulblets regenerated from 1×1 cm² bulbscale segments (explants) of cultivar ‘Gran Paradiso’ after four subcultures (after 6 mo.). The second set of 15 bulblets was selected again randomly after 12 subcultures (after one and a half years) when the bulblets were to be taken out for transplantation. Of the 20 primers used to screen the samples, only 14 primers gave clear reproducible bands. The 14 primers produced a total of 163 (an average of 11.6 bands per primer) scorable bands. Analysis of individual primers revealed the RAPD patterns produced were all shared by both the in vitro-raised bulblets (randomly selected after four and 12 subcultures) and the mother bulb. There was no variation observed within the tissue culture-raised progenies. Thus, our results show that adventitiously propagated in vitro bulblets of Asiatic hybrids of lilies are clonally uniform and stable.     

Random amplified polymorphic DNA (RAPD) markers for genetic analysis in micropropagated plants of Populus deltoides Marsh

RAPD markers were used to assess genetic fidelity of 23 micropropagated plants of a single clone (L34) of Populus deltoides. Eleven arbitrary 10-base primers were successfully used to amplify DNA from in vivo and in vitro material. Of these, 5 distinguished a total of 13 polymorphisms common across 6 micropropagated plants. Apart from these 6 plants, the amplification products were monomorphic across all the micropropagated plants, the mother plant and 4 additional field-grown control plants. Our results show that RAPD markers can be used to gain rapid and precise information about genetic similarities or dissimilarities in micropropagation systems that might not be so easily evident from other commonly used techniques.     

ISSR assay for ascertaining genetic fidelity of micropropagated plants of apple rootstock Merton 793

With the current trends in high density plantations of fruit trees, numerous clonal rootstocks of apple have been developed through various breeding programs. Among them, Merton 793 is the most popular in India because of the desirable traits of vigorous growth and resistance to woolly apple aphid and collar rot. The planting material of this rootstock cannot be multiplied at a desirable rate by means of conventional vegetative propagation methods, so micropropagation techniques are being explored to augment scarce planting material. Large number of plants can be produced in vitro under aseptic conditions, but there is always a danger of producing somaclonal variants by tissue culture technology. Thus, it is advisable to check the clonal fidelity of in vitro raised plants, especially of perennials prior to their field transplantation. The genetic stability of in vitro raised plants of apple rootstock Merton 793, multiplied through enhanced axillary bud proliferation up to 22 subculture passages, was tested by intersimple sequence repeat (ISSR) assay. Of 24 ISSR primers screened, 15 primers produced clear reproducible bands, resulting in a total of 134 distinct bands with an average of 8.9 bands per primer. Apple rootstock MM 111 and scion Jonathan, taken as outliers with tissue culture-raised progenies of Merton 793, ruled out the possibility that the invariant banding pattern occurred because of inefficiency of ISSR primers in detecting variations. The homogenous amplification profile observed for all the micropropagated plants compared to the donor plant confirmed the clonal fidelity of the tissue culture-raised Merton 793 plants. This suggests that axillary bud multiplication is the safest mode for multiplication of true-to-type plants. This is the first study that evaluates the applicability of ISSR markers in establishing clonal fidelity of tissue culture-raised apple plants.     

Evaluation of genetic stability in cryopreserved Prunus

Summary The evaluation of the genetic stability of Prunus Ferlenain plants regenerated from cryopreserved apices was investigated. The analysis of plants recovered from frozen material was performed at the phenotypic (developmental competence), cytological (chromosomal preparations) and molecular level [random amplified polymorphic DNA (RAPD) and amplified fragment length polymorphism (AFLP)]. No genetic change was detected among the plantlets regenerated from frozen apices in comparison to the non-frozen material, including leaves of the mother tree kept in an orchard and vitroplantlets regenerated from non-frozen apices. This result suggested that the procedure used for Prunus cryopreservation could be used for long-term conservation. The relevance of each strategy for the genetic stability evaluation of the cryopreserved material is discussed.     

Amplified fragment length polymorphism (AFLP) in soybean: species diversity, inheritance, and near-isogenic line analysis

Amplified fragment length polymorphism (AFLP) analysis is a PCR-based technique capable of detecting more than 50 independent loci in a single PCR reaction. The objectives of the present study were to: (1) assess the extent of AFLP variation in cultivated (Gycine max L. Merr.) and wild soybean (G. soja Siebold & Zucc.), (2) determine genetic relationships among soybean accessions using AFLP data, and (3) evaluate the usefulness of AFLPs as genetic markers. Fifteen AFLP primer pairs detected a total of 759 AFLP fragments in a sample of 23 accessions of wild and cultivated soybean, with an average of 51 fragments produced per primer pair per accession. Two-hundred and seventy four fragments (36% of the total observed) were polymorphic, among which 127 (17%) were polymorphic in G. max and 237 (31%) were polymorphic in G. soja. F₂ segregation analysis of six AFLP fragments indicated that they segregate as stable Mendelian loci. The number of polymorphic loci detected per AFLP primer pair in a sample of 23 accessions ranged from 9 to 27. The AFLP phenotypic diversity values were greater in wild than in cultivated soybean. Cluster and principal component analyses using AFLP data clearly separated G. max and G. soja accessions. Within the G. max group, adapted soybean cultivars were tightly clustered, illustrating the relatively low genetic diversity present in cultivated soybean. AFLP analysis of four soybean near-isogenic lines (NILs) identified three AFLP markers putatively linked to a virus resistance gene from two sources. The capacity of AFLP analysis to detect thousands of independent genetic loci with minimal cost and time requirements makes them an ideal marker for a wide array of genetic investigations.     

PCR-based molecular markers for assessment of somaclonal variation in <Emphasis Type="Italic">Pinus pinea</Emphasis> clones micropropagated <Emphasis Type="Italic">in vitro</Emphasis>

Four different markers [random amplified polymorphic DNA (RAPD), inter simple sequence repeat (ISSR), amplified fragment length polymorphism (AFLP), and selective amplified microsatellite polymorphism length (SAMPL)] were applied for evaluating somaclonal variation of micropropagated genotypes of stone pine (Pinus pinea L.). The total number of primers tested was 130, with 223 combinations assayed. A high number of them amplified successfully (178), representing 79.82 % of the total, and the average number of amplified fragments ranged from 2.47 (ISSR) to 65.76 (SAMPL). Based on internal controls, no problem of reproducibility was detected. Almost no somaclonal variation was detected within the clones. Of the tested markers, ISSR, AFLP, and SAMPL showed monomorphic amplification profiles, with only RAPD markers showing some interclonal variation.     

Assessment of genetic diversity in Azadirachta indica using AFLP markers

 Genetic diversity was estimated in 37 neem accessions from different eco-geographic regions of India and four exotic lines from Thailand using AFLP markers. Seven AFLP selective primer combinations generated a total of 422 amplification products. The average number of scorable fragments was 60 per experiment, and a high degree (69.8%) of polymorphism was obtained per assay with values ranging from 58% to 83.8%. Several rare and accession-specific bands were identified which could be effectively used to distinguish the different genotypes. Genetic relationships within the accessions were evaluated by generating a similarity matrix based on the Jaccard index. The phenetic dendrogram generated by UPGMA as well as principal correspondence analysis separated the 37 Indian genotypes from the four Thai lines. The cluster analysis indicated that neem germplasm within India constitutes a broad genetic base with the values of genetic similarity coefficient ranging from 0.74 to 0.93. Also, the Indian genotypes were more dispersed on the principal correspondence plot, indicating a wide genetic base. The four lines from Thailand, on the other hand, formed a narrow genetic base with similarity coefficients ranging from 0.88 to 0.92. The lowest genetic similarity coefficient value (0.47) was observed between an Indian and an exotic genotype. The level of genetic variation detected within the neem accessions with AFLP analysis suggests that it is an efficient marker technology for delineating genetic relationships amongst genotypes and estimating genetic diversity, thereby enabling the formulation of appropriate strategies for conservation and tree improvement programs. Received: 20 October 1998 / Accepted: 28 November 1998     

Stomatal physiology of a micropropagated CAM plant; Agave tequilana (Weber)

Experiments were designed to assess the capacity of an in vitro cultured CAM plant to control water loss and to examine the response of their stomata to various factors. Detached leaves of micropropagated Agave tequilana plants lost water at similar rates as did field-grown plantlets when dehydrated in air. This was consistent with the fact that stomata from micropropagated plants show similar morphology than field-grown plantlets. In addition, stomata from micropropagated plants responded to various factors in a manner similar to those from field-grown plantlets. It appears that in vitro culture does not affect the capacity of leaves to control water loss nor does it alters the nocturnal stomatal opening of this CAM plant.