Genetic and epigenetic stability of cryopreserved and cold-stored hops (Humulus lupulus L.)

Conventional cold storage and cryopreservation methods for hops (Humulus lupulus L.) are available but, to our knowledge, the genetic and epigenetic stability of the recovered plants have not been tested. This study analyzed 51 accessions of hop using the molecular techniques, Random Amplified DNA Polymorphism (RAPD) and Amplified Fragment Length Polymorphism (AFLP), revealing no genetic variation among greenhouse-grown controls and cold stored or cryopreserved plants. Epigenetic stability was evaluated using Methylation Sensitive Amplified Polymorphism (MSAP). Over 36% of the loci were polymorphic when the cold and cryo-treated plants were compared to greenhouse plants. The main changes were demethylation events and they were common to the cryopreserved and cold stored plants indicating the possible effect of the in vitro establishment process, an essential step in both protocols. Protocol-specific methylation patterns were also detected indicating that both methods produced epigenetic changes in plants following cold storage and cryopreservation.     

Evaluation of genetic fidelity of in vitro raised plants of Dendrocalamus asper (Schult. & Schult. F.) Backer ex K. Heyne using DNA-based markers

Dendrocalamus asper, an edible bamboo is valued for its tender edible shoots in the food industry. However, overexploitation of natural stands of D. asper coupled with minimal conservation and reforestation efforts has led to its rapid depletion in nature. Therefore protocol for rapid multiplication of D. asper via direct regeneration using nodal segments from mature clumps was standardized and more than 25,000 plants were transferred to the field (Singh et al. 2012a). However, genetic fidelity of these in vitro raised plants needs to be authenticated for commercial scale application of the developed micropropagation protocol. PCR-based molecular markers have emerged as simple, fast, reliable and labor-effective tools for testing the genetic fidelity of in vitro raised plants. This study report the genetic fidelity analysis of in vitro raised plants of D. asper for the first time using arbitrary (Random Amplified Polymorphic DNA, RAPD), semi-arbitrary (Inter-Simple Sequence Repeat, ISSR; Amplified Fragment Length Polymorphism, AFLP), and sequence-based (Simple Sequence Repeat, SSR) markers. Bulked DNA samples of 20 in vitro raised shoots (collected after every three subculture cycles starting from 3rd to 30th passage) and field transferred plantlets were compared with the mother plant DNA using 90 primer combinations (25 each of RAPD, ISSR, SSR, and 15 AFLP) and scorable bands were produced by 78 (22 RAPD, 24 ISSR, 21 SSR, and 11 AFLP) primers. A total of 146 distinct and scorable bands were produced by 22 RAPD primers with an average of 6.6 bands per primer while the number of bands for ISSR primers varied from 3 (ISSR-4 and 9) to 13 (ISSR-17), with an average of 7.1 bands per primer. Similarly, SSR markers also showed wide variation in number of bands, ranging from 2 (RM 261) to 12 (RM 44, 140, and 224) with an average of 7.8 bands. AFLP primer combinations could generate 35–72 bands with an average of 48.7 bands per primer pair. Amplification of monomorphic bands with all primer combinations authenticated the true to type nature of the in vitro raised plants of D. asper which underwent up to 30 subculture passages over a period of approximately 2 years thereby supporting the commercial utilization of the developed micropropagation protocol.     

龙生型花生的遗传多样性

龙生型花生(Arachis hypogaea var.hirsute)是中国引进最早、种植最早的花生类型。经过不断地自然选择和人工选择,形成了许多各具特色的地方品种,并逐渐形成了次生中心。本实验对15份龙生型花生资源在植物学性状和品质性状及分子水平上进行了系统研究。结果表明:龙生型花生在植物学性状和品质性状上具有丰富的遗传多样性,在分子水平上差异也较大。变异系数在5.10~34.60之间,多样性指数在1.17~2.04之间,同时两者的变化趋势相反。基于植物学性状和品质性状上的聚类分析在阀值为6.5将龙生型花生分为两大类,一类主要包括广西的品种,另一类包括其它省份的品种;基于AFLP分析的聚类结果在阀值为0.39处分为5类,一类主要包括广西的品种,其它4类包括其它省份的品种。     

Multiple shoots induction in wild cotton (<Emphasis Type="Italic">Gossypium bickii</Emphasis>) through organogenesis and the analysis of genetic homogeneity of the regenerated plants

Fertile plants were regenerated via organogenesis from cultures of Gossypium bickii Prokhanov cotyledonary nodes devoid of cotyledons. Cotyledonary nodes from 7-day-old seedlings yielded the maximum number of shoots (9.12 shoots per explant) using MSB medium [MS medium (Murashige & Skoog 1962) and B5 (Gamborg et al. 1968) vitamins] supplemented with the combination of 4 mg/L BAP (N6-benzyladinine) and 0.1 mg/L TDZ (thidiazouron), and the subculture was made on a medium containing 2 mg/L BAP. Elongation of multiple shoots was obtained on MSB medium containing 0.05 mg/L GA₃ (gibberellic acid). For rooting, a modified half-strength MS medium was utilized. Some regenerants were transferred to a greenhouse, and most of them were morphologically normal and fertile. Histological studies revealed that proliferating buds originated directly from the superficial layers of the explants. Flow cytometric analyses and chromosome counting suggested that the regenerants and their offsprings were diploid. DNA content of regenerants and their offsprings was homogeneous and similar to that of seed-derived plants with unchanged chromosome number (2n = 26). Random amplified polymorphic DNA (RAPD) analysis confirmed the genetic homogeneity of the regenerants and their offsprings with the diploid parent.     

Agrobacterium-mediated transformation of peanut (Arachis hypogaea L.) embryo axes and the development of transgenic plants

Transgenic peanut (Arachis hypogaea L.) plants have been produced using an Agrobacterium-mediated transformation system. Zygotic embryo axes from mature seed were cocultured with Agrobacterium tumefaciens strain EHA101 harboring a binary vector that contained the genes for the scorable marker B-glucuronidase (GUS) and the selectable marker neomycin phosphotransferase II. Nine percent of the germinated seedlings were GUS+. Polymerase chain reaction analysis confirmed that GUS+ shoots and T₁ progeny contained T-DNA. Molecular characterization of one primary transformant and its T₁ and T₂ progeny plants established that T-DNA was integrated into the host genome.     

Assessment of genetic fidelity of encapsulated microshoots of <Emphasis Type="Italic">Picrorhiza kurrooa</Emphasis>

In vitro grown microshoots of Picrrhiza kurrooa were encapsulated in the alginate beads. Regrowth of encapsulated microshoots, using alginate encapsulation, of P. kurrooa reached 89.33% following 3 months of storage. Amongst developing plantlets, 42.66% exhibited formation of multiple shoots at the onset of regrowth and 21.43% demonstrated simultaneous formation of shoots and roots. Healthy root formation was observed in plantlets following 2 weeks of their transfer to half-strength Murashige and Skoog medium containing 1 μM α-naphthalene acetic acid. Plants were transplanted to the greenhouse in three batches with 95% frequency of survival. The genetic fidelity of P. kurrooa plants growing out after storage in encapsulated form was ascertained by random amplified polymorphic DNA (RAPD) analysis. Molecular analysis of randomly selected plants from each batch was conducted using 45 random decamer primers. Of 45 primes tested, 14 produced scorable amplified products. Total 68 bands were observed amongst them 7.35% bands were polymorphic. Cluster analysis of the RAPD profile revealed an average similarity coefficient of 0.966 thus confirming genetic stability of plants derived from encapsulated microshoots following 3 months of storage.     

Comparative assessment of variation in the USA Arachis pintoi (Krap. and Greg.) germplasm collection using RAPD profiling and tissue culture regeneration ability

Arachis pintoi accessions were used to study genetic diversity using RAPD markers. Concurrently, two tissue culture protocols were evaluated for organogenesis and the capacity to generate somaclonal variation. Data were collected on callus growth, callus weight gain, and number of regenerated plants. Robust RAPD profiles were obtained and eight primers amplified 100 different bands with 98% polymorphisms. The proportion of polymorphic RAPD loci was 89%. Average genetic distance was 0.36 and indicated that a large amount of genetic diversity exists within the germplasm evaluated. Genetic distances were used to prepare a dendogram for the A. pintoi accessions that separated them into four groups. A large degree of variability for callus induction and callus weight gain was observed among the accessions. Shoot regeneration was achieved for several accessions on both media with no structures indicative of somatic embryogenesis detected. Root induction was difficult to obtain, and many shoots died during this process. RAPD band profiles of regenerated tissue culture plants were similar to their parent plants, and therefore no somaclonal variation was evident using these methods.     

Genetic stability of cryopreserved shoot tips of <Emphasis Type="Italic">Rubus</Emphasis> germplasm

Questions often arise concerning the genetic stability of plant materials stored in liquid nitrogen for long time periods. This study examined the genetic stability of cryopreserved shoot tips of Rubus germplasm that were stored in liquid nitrogen for more than 12 yr, then rewarmed and regrown. We analyzed the genetic stability of Rubus grabowskii, two blackberry cultivars (“Hillemeyer” and ‘Silvan’), and one raspberry cultivar (“Mandarin”) as in vitro shoots and as field-grown plants. No morphological differences were observed in greenhouse-grown cryopreserved plants when compared to the control mother plants. In the field, cryopreserved plants appeared similar but were more vigorous than mother plants, with larger leaves, fruit, and seeds. Single sequence repeats (SSR) and amplified fragment length polymorphism (AFLP) analyses were performed on shoots immediately after recovery from cryopreservation and on shoots subcultured for 7 mo before analysis. Ten SSR primers developed from “Marion” and “Meeker” microsatellite-enriched libraries amplified one to 15 alleles per locus, with an average of seven alleles and a total of 70 alleles in the four genotypes tested. No SSR polymorphisms were observed between cryopreserved shoots and the corresponding mother plants regardless of subculture. Although no polymorphisms were detected in shoots analyzed immediately after recovery from cryopreservation, AFLP polymorphisms were detected in three of the four Rubus genotypes after they were subcultured for 7 mo. Field-grown plants from the polymorphic shoot tips of R. grabowskii and ‘Silvan’ displayed the same AFLP fingerprints as their corresponding mother plants. Only long-cultured in vitro shoot tips displayed polymorphisms in vitro, and they were no longer detected when the plants were grown ex vitro. The transitory nature of these polymorphisms should be carefully considered when monitoring for genetic stability.     

ISSR and RAPD based evaluation of genetic fidelity and active ingredient analysis of regenerated plants of Picrorhiza kurroa

Genetic stability and phytochemical analysis of in vitro established plants of Picrorhiza kurroa Royle ex Benth, have been carried out. Random amplified polymorphic DNA (RAPD) and inter simple sequence repeats (ISSR) markers were used to assess the genetic fidelity of tissue culture products including three adventitious shoots from three calli and 6 months old tissue culture raised plants growing in green house condition with mother plant. Apparent genetic variation was detected in the five types of plant materials. The percentage of polymorphic bands in the RAPD and ISSR analysis were 16.25 and 14.54 %, respectively. The genetic similarity was calculated on the basis of RAPD and ISSR data among the five types of plant materials and were ranged from 0.5 to 1.0 (mean 0.75) and 0.47 to 1.0 (mean 0.73), respectively. The similarity coefficient by both RAPD and ISSR analysis revealed that differences between tissue culture raised plants and mother plant was not remarkable, but notable differences were observed among three adventitious shoots regenerated from three calli. The phytochemical analysis of tissue culture raised products showed higher secondary metabolite (picrotin and picrotoxinin) content as compare to mother plant. The information gained on genetic stability/variability will be valuable for the large scale propagation and secondary metabolite production of P. kurroa.     

Inheritance and mapping of 2n-egg production in diploid alfalfa.

The production of eggs with the sporophytic chromosome number (2n eggs) in diploid alfalfa (Medicago spp.) is mainly associated with the absence of cytokinesis after restitutional meiosis. The formation of 2n eggs through diplosporic apomeiosis has also been documented in a diploid mutant of M. sativa subsp. falcata (L.) Arcang. (2n = 2x = 16), named PG-F9. Molecular tagging of 2n-egg formation appears to be an essential step towards marker-assisted breeding and map-based cloning strategies aimed at investigating and manipulating reproductive mutants of the M. sativa complex. We made controlled crosses between PG-F9 and three wild type plants of M. sativa subsp. coerulea (Less.) Schm. (2n = 2x = 16) and then hand-pollinated the F1 progenies with tetraploid plants of M. sativa subsp. sativa L. (2n = 4x = 32). As a triploid embryo block prevents the formation of 3x progenies in alfalfa because of endosperm imbalance, and owing to the negligible selfing rate, seed set in 2x-4x crosses was used to discriminate the genetic capacity for 2n-egg production. F1 plants that exhibited null or very low seed sets were classified as normal egg producers and plants with high seed sets as 2n-egg producers. A bulked segregant analysis (BSA) with RAPD (random amplified polymorphic DNA), ISSR (inter-simple sequence repeat), and AFLP (amplified fragment length polymorphism) markers was employed to identify a genetic linkage group related to the 2n-egg trait using one of the three F1 progenies. This approach enabled us to detect a paternal ISSR marker of 610 bp, generated by primer (CA)8-GC, located 9.8 cM from a putative gene (termed Tne1, two-n-eggs) that in its recessive form determines 2n eggs and a 30% recombination genomic window surrounding the target locus. Eight additional RAPD and AFLP markers, seven of maternal, and one of paternal origin, significantly co-segregated with the trait under investigation. The minimum number of quantitative trait loci (QTLs) controlling seed set in 2x-4x crosses was estimated by ANOVA and regression analysis. Four maternal and three paternal independent molecular markers significantly affected the trait. A paternal RAPD marker allele, mapped in the same linkage group of Tne1, explained 43% of the variation for seed set in 2x-4x crosses indicating the presence of a major QTL. A map of the PG-F9 chromosome regions carrying the minor genes that determine the expression level of 2n eggs was constructed using selected RAPD and AFLP markers. Two of these genes were linked to previously mapped RFLP loci belonging to groups 1 and 8. Molecular and genetic evidence support the involvement of at least five genes.     

Thidiazuron-induced highly morphogenic callus and high frequency regeneration of fertile peanut (Arachis hypogaea L.) plants

Summary An efficient regeneration system was developed by culturing immature cotyledons and embryo axes of Arachis hypogaea L. cv. Georgia Green on Murashige and Skoog basal medium (MS) supplemented with various concentrations of thidiazuron (TDZ; 1, 5, 10, and 15 μM). Highly morphogenic callus was produced from 100% of the explants comprising the cotyledon with attached embryo axis when cultured in the dark on 10 μM TDZ. Upon excision and continued culture in the dark on 10 μM TDZ, morphogenic callus grew repetitively during monthly subcultures and retained its regeneration potential. For organogenesis, a gradual reduction in TDZ concentration and exposure to light were necessary before transfer to MS basal medium. Inclusion of indole-3-butyric acid in liquid MS medium favored rooting of recovered shoots. A distinct feature of this investigation is the induction of highly morphogenic callus by TDZ and regeneration of morphologically normal, fertile peanut plants after 8 months of callus subculture.     

Analysis of genetic stability of in vitro propagated potato microtubers using DNA markers

The genetic stability of in vitro propagated potato microtubers was assessed using random amplified polymorphic DNA (RAPD), inter simple sequence repeat (ISSR), simple sequence repeat (SSR) and amplified fragment length polymorphism (AFLP) markers. Microtubers were developed through in vitro from potato microplants using standardized protocols. The microtubers were conserved for 1 year under three different culture media and consequently microplants were regenerated for the DNA analyses. During the study, a total of 38 (10 RAPD, 11 ISSR, 12 SSR and 5 AFLP) primers produced a total of 407 (58 RAPD, 56 ISSR, 96 SSR and 197 AFLP) clear, distinct and reproducible amplicons. Cluster analysis revealed 100 % genetic similarity among the mother plant and its derivatives within the clusters by SSR, ISSR and RAPD analyses, whereas AFLP analysis revealed from 85 to 100 % genetic similarity. Dendrogram analysis based on the Jaccard’s coefficient classified the genotypes into five clusters (I–V), each cluster consisting of mother plant and its derivatives. Principal component analysis (PCA) also plotted mother plant and its genotypes of each cluster together. Based on our results, it is concluded that AFLP is the best method followed by SSR, ISSR and RAPD to detect genetic stability of in vitro conserved potato microtubers. The in vitro conservation medium (T2) is a safe method for conservation of potato microtubers to produce true-to-type plans.     

Molecular characterization of intra-population variability of <Emphasis Type="Italic">Jatropha curcas</Emphasis> L. using DNA based molecular markers

Jatropha curcas L. (Euphorbiaceae) has acquired a great importance as a renewable source of energy with a number of environmental benefits. Very few attempts were made to understand the extent of genetic diversity of J. curcas germplasm. In the present study, efforts were made to analyze the genetic diversity among the elite germplasms of J. curcas, selected on the basis of their performance in field using random amplified polymorphic DNA (RAPD), amplified fragment length polymorphism (AFLP) and simple sequence repeats (SSR). The plants were selected on the basis of height, canopy circumference, number of seeds per fruit, weight of 100 seeds, seed yield in grams per plant and oil content. Out of 250 RAPD (with 26 primers), 822 AFLP (with 17 primers) and 19 SSR band classes, 141, 346 and 7 were found to be polymorphic, respectively. The percentage polymorphism among the selected germplasms using RAPD, AFLP and SSR was found to be 56.43, 57.9, and 36.84, respectively. The Jaccard’s similarity coefficient was found 0.91, 0.90 and 0.91 through RAPD, AFLP and SSR marker systems, respectively. Principle component analysis (PCA) and dendrogarm analysis of genetic relationship among the germplasm using RAPD, AFLP and SSR data showed a good correlation for individual markers. The germplasm JCC-11, 12, 13, 14 and 15 whose yield found to be high were clustered together in dendrogram and PCA analysis though JCC11 is geographically distinct from others. In overall analysis JCC6 (in RAPD), JCC8 (in AFLP) and JCC 6 and JCC10 (in SSR) were found genetically diverse. Characterization of geographically distinct and genetically diverse germplasms with varied yield characters is an important step in marker assisted selection (MAS) and it can be useful for breeding programs and QTL mapping.     

基于RAPD、ISSR和AFLP对西瓜枯萎病菌遗传多样性的评价

利用RAPD、ISSR和AFLP分子标记技术对50个西瓜枯萎病菌株进行了分析。结果表明,21个RAPD引物、21个ISSR引物和21对AFLP引物分别对供试菌株扩增出113、134和389条带,三种分子标记的遗传相似系数比较一致,均可揭示西瓜枯萎病菌的遗传变异特点。三种分子标记产生的聚类分析结果存在一定差异,其中RAPD类群与生理小种和地理来源之间均不存在明显关系;而AFLP和ISSR类群与生理小种之间存在一定相关性,与菌株的地理来源关系不明显。     

基于RAPD、ISSR和AFLP对西瓜枯萎病菌遗传多样性的评价

利用RAPD、ISSR和AFLP分子标记技术对50个西瓜枯萎病菌株进行了分析。结果表明,21个RAPD引物、21个ISSR引物和21对AFLP引物分别对供试菌株扩增出113、134和389条带,三种分子标记的遗传相似系数比较一致,均可揭示西瓜枯萎病菌的遗传变异特点。三种分子标记产生的聚类分析结果存在一定差异,其中RAPD类群与生理小种和地理来源之间均不存在明显关系;而AFLP和ISSR类群与生理小种之间存在一定相关性,与菌株的地理来源关系不明显。     

Novel polymorphic microsatellite markers in section Caulorrhizae (Arachis,Fabaceae)

This work reports the characterization of 11 polymorphic microsatellite loci in section Caulorrhizae. The primer pairs were designed from Arachis pintoi and showed full transferability to Arachis repens species. These new markers were used to evaluate the genetic diversity in germplasm (accessions and cultivars) of section Caulorrhizae. This new set of markers detected greater gene diversity than morphological and molecular markers such as AFLP (amplified fragment length polymorphism) and RAPD (rapid analysis of polymorphic DNA) previously used in this germplasm.     

ISSR and RAPD Based Evaluation of Genetic Stability of Encapsulated Micro Shoots of Glycyrrhiza glabra Following 6?Months of Storage

In vitro grown axillary micro shoots of Glycyrrhiza glabra were encapsulated in alginate beads. Following 6?months of normal storage at 25?±?2°C the re growth of encapsulated G. glabra micro shoots, reached 98% within 30?days of incubation on MS medium supplemented with 0.1 mg/l IAA. Re growth was characterized by the development of both shoot and root from single encapsulated micro shoot. Healthy plants were established to glass house with 95% survival. The genetic fidelity of plants obtained after conversion of alginate beads was ascertained through 10 RAPD and 13 ISSR primers. Of the 10 RAPD primers tested, 6 of them produced 14 clear and reproducible amplicons with an average of 2.3 bands per primer out of which 28.57% were polymorphic generated by only two primers. Eight ISSR primers produced total 37 bands ranging between 300 and 3,500?bp length. Number of scorable bands for each primer varied from 3 to 8 with an average of 4.6 bands per primer. Cluster analysis from ISSR and RAPD showed that all the tested plants including the mother plant distributed in two major groups with similarity coefficient ranging from 0.91 to 0.96 for RAPD and 0.89 to 0.97 for ISSR.     

Monitoring of cultivar identity in micropropagated olive plants using RAPD and ISR markers

Randomly amplified polymorphic DNA (RAPD) and inter simple sequence repeat (ISSR) markers were applied to assess the genetic stability of micropropagated olive (Olea europaea L. cv. Maurino) plants regenerated by axillary buds. Initial olive explants, isolated from one donor tree, were multiplied on Murashige and Skoog medium for 12 repeated subcultures. A total of 40 RAPD and 10 ISSR markers resulted in 301 distinct and reproducible band classes showing homogeneous RAPD and ISSR patterns. The amplification products revealed genetic stability among the micropropagated plants and between them and the donor plant. The results demonstrate the genetic stability of nine year old mature micropropagated olive plants cultured in field, and corroborated the fact that axillary multiplication is the safest mode for multiplication of true to type plants.     

Molecular characterization and genetic diversity analysis of <Emphasis Type="Italic">Jatropha curcas</Emphasis> L. in India using RAPD and AFLP analysis

Jatropha curcas L. belongs to family Euphorbiaceae, native to South America and widely distributed in South and Central America, attained significant importance for its seed oil which can be converted to biodiesel, a renewable energy source alternative to conventional petro-diesel. Very few attempts were made to understand the extent of genetic diversity that exists in J. curcas. Therefore, the present investigation was undertaken to asses the genetic diversity among 28 diverse germplasm collected from distinct geographical areas in India. The overall percentage of polymorphism (PP) was found to be 50.70 and 60.95 by RAPD and AFLP, respectively. The mean PP was found to be 9.72 and 20.57 by RAPD and AFLP, respectively. The mean genetic similarity was observed to be 0.89 by RAPD and 0.88 by AFLP. Among the germplasm JCI20 found to be the most diverged one. The dendrogram analysis of RAPD and AFLP data showed good congruence, but better resolution and more polymorphism was observed with AFLP. When the dendrogram of RAPD was compared with AFLP dendrogram, the major clustering pattern was found to be similar; however, changes in minor grouping were observed. In both RAPD and AFLP analysis clustering of germplasm did not show any correlation with the geographical area of collection. Low genetic diversity observed in J. curcas and the clustering pattern indicates that the distribution of species might have happened through anthropogenic activity and warrants the need for widening the genetic base. The present study will provide pavement for further intra-population studies on narrow geographical areas, to understand the population genetic structure, phylogeography, molecular ecological studies. The marker information and the characterized germplasm help in further improvement of the species through marker assisted breeding programs.     

A Comparison of AFLP and RAPD Markers for Genetic Diversity and Cultivar Identification in Cotton

AFLP and RAPDmarkers were employed in sixteen diploid cotton (Gossypium sp) cultivars for genetic diversity estimation and cultivar identification. Polymorphism information content (PIC) and percent polymorphism were found to be more for AFLP markers as compared to RAPD markers. Average Jaccard’s genetic similarity index was found to be almost similar using either AFLP or RAPD markers. All the cultivars could be distinguished from one another using AFLP markers and also by the combined RAPD profiles. Cultivar identification indicators like resolving power, marker index and probability of chance identity of two cultivars suggested the usefulness of AFLP markers over the RAPD markers. AFLP and RAPD analyses revealed limited genetic diversity in the studied cultivars. Cluster analysis of both RAPD and AFLP data produced two clusters, one containing cultivars of G. herbaceum and another containing cultivars of G. arboreum species. Highly positive correlation between cophenetic matrices using RAPD and AFLP markers was observed. AFLP markers were found to be more efficient for genetic diversity estimation, polymorphism detection and cultivar identification.