Morphological and RAPD-marker characterization of Melia volkensii (Grke) in vitro plants regenerated via direct and indirect somatic embryogenesis

Mulanda, Eliud Sagwa; Chuhila, Yeremia; Awori, Ryan Musumba; Adero, Mark Ochieng; Amugune, Nelson Onzere; Akunda, E.; Kinyamario, JI

doi:10.5897/ajb2014.14372

Cited by 5 publications

(6 citation statements)

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“…Therefore, the early indicators for the existence of somaclonal variation are important to commercial plant growers. Fortunately, some of the observed phenotypic variants among the regenerated plantlets in tissue culture propagated planting materials are controlled by epigenetics (Miguel and Marum 2011;Mulanda et al 2015;Park et al 2009;Smulders and Klerk 2011;Us-Camas et al 2014). We found some phenotypic variations such as leaf shape and leaf apex shape in the plantlet from irradiated protocorm in the present results.…”

Section: Discussionsupporting

confidence: 56%

“…Somaclonal variation may be undesirable in micropropagation through in vitro techniques (Hammerschlag et al 1992;Taylor et al 1995;Biswas et al 2009;Miguel and Marum 2011;Mulanda et al 2015;Park et al 2009;Smulders and Klerk 2011;Us-Camas et al 2014). Therefore, the early indicators for the existence of somaclonal variation are important to commercial plant growers.…”

Section: Discussionmentioning

confidence: 99%

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Morphological, molecular and resistance responses to soft-rot disease variability among plantlets of Phalaenopsis amabilis regenerated from irradiated protocorms

et al. 2021

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Abstract. Putri HA, Purwito A, Sudarsono, Sukma D. 2021. Morphological, molecular and resistance responses to soft-rot disease variability among plantlets of Phalaenopsis amabilis regenerated from irradiated protocorms. Biodiversitas 22: 1077-1090. Phalaenopsis amabilis (L.) Blume is a prominent donor for the white petal and sepal trait in Phalaenopsis breeding. However, it has an undesirable character, such as susceptible to soft-rot disease. Therefore, developing soft-rot resistance mutants through gamma irradiation could be explored. This study aimed to evaluate the variability of plantlets regenerated from irradiated and non-irradiated protocorms using morphology, stomatal size and molecular markers and to test responses of the plantlets against soft-rot disease. The plantlets were regenerated from irradiated (5, 10, 15 or 20 Gy) and non-irradiated protocorms. The results showed that P. amabilis plantlet variants were successfully identified based on their leaf morphology and stomatal size variations. A few plantlets have low stomatal densities, large stomatal size, and high chloroplast numbers, which indicated they were polyploids. Leaf disc assay for soft-rot disease response grouped most of the plantlets into very susceptible or susceptible. Moreover, four soft-rot resistant plantlets regenerated from irradiated and non-irradiated protocorms were successfully identified. The resistant plantlets were identified after three consecutive periods of inoculations with pathogens causing soft-rot disease. The evaluation also confirmed nucleotide variation in the Pto gene isolated from different levels of plantlet variant resistance responses.

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Section: Discussionsupporting

confidence: 56%

Section: Discussionmentioning

confidence: 99%

Morphological, molecular and resistance responses to soft-rot disease variability among plantlets of Phalaenopsis amabilis regenerated from irradiated protocorms

et al. 2021

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“…In addition, the plant material should be analyzed at the genetic level to identify changes in DNA sequence. However, as changes in the regenerant genome may also occur following changes in the level of DNA methylation, these should also be confirmed using methylation-sensitive markers [15,21,34,35].…”

Section: Discussionmentioning

confidence: 99%

“…Sample purification was performed by solid phase extraction (SPE) according to the method presented by [35]. Chromabond SB (Macherey-Nagel, Düren, Germany) polypropylene columns with a bed weight of 500 mg and a capacity of 6 mL were used.…”

Section: Purification Of the Ether Extract By Spe Methodsmentioning

confidence: 99%

Comparative Study of the Genetic and Biochemical Variability of Polyscias filicifolia (Araliaceae) Regenerants Obtained by Indirect and Direct Somatic Embryogenesis as a Source of Triterpenes

Śliwińska

Białek

Orłowska

et al. 2021

IJMS

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Polyscias filicifolia (Araliaceae) is broadly used in traditional medicine in Southeast Asia due to its antimicrobial, immunomodulating and cytotoxic activities. The main groups of compounds responsible for pharmacological effects are believed to be oleanolic triterpene saponins. However, Polyscias plants demonstrate relatively slow growth in natural conditions, which led to applying a developing sustainable source of plant material via primary (PSE), secondary (DSE) and direct somatic embryogenesis from DSE (TSE). The AFLP and metAFLP genotyping resulted in 1277 markers, amplified by a total of 24 pairs of selective primers. Only 3.13% of the markers were polymorphic. The analysis of variance showed that the PSE and TSE regenerants differed only in terms of root number, while the DSE plantlets differed for all studied morphological characteristics. Further, the chemical analysis revealed that oleanolic acid (439.72 µg/g DW), ursolic acid (111.85 µg/g DW) and hederagenin (19.07 µg/g DW) were determined in TSE regenerants. Our results indicate that direct somatic embryogenesis ensures the production of homogeneous plant material, which can serve as a potential source of triterpene compounds. Plants obtained via somatic embryogenesis could also be reintroduced into the natural environment to protect and preserve its biodiversity.

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“…No obstante, De Oliveira et al (2015) en Carapa guianensis plantean una elevada frecuencia caulogénica (sin indicar el porcentaje) empleando de 1-10 mg.L -1 de 2,-4-D con 1.1 mg.L -1 de BAP. En el caso de los cotiledones, el desarrollo de callos regenerativos que se describe en su mayoría es de tipo embriogénico, así, en el caso del callo caulogénico o con brotes, se induce entre un 87 y 100 % con 1.1 mg.L -1 de BAP y 1 mg.L -1 ANA en Cedrela fissilis (Nunes et al, 2002), mientras que el callo nodular compacto o embriogénico se desarrolla en un 80 % utilizando 3 mg.L -1 de 2,4-D con 3 mg.L -1 ANA en Melia azedarach (Deb, 2001) y con solo 0.05 a 1 mg.L -1 de tidiazuron en Melia volkensii (Mulanda et al, 2014;Mulanda et al, 2015), potenciándose el desarrollo de callo con embriones somáticos secundarios en un 68 % con 1.6 mg.L -1 de TDZ en Semecarpus anacardium (Panda y Hazea, 2012) o 61 % con 0.7 mg.L -1 de ANA en Sorbus pohuashanensis (Yang et al, 2012). Por último, en secciones nodales o esquejes se desarrollaron 85% de callos con brotes con solo 0.5 mg.L -1 de BAP en Melia dubia (Ram et al, 2014).…”

Section: Discusión Proceso De Inducción De Callounclassified

Evaluación de un sistema de regeneración por embriogénesis somática de Neem (Azadirachta indica)

et al. 2016

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RESUMENAzadirachta indica, también conocida como neem, es una especie arbórea leñosa perteneciente a la familia Meliaceae, de gran importancia en diversas disciplinas científicas, tales como la forestal y la médico-farmacéutica. Se estableció un método para la propagación in vitro de esta planta, evaluándose como explantes, secciones foliares de vitro-plantas, cotiledones y esquejes. Se emplearon medios semisólidos con combinaciones variables de la citocinina 6-benzylaminopurina (BAP) y las auxinas ácido 2,4-diclorofenoxiacético (2,4-D) y ácido indolacético (AIA). Se observó la formación de callo regenerativo, a partir del cual se generó embriogénesis somática primaria y secundaria, mediante los reguladores de crecimiento BAP (1,0 mg.L ), mientras que la formación de callo no regenerativo fue promovida por concentraciones mayores a 0,3 mg.L -1 de 2,4-D. De los explantes evaluados, la mayor frecuencia de regeneración de plantas (~67 %) se presentó con secciones cotiledonares.Palabras clave: cotiledones, embriogénesis somática secundaria, hoja. ABSTRACTAzadirachta indica, also known as neem, is a woody tree species belonging to the Meliaceae family, of great importance in various scientific disciplines, such as forestry, medicinal and pharmacist. It was established a method for in vitro propagation of this plant, evaluating explants as leaf sections of vitro-plants, cotyledons and stem cuttings, using semi-solid medium with various combinations of cytokinin 6-benzylaminopurine (BAP) and auxins 2,4-dicholorophenoxyacetic acid (2,4-D) and indol-3-acetic acid (IAA). Regenerative callus formation was observed, from which primary and secondary somatic embryogenesis was generated by growth regulators BAP (1.0 mg.L ), whereas non-regenerative callus formation was promoted by concentrations higher than 0,3 mg.L -1 of 2,4-D. Between the used explants, the highest frequency of plant regeneration (~ 67%) presented from cotyledon sections.

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Morphological and RAPD-marker characterization of Melia volkensii (Grke) in vitro plants regenerated via direct and indirect somatic embryogenesis

Cited by 5 publications

References 38 publications

Morphological, molecular and resistance responses to soft-rot disease variability among plantlets of Phalaenopsis amabilis regenerated from irradiated protocorms

Morphological, molecular and resistance responses to soft-rot disease variability among plantlets of Phalaenopsis amabilis regenerated from irradiated protocorms

Comparative Study of the Genetic and Biochemical Variability of Polyscias filicifolia (Araliaceae) Regenerants Obtained by Indirect and Direct Somatic Embryogenesis as a Source of Triterpenes

Evaluación de un sistema de regeneración por embriogénesis somática de Neem (Azadirachta indica)

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