Occurrence of somaclonal variation among somatic embryo‐derived white spruces (Picea glauca, Pinaceae)

Isabel, Nathalie; Boivin, Rodolphe; Levasseur, Caroline; Charest, Pierre-M.; Bousquet, Jean; Tremblay, Francine

doi:10.1002/j.1537-2197.1996.tb13892.x

Cited by 34 publications

(13 citation statements)

References 51 publications

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“…Similar results were reported using the RAPD technique in Norway spruce (Fourré et al 1997), Japanese black pine (Goto et al 1998), Japanese white oak (Thakur et al 1999), loblolly pine (Tang 2001), almond (Martins et al 2004), hazelnut (Nas et al 2004, pedunculate oak (Valladares et al 2006), cork oak (Fernandes et al 2011), apricot (Soliman 2012), annatto (Siril and Joseph 2013), and seedless lemon (Goswami et al 2013). In contrast, RAPD analysis reported genetic variation in poplar (Ostry et al 1994;Rani et al 1995), white spruce (Isabel et al 1995(Isabel et al , 1996, peach (Hashmi et al 1997), teak (Gangopadhyay et al 2003), Idaho locust (Ngezahayo et al 2006), stone pine (Cuesta et al 2010), and olive (Leva et al 2012).…”

Section: Discussionsupporting

confidence: 67%

Screening RAPD primers to assess clonal fidelity in somatic embryos of Sawara cypress (Chamaecyparis pisifera Sieb. et Zucc.) and field performance of somatic embryo-derived trees

Hosoi

Kuramoto

Maruyama

2015

Plant Biotechnology

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In this study, 100 random amplified polymorphic DNA (RAPD) primers were screened to assess clonal fidelity in somatic embryos of Sawara cypress (Chamaecyparis pisifera Sieb. et Zucc.). Of the 100 primers tested, eight were selected based on their amplification products, which showed clear DNA fragmentation, generating 8.75 bands per primer in average. The amplification products showed no genetic variation among the tested somatic embryos. In addition, the performance of somatic embryo-derived trees was monitored in the field, and their mean height growth was measured until the age of 10 years. Although no phenotypic differences were observed, the somatic embryo-derived trees showed lower growth compared with seedlings.

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Section: Discussionsupporting

confidence: 67%

Screening RAPD primers to assess clonal fidelity in somatic embryos of Sawara cypress (Chamaecyparis pisifera Sieb. et Zucc.) and field performance of somatic embryo-derived trees

Hosoi

Kuramoto

Maruyama

2015

Plant Biotechnology

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“…We hypothesized that both procedures used could negatively affect the genetic stability of plant material. Several studies have reported somaclonal variation in embryonic cultures both after in vitro cultivation and after cryopreservation (Burg et al, 2007;DeVerno et al, 1999;Helmersson et al, 2008;Nawrot-Chorabik, 2009;Isabel et al, 1996;Krajňáková et al, 2011;Dey et al, 2015). In this study we report substantial genetic instability in SSR genotypes of the studied material as 52 different mutation events in total were detected.…”

Section: Discussionsupporting

confidence: 52%

Somaclonal Variation During Picea abies and P. omorika Somatic Embryogenesis and Cryopreservation

Hazubska-Przybył¹,

Dering²

2017

Acta Biologica Cracoviensia S. Botanica

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Embryogenic cultures of plants are exposed to various stress factors both in vitro and during cryostorage. In order to safely include the plant material obtained by somatic embryogenesis in combination with cryopreservation for breeding programs, it is necessary to monitor its genetic stability. The aim of the present study was the assessment of somaclonal variation in plant material obtained from embryogenic cultures of Picea abies (L.) Karst. and P. omorika (Pančić) Purk. maintained in vitro or stored in liquid nitrogen by the pregrowth-dehydration method. The analysis of genetic conformity with using microsatellite markers was performed on cotyledonary somatic embryos (CSE), germinating somatic embryos (GSE) and somatic seedlings (SS), obtained from tissues maintained in vitro or from recovered embryogenic tissues (ETc) and CSE obtained after cryopreservation. The analysis revealed changes in the DNA of somatic embryogenesis-derived plant material of both Picea spp. They were found in plant material from 8 out of 10 tested embryogenic lines of P. abies and in 10 out of 19 embryogenic lines of P. omorika after in vitro culture. Changes were also detected in plant material obtained after cryopreservation. Somaclonal variation was observed in ETc and CSE of P. omorika and at ETv stage of P. abies. However, most of the changes were induced at the stage of somatic embryogenesis initiation. These results confirm the need for monitoring the genetic stability of plants obtained by somatic embryogenesis and after cryopreservation for both spruce species.

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“…Somaclonal variation was also reported in somatic embryo-derived plants of conifers. Four P. glauca plants with variegata phenotypes were found among 2270 regenerated plants (Isabel et al, 1996). In this study, one out of 250 RAPD markers was correlated with the white needles of the variegated plants.…”

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confidence: 54%

Frequency of somaclonal variation in plants of black spruce (Picea mariana, Pinaceae) and white spruce (P. glauca, Pinaceae) derived from somatic embryogenesis and identification of some factors involved in genetic instability

Tremblay

Levasseur

Tremblay

1999

American J of Botany

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Plants of black spruce (Picea mariana, N = 7047 individuals) and white spruce (P. glauca, N = 3995 individuals) were regenerated from a total of 87 clones over a 5-yr period by somatic embryogenesis to study factors that might be associated with the appearance of variant phenotypes. Morphological evaluation of the plants showed several types of variation. These variations were grouped into nine types: dwarfism (type A), reduced height with various form anomalies (types B, C, and D), needle fasciation (type E), abnormality in tree architecture (type F), variegata phenotype (type G), and plants with an overall regular morphology but smaller than normal plants (type H). Plagiotropic plants were also observed (type I). Each plant from types A to H (except type C where no plants survived more than 6 mo) had retained its phenotype over 4-5 yr of growth. Some of the variant types could be related to chromosomic instability: chromosome counts showed aneuploid cells for type-A and type-D plants. The type I (plagiotropism) was not related to genetic instability but rather to physiological disorders. In total, spruce variants of types A-H were obtained at relatively low frequencies, i.e., 1.0% (39/3995) for white spruce and 1.6% (110/7047) for black spruce. Statistical analyses, conducted with family, clone, and time in maintenance as variables, showed that clone was the most important source of genetic instability followed by time in maintenance.

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Occurrence of somaclonal variation among somatic embryo‐derived white spruces (Picea glauca, Pinaceae)

Cited by 34 publications

References 51 publications

Screening RAPD primers to assess clonal fidelity in somatic embryos of Sawara cypress (<i>Chamaecyparis pisifera</i> Sieb. et Zucc.) and field performance of somatic embryo-derived trees

Screening RAPD primers to assess clonal fidelity in somatic embryos of Sawara cypress (<i>Chamaecyparis pisifera</i> Sieb. et Zucc.) and field performance of somatic embryo-derived trees

Somaclonal Variation During Picea abies and P. omorika Somatic Embryogenesis and Cryopreservation

Frequency of somaclonal variation in plants of black spruce (Picea mariana, Pinaceae) and white spruce (P. glauca, Pinaceae) derived from somatic embryogenesis and identification of some factors involved in genetic instability

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