Competence For Somatic Embryogenesis Research Articles

MiR171 modulates induction of somatic embryogenesis in citrus callus.

Overexpression of miR171 restored SE competence in the recalcitrant citrus callus, and inhibition of miR171 function weakened SE competence in the strongly embryogenic citrus callus. Somatic embryogenesis (SE) is an important way of in vitro regeneration for plants. For perennial woody crops such as citrus, embryogenic callus is usually induced from unfertilized aborted ovules and widely used in biotechnology aided breeding. However, SE capacity always declines in callus during subculture, which makes regeneration difficult and hinders the application of biotechnology. We previously found that miR171 may be a regulator of SE in citrus, based on the abundant expression of csi-miR171c in the embryogenic callus and during SE of citrus. Here, we report that miR171 promotes SE and is required for SE in citrus. Overexpression of miR171 restored SE competence in the recalcitrant callus of 'Guoqing No.1' Satsuma mandarin (G1), whereas inhibition of miR171 function by Short Tandem Target Mimic (STTM) weakened SE competence in the strongly embryogenic callus of 'Valencia' sweet orange (V). The comparative transcriptomic analysis in miR171 overexpressed callus line (OE) and the wild type callus (WT) indicated that overexpression of miR171 decreased the expression level of its SCARECROW-LIKE (CsSCL) targets, and activated stress response related biological processes and metabolic processes that are required for cell differentiation. However, CsSCLs were up-regulated in the OE callus during SE induction process, which activated the cell division and developmental processes that are required for embryogenesis progress. Our results validate the function of miR171 in regulation of SE and reveal the biological responses provoked by miR171 in citrus that may promote SE.

MiR156-SPL modules regulate induction of somatic embryogenesis in citrus callus.

miR156 is a highly conserved plant miRNA and has been extensively studied because of its versatile roles in plant development. Here, we report a novel role of miR156 in regulating somatic embryogenesis (SE) in citrus, one of the most widely cultivated fruit crops in the world. SE is an important means of in vitro regeneration, but over the course of long-term sub-culturing there is always a decline in the SE potential of the preserved citrus embryogenic callus, and this represents a key obstacle for citrus biotechnology. In this study, the SE competence of citrus callus of wild kumquat (Fortunella hindsii) was significantly enhanced by either overexpression of csi-miR156a or by individual knock-down of the two target genes, CsSPL3 and CsSPL14, indicating that the effect of miR156-SPL modules was established during the initial phases of SE induction. Biological processes that might promote SE in response to miR156 overexpression were explored using RNA-seq, and mainly included hormone signaling pathways, stress responses, DNA methylation, and the cell cycle. CsAKIN10 was identified as interacting protein of CsSPL14. Our results provide insights into the regulatory pathway through which miR156-SPL modules enhance the SE potential of citrus callus, and provide a theoretical basis for improvement of plant SE competence.

Transcriptional profiling of genes involved in embryogenic, non-embryogenic calluses and somatic embryogenesis of Valencia sweet orange by SSH-based microarray

Somatic embryogenesis (SE) is a most promising technology that is used for in vitro germplasm conservation and genetic improvement via biotechnological approaches in citrus. Herein, three suppression subtractive hybridization (SSH) libraries were constructed using calluses of Citrus sinensis cv. 'Valencia' to explore the molecular mechanisms that underlie the SE in citrus. A total of 880 unisequences were identified by microarray screening based on these three SSH libraries. Gene ontology analysis of the differentially expressed genes indicated that nucleolus associated regulation and biogenesis processes, hormone signal transduction, and stress factors might be involved in SE. Transcription factors might also play an important role. LEC1/B3 domain regulatory network genes (LEC1, L1L, FUS3, ABI3, and ABI5) were isolated in citrus SE. Some new transcription factors associated with citrus SE, like a B3 domain containing gene and HB4, were identified. To understand the influence of these isolated genes on SE competence, their expression profiles were compared among callus lines of seven citrus cultivars with different SE competence. The expression dynamics suggested that these genes could be necessary for the SE initiation and might play a role in embryogenic competence maintenance in different cultivars. On the basis of gene expression profiles, an overview of major physiological and biosynthesis processes at different developmental stages during citrus SE is presented. For the first time, these data provide a global resource for transcriptional events important for SE in citrus, and the specific genes offer new information for further investigation on citrus SE maintenance and development.

Cell morphometry and osmolarity as early indicators of the onset of embryogenesis from cell suspension cultures of grain legumes and model systems

Whatever the in vitro regeneration pathway, it would be of interest to be able to distinguish regeneration-competent from non-regenerating cells and tissues, and as early in culture as possible, as this would allow a dramatic improvement of biotechnology breeding, particularly for the so-called recalcitrant species. With this aim, we examined a range of genotypes of pea (Pisum sativum) and grass pea (Lathyrus sativus), and of the two model species Medicago truncatula, another legume, and Arabidopsis thaliana. This was done by comparing cell suspension cultures of different ages (young [<6 transfers-old]vs. mature [>6 transfers-old]), densities (dense [>107 cells/ml] or sparse [<106 cells/ml]) and regeneration abilities (non-embryogenic vs. embryogenic), in order to identify early indicators of competence for somatic embryogenesis. All such cell suspensions were subcultured every 14 days and several parameters were assessed every 3–4 days during each 14-day cycle. These included the time course pH and osmolarity of the culture medium, the internal osmolarity of cells, the cell surface and the cell wall thickness (by examining cellulose accumulation in Calcofluor White-stained cells under UV light). As cells underwent embryogenesis they enlarged. Cellulose accumulated in the walls of non-embryogenic cells, but walls became thinner with the onset of embryogenesis, and diminished further as embryos matured. Although medium osmolarity decreased at the onset of embryogenesis, this was never observed for non-embryogenic cell suspensions. Conversely, there was a concomitant increase in intracellular osmolarity for embryogenic cells. Medium pH (analysed with the model species only) was not significantly correlated with regeneration competence of cells. For all genotypes and species, the kinetics of cell wall thickness and cell surface, and that of medium and cell osmolarity were reliable early indicators of the competence of cells to undergo somatic embryogenesis. The implication of these results for biotechnological breeding of grain legumes and for plant regeneration competence in general are discussed.

Factors affecting maintenance, proliferation, and germination of secondary somatic embryos of Eucalyptus globulus Labill

The described protocol for repetitive somatic embryogenesis (SE) in Eucalyptus globulus produced more somatic embryos than the primary SE protocol. Primary somatic embryos (induced on MS3NAA) were transferred to the same medium, leading to new cycles of somatic embryos, for at least 2 years. The influence of medium (MS and B5), plant growth regulators (auxins and cytokinins), and light on secondary SE was tested. The MS medium without growth regulators (MSWH) was more efficient for cotyledonary embryo formation and germination than the B5 medium. Reducing auxin (NAA) levels increased the proliferation of globular somatic embryos and allowed SE competence to be maintained on medium free of plant growth regulators. The addition of two cytokinins (BAP and KIN) to the MS medium did not improve proliferation of globular secondary embryos, but was crucial during later stages of the SE process (germination and conversion). Data also show that light may influence the quality of the process, depending on its stage. Darkness should be maintained until the cotyledonary stage is reached, after which exposure to light is recommended.

English

A protocol of plant regeneration through direct somatic embryogenesis was established for the first time on Vinca herbacea using immature seed explants. Frequency of embryogenesis was significantly influenced by size of the seeds and growth regulators supplemented to the medium. Seeds isolated from the immature fruits between 15 and 20 days after flowering were superior in the induction of somatic embryos. Only 35% of seeds induced somatic embryos. Somatic embryos developed best on N2 medium with 0.5 mg l-1 2,4-D and 0.5 mg l-1 Kin. An increase in competence for somatic embryogenesis was found with the cotyledons, while the hypocotyls part completely lost their competence. The minor seeds never initiated somatic embryo, even after 2 months of culture. Somatic embryo formation principally occurred with the major seeds. Maturation embryos developed into plantlets at a frequency of 100% when planted in free MS medium for a further 5 - 6 week period. After 5 or 6 weeks, plantlets developed in small plants. The growth rates, genotype and morphological characteristics of plantlets were different but 55% of the embryos have normal shape and 45% were abnormal.

High frequency somatic embryogenesis and plant regeneration in root explant cultures of carnation

Root explants excised from carnation plants maintained in vitro formed off-white, friable calluses after three weeks of culture on Murashige and Skoog (MS) medium supplemented with 1 mg l−1 thidiazuron (TDZ) and 1 mg l−1 α-naphthalaneacetic acid (NAA). These calluses were subsequently transferred to MS basal medium where, after an additional four weeks of culture, approximately 50% of the calluses formed somatic embryos. However, calluses formed on root explants that had been cultured on MS medium supplemented with 2,4-dichlorophenoxyacetic acid did not produce somatic embryos upon transfer to MS basal medium. Somatic embryos developed into plantlets and subsequently were grown to maturity. These results indicate that root explants have a high competence for somatic embryogenesis in carnation.

Genetic improvement of the somatic embryogenesis and regeneration in soybean and transformation of the improved breeding lines

Somatic embryos of soybean [Glycine max (L.) Merrill] have been used to generate transgenic plants by particle bombardment. The induction and proliferation of somatic embryos from immature cotyledons are dependent on the genotype of the cultivar. Whereas somatic embryogenesis and plant regeneration are inefficient in most cultivars, they are efficient in the cultivar Jack. We previously established a breeding line, QF2, by the integration of null mutations of each subunit of the major seed storage proteins glycinin and beta-conglycinin, but the embryogenic response of this line is insufficient to allow efficient transformation. We have now backcrossed QF2 to cultivar Jack in order to combine the null traits with competence for somatic embryogenesis. The backcrossed breeding lines selected on the basis of the absence of the major storage proteins exhibited an improved capacity for the induction and proliferation of somatic embryos compared with that of QF2. The induced somatic embryogenic tissue of these breeding lines was successfully used for the production of transgenic plants by particle bombardment. These results also indicate that somatic embryogenesis in soybean is genetically controlled and inherited in a manner independent of the null traits of the major seed storage proteins.

Relationship Between Ploidy Variation of Citrus Calli and Competence for Somatic Embryogenesis

This study focuses on the relationship between the genetic variation of calli and the competence for somatic embryogenesis in citrus. The DNA content of 35 citrus calli of different genotypes was measured three times by flow cytometry during a period of four years. The results showed that 71.4% of the genotypes had a progressive increase of varied cells, while those of Page tangelo, Shamouti sweet orange, Russ navel orange and Cleopatra decreased; significant difference in the variation degree (percentages) existed among genotypes. Studies carried out on the induction of somatic embryogenesis revealed that 9 out of the 35 genotypes had still kept the competence of somatic embryogenesis, and the rest 26 had lost the competence. Correlation analysis indicated that there was no significant relationship between the variation degree and the embryogenesis competence r=−0.10 ( P<0.01), neither for the relationship between the subculture duration and the regeneration capacity.

Changes in competence for somatic embryogenesis in Norway spruce zygotic embryo segments

Embryogenic capacity of Norway spruce zygotic embryo sections was drastically altered by a preinduction transfer to hormone-free medium for 7 or 14 days. An increase in competence for somatic embryogenesis was found with the cotyledons, while the hypocotyl sections completely lost their competence. These changes in competence were not dependent on physical contact between plant sections, and could not be correlated to the developmental stage of each section. The increase of competence in cotyledonary material was due not only to an increase of genotypes initiating somatic embryos, but also to an increase in embryogenicity of cotyledons.

Changes in endogenous polyamines during the formation of somatic embryos from isogenic lines of Dactylis glomerata L. with different regenerative capacities

The endogenous levels of polyamines (PAs) in leaf-base explants isolated from plants of two isogenic lines of Dactylis glomerata L., differing in their competence for somatic embryogenesis, were compared. Leaf-bases isolated from plants with a high level of competence for somatic embryogenesis (HEC) contained four times the level of polyamines compared to those isolated from plants with a low level of competence for somatic embryogenesis (LEC). When the levels of individual polyamines in the HEC and LEC lines were compared, leaf-bases from plants of the HEC line had much lower PUT/SPD ratios than those from the LEC line. When changes in the levels of PAs were monitored during the first 28 d of culture, on a medium which promotes initiation of somatic embryogenesis, leaf-base cultures from plants of the HEC line showed a 50% increase in the levels of PAs during the first 7 d of culture, after which time levels began to decline. By day 21, levels had dropped below those found in freshly isolated leaf bases. While PUT and SPM levels increased by about 30%, the greatest increase was shown by SPD, which increased by more than 100% during the first 7 d of culture, before declining. In contrast much smaller changes in PA levels were found when leaf-bases from plants of the LEC line were cultured.

Transient expression of a reporter gene changes significantly during somatic embryogenesis in alfalfa

Transient expression of the β -glucuronidase (GUS) gene driven by a 35S constitutive promoter was investigated during somatic embryo development in alfalfa (Medicago sativa L.) following micro-projectile bombardment. The level of gene expression varied with the different developmental stages and changed dramatically within the stages. During embryogenic callus induction (stage I), expression was low in explants freshly transferred to culture, but increased when cells started to divide and show competence for somatic embryogenesis. Gene expression, however, decreased when extensive callus formation began and reached the lowest observed level when callus was fully developed. Reporter gene expression was consistently low during embryogenic cell proliferation (stage II). In contrast, high levels of reporter gene expression were detected in non-embryogenic suspension cultures during cell proliferation. Extremely low reporter gene expression was detected in embryonal tissues and young embryos at the embryo development and maturation stage (stage III). Expression increased as the somatic embryos developed and reached the highest level when the embryos reached maturity. Transient expression levels were similar in excised petiole tissue across 10 alfalfa genotypes, which included both diploid and tetraploid genotypes. In general, reporter gene expression was found to be higher in more organised mature tissues and organs than in less-organised or young tissues. The developmental status of the cells and tissues appears to be an important factor in the degree of transient expression of the introduced gene. Changes of gene expression during embryogenesis and factors affecting gene expression are discussed. Key words: GUS expression, Medicago sativa, bombardment, forage

Flow cytometric analyses in embryogenic and non-embryogenic callus lines of Cyclamen persicum Mill.: relation between ploidy level and competence for somatic embryogenesis.

Embryogenic and non-embryogenic callus lines derived from the same diploid Cyclamen persicum genotype (`Purple Flamed') were analyzed by flow cytometry and compared to the initial plant material. The DNA content of the diploid plant in the greenhouse was 1.12 pg DNA/2C as estimated in relation to the internal standards tomato nuclei and chicken erythrocytes. In both callus lines the majority of cells contained the same amount of DNA as the initial plant, indicating that no polyploidization has taken place after 5 years of culture on medium containing 2.0 mg/l 2,4-dichlorophenoxyacetic acid (2,4-D) and 0.8 mg/l 6-(γ-γ-dimethylallylamino)purine(zip). Thus, our data suggest that in Cyclamen callus lines there was no strict correlation between the ploidy level and the ability to produce somatic embryos. Furthermore, following the proportion of cells in the three phases of the cell cycle (G0/G1, S, G2/M) during one subculture period of 4 weeks revealed high division activity within the first 2 weeks for both callus lines cultured on the 2,4-D-containing medium. However, when transferred to hormone-free medium, the division activity of the embryogenic cell line decreased markedly, corresponding to the differentiation of somatic embryos. In contrast, for the non-embryogenic callus an increase in cells in the G2/M phase was observed.

Characterization of immature embryos of interior spruce by SDS-PAGE and microscopy in relation to their competence for somatic embryogenesis

SDS-PAGE analysis of total proteins from cotyledonary embryo explants reveals that their competence to form somatic embryos is limited to a specific stage of development prior to the accumulation of storage proteins. When protein profiles of embryo explants of different open pollinated families from the same collection date are compared, there is a close relationship between the absence of storage proteins and their ability to produce embryogenic callus. In addition, the appearance of storage proteins in embryos from subsequent collections is associated with their loss of competence. Light microscopy combined with staining for total protein demonstrates that competent immature embryos have cotyledons but do not contain protein bodies.