In vitro Regeneration of Picralima nitida (Stapf). T. Durand & H. using Zygotic Embryo

Disinfected mature seed embryos of Picralima nitida, were cultured in MS medium supplemented with different concentrations and combinations of 2,4-D, BAP and NAA to determine an efficient protocol for in vitro propagation. Nine culture media made of combination of different components were used in a factorial design with three replications. Results showed up to 80 ± 4% disinfection rate with combination of triton x- 100 (0.2%) and sodium hypochlorite (30%). Embryo germination was highest on control medium. Rooting was higher (2±1 roots per embryo) after 4 weeks on control medium and on BAP supplemented medium at 0.8 μM while the longest root (1.5±0.5 cm) was observed on 2,4-D supplemented medium at 1.8 μM. Black soil was suitable for leaf formation (4 ± 2 leaves) and shoot elongation (2±1 cm) after 8 weeks in acclimatisation. These results show efficient disinfection, regeneration and acclimatisation of Picralima nitida. Plant Tissue Cult. & Biotech. 31(2): 143-151, 2021 (December)

Standardization of zygotic embryo culture from Nerium oleander L. and comparative analysis of biosynthesized cardiac glycosides within in vitro and acclimatized plants

The primary result of our experiment revealed that the germination percentage of N. oleander mature seeds is only 30%. From this observation, the concept of protocol standardization for zygotic embryo culture of this plant was originated. Zygotic embryo culture was proved an efficient in vitro multiplication system of N. oleander. The maximum germination percentage (96%) of zygotic embryos was observed on ¼ MS medium with 15 gm/L sucrose, whereas the best growth medium was optimized as ½ B5 with same sucrose concentration. The second part of this study was aimed to find out the cardiac glycoside accumulation pattern in both in vitro and acclimatized plants. For this purpose, one-month-old in vitro plantlets and acclimatized plants were subjected to LC-MS analysis and 09 cardiac glycosides were detected and quantified in both the systems. Most of the cardiac glycosides including odoroside A (32.71 mg/gm DW), odoroside H (4.69 mg/gm DW) and oleandrin (0.52 mg/gm DW) were found to be accumulated at maximum level within in vitro plantlets. CG 840b (1.89 mg/gm DW) is the only cardiac glycoside, which was maximally accumulated in acclimatized plants. From this study, it can be concluded that, zygotic embryo culture is a better choice for in vitro multiplication of N. oleander when compared to matured seeds and in vitro grown plantlets of this species favor cardiac glycosides biosynthesis in comparison to acclimatized plants. Therefore, all future research on the enrichment of cardiac glycosides from this plant may be conducted on zygotic embryos derived in vitro grown plantlets or cultures.

Regeneration potential of different explants during micropropagation of neem tree (Azadirachta indica A. Juss.)

Azadirachta indica A. Juss., (Neem), a prodigious multipurpose tree, has immense potential to benefit mankind and to protect the environment. In order to investigate the effects of three different explants for its regeneration potential, de embryonated cotyledon, immature zygotic embryo and nodal segments from a 30 year old neem plus tree were used. Half strength MS medium with benzyl amino purine (3 mg/L) and naphthalene acetic acid (0.5 mg/L) and casein hydrolysate (1 g/L) was effective in shoot bud sprouting from both nodes and cotyledons. Half strength MS medium fortified with TDZ (0.2 mg/L) was effective for induction of somatic embryogenesis from zygotic embryos. Shoot buds initiated from the cotyledons produced a maximum number of shoots per explants (4.33) which on further sub culturing induced maximum multiple shoots (15) on half strength MS medium fortified with BAP (1.5 mg/L), NAA (0.5 mg/L) and CH (400 g /L) and the nodal explants induced only 4-5 axillary shoots on further sub culturing. Even though immature zygotic embryos produced more number of somatic embryos per explant (24.97) within a short time (30-45 days), the plantlet conversion was poor (25.52 %). In vitro rooting was observed in half strength MS medium supplemented with IBA (2 mg/L). The regeneration potential of de embryonated cotyledons through a simple regeneration system may be beneficial for efficient mass propagation of selected plus trees of neem.

Reproductive Characteristics of the Selected Cocoa (Theobroma cacao L.) Clones after Regenerated from the Somatic Embryogenesis Culture

This study was conducted to evaluate the reproductive characteristics of 4 elite cocoa clones (MCBC1, PBC230, KKM22 and KKM4) propagated via somatic embryogenesis culture. From the findings, all clones have similar reproductive characteristics with clones from conventional grafted. However, only KKM4 clone from immature zygotic embryo culture produced the shortest staminode to style distance of 1.83 mm. This consequently influenced flower stability by reducing the efficiency of pollination by insects. It was found that this clone also has the highest number of flowers drop after anthesis (5 flowers) and lowest production of cherelle (5 cherelles). Further observation revealed that floral development from first bud visible (BBCH51) to flower anthesis (BBCH68) of all clones took around 31 days. These cocoa flowers which remained receptive soon after anthesis at 10 am (day-31) until the next day (day-32) suggesting 2 days’ period of receptivity. HIGHLIGHTS It is crucial to assess the presence of off-type characteristics in the reproductive organ structure such as the distance between staminode to style, period of reproductive cycle and stigmatic receptivity of cocoa clones regenerated from somatic embryogenesis The converging and parallel type of staminode to style distances are the ideal flower spatial arrangements for the optimal pollination in cocoa plant compared to splay type Only KKM4 clone propagated from immature zygotic embryo culture showed variation in the distance between staminode to style distance and this caused pollination failure by insect which then consequently caused minimum cherelle production All regenerated cocoa clones observed with typical period of the reproductive cycle and stigmatic receptivity GRAPHICAL ABSTRACT

Transcriptomic Time-Series Analyses of Gene Expression Profile During Zygotic Embryo Development in Picea mongolica

Zygotic embryogenesis is a critical process during seed development in gymnosperms. However, knowledge on the genome-wide transcriptional activation that guides this process in conifers is limited, especially in Picea mongolica. This tree species is endemic to semiarid habitats of Inner Mongolia in China. To extend what is known about the molecular events underpinning its zygotic embryogenesis, comparative transcriptomic analyses of gene expression in zygotic embryos were performed by RNA sequencing in P. mongolica. Our results showed that most changes in transcript levels occurred in the early embryonic pattering determination and formation of mature embryos. Transcripts related to embryogenic competence, cell division pattern, hormones, and stress response genes were identified during embryogenesis. Auxin is essential for early embryo patterning and pre-cotyledon embryonic formation. However, ABA is a major regulator of embryo maturation. Moreover, we found that methylation-related gene expression is associated with activation of early-stage embryos, late embryogenesis abundant proteins, and storage/energy-related genes with late and mature embryos. Furthermore, network analysis revealed stage-specific and multistage gene expression clusters during embryogenesis. WOX, MYB, AP2, and HLH transcription factors seem more relevant to embryogenesis in different stages. Our results provide large-scale and comprehensive transcriptome data for embryo development in P. mongolica. These data will lay a foundation for the protection and utilization of P. mongolica resources.

Plant regeneration and transformation of Trachyspermum ammi using Agrobacterium tumefaciens and zygotic embryos

Background Trachyspermum ammi is one of the key medicinal plant species with many beneficial properties. Thymol is the most important substance in the essential oil of this plant. Thymol is a natural monoterpene phenol with high anti-microbial, anti-bacterial, and anti-oxidant properties. Thymol in the latest research has a significant impact on slowing the progression of cancer cells in human. In this research, embryos were employed as convenient explants for the fast and effectual regeneration and transformation of T. ammi. To regenerate this plant, Murashige and Skoog (MS) and Gamborg's B5 (B5) media were supplemented with diverse concentrations of plant growth regulators, such as 6-benzyladenine (BA), 1-naphthaleneacetic acid (NAA), 2,4-dichlorophenoxyacetic acid (2,4-D), and kinetin (kin). Transgenic Trachyspermum ammi plants were also obtained using Agrobacterium-mediated transformation and zygotic embryos explants. Moreover, two Agrobacterium tumefaciens strains (EHA101 and LBA4404) harboring pBI121-TPS2 were utilized for genetic transformation to Trachyspermum ammi. Results According to the obtained results, the highest plant-regeneration frequency was obtained with B5 medium supplemented with 0.5 mg/l BA and 1 mg/l NAA. The integrated gene was also approved using the PCR reaction and the Southern blot method. Results also showed that the EHA101 strain outperformed another strain in inoculation time (30 s) and co-cultivation period (1 day) (transformation efficiency 19.29%). Furthermore, HPLC method demonstrated that the transformed plants contained a higher thymol level than non-transformed plants. Conclusions In this research, a fast protocol was introduced for the regeneration and transformation of Trachyspermum ammi, using zygotic embryo explants in 25–35 days. Our findings confirmed the increase in the thymol in the aerial part of Trachyspermum ammi. We further presented an efficacious technique for enhancing thymol content in Trachyspermum ammi using Agrobacterium-mediated plant transformation system that can be beneficial in genetic transformation and other plant biotechnology techniques.

Investigation of genes involved in somatic embryogenesis and plant-Agrobacterium interactions through transcriptional profiling

Plant genetic engineering relies on the ability to transmit and express cloned DNA sequences in plant cells (transformation) as well as the capacity for the cells carrying this DNA to undergo division and differentiation (regeneration), eventually giving rise to a mature whole plant. The breadth of application for genetic engineering is limited by constraints on one or both of these factors in many plant species and individual varieties. Uncovering plant genes which are involved in important aspects of either component can inform the development of technologies that serve to enable or improve the efficiency of genetic modification methods. The most commonly employed method of delivering exogenous genetic material into plant cells is via disarmed strains of the plant pathogen Agrobacterium tumefaciens. Somatic embryogenesis is a frequently applied mode of plant regeneration following DNA delivery, especially in major cereal crops such as maize, rice, and sorghum. In the work reported here, whole transcriptome sequencing (RNA-seq) was used in two different experiments to capture transcriptional dynamics throughout early somatic embryogenesis in immature zygotic embryo tissue of the major crop plant sorghum (Sorghum bicolor), and throughout early times following host plant inoculation with A. tumefaciens in seedlings of the model plant Arabidopsis thaliana (Chapters 2 and 3, respectively). In both cases, differential expression analysis revealed many genes which were induced either during somatic embryogenesis or in response to inoculation with either virulent or avirulent A. tumefaciens strains. Several of these genes were highlighted as candidates for future study into their potential role in the respective processes. Multiple candidate genes were functionally tested, using transgenic methods, for the possibility of having a role in the regulation of somatic embryogenesis in sorghum (Chapter 4). These experiments failed to confirm an influence over the process for all candidate genes that were evaluated. The experimental work documented herein contributes to a growing body of literature documenting plant genes which could serve as possible targets for techniques that work to enhance the utility of biotechnological methods for improving traits in plants.

Embryo Culture and Embryo Rescue in Brassica

Somatic embryogenesis is the best demonstration of totipotency in higher plants in which somatic cell produce whole plant like zygotic embryo. It is also demonstrated that immature, weak, hybrid or sometimes inviable embryos can be saved through in vitro culture to prevents its degradation. It may help to cross the reproductive barriers when interspecific hybrids developed. Brasssica is an economically valuable oil yielding and vegetable crop and India is the largest producer of oil seed rape in the world. Various factors affect the embryo rescue in Brassica like growth stage of the embryos, types and composition of the rescue medium etc. The embryo regeneration potential can improve through the modification of culture conditions in both zygotic as well as somatic embryo. Except the embryo culture other parts like ovule, ovary culture can also be done to developed interspecific hybrids. This chapter is focused on the embryo rescue techniques in the genus Brassica and summarizes possible ways of improving the technique used.