Tracking dynamics of enzyme activities and their gene expression in <Emphasis Type="Italic">Picrorhiza kurroa</Emphasis> with respect to picroside accumulation

Picrosides, the terpenoids synthesized by Picrorhiza kurroa, have ample usage in medicine. Identification of the regulatory enzymes involved in picroside biosynthesis needs to be explored for improving the level of these secondary metabolites. Current efforts are based on the analysis of secondary metabolism in picroside biosynthesis but its interpretation is limited by the lack of information on the involvement of primary metabolic pathways. The present study investigated the connection of primary metabolic enzymes with the picrosides levels in P. kurroa. The results showed changes in the catalytic activities as well as in the gene expression profiles of hexokinase, pyruvate kinase, isocitrate dehydrogenase, malate dehydrogenase, and NADP⁺-malic enzyme in congruence with picroside-I content under different conditions of P. kurroa growth, which indicates the role of these enzymes in the accumulation of picrosides. The significant correlation coefficients (p?<?0.05) observed between gene expression and enzyme activity underline the role of integrative studies for a better understanding of connecting links between metabolic pathways leading to picroside biosynthesis. This is apparently the first report on the involvement of glycolytic and TCA cycle enzymes in the accumulation of picrosides in P. kurroa.     

Differences in capacities of in vitro organ regeneration between two Arabidopsis ecotypes Wassilewskija and Columbia

In vitro organogenesis is well-controlled and thus provides an ideal system to study mechanisms of plant organ development. Although it has been well investigated for a long time that exogenous hormones play important roles in determining the types of organs regenerated in vitro, there is currently limited information available for other key factors that mediate de novo organ regeneration. Here, we reported simple and efficient one-step processes for evaluating capacities of inflorescence stem-derived in vitro organogenesis between two different ecotypes in Arabidopsis. Different types of organs, including shoots and roots were initiated from inflorescence stem explants cultured on the media containing 216 combinations of exogenous auxin and cytokinin. Further, we showed that Wassilewskija ecotype had the much higher shoot regeneration capacity than Columbia with different combinations of hormones, indicating that the ecotype is an essential factor determining de novo organogenesis. Our results also suggested that the defined expression patterns of genes involved in auxin and cytokinin biosynthesis were correlated with the variations in organogenesis capacities between the two ecotypes. Thus, in vitro organogenesis is likely regulated by ecotypes through mediating endogenous hormonal biosynthesis.     

Efficient plant regeneration via direct organogenesis and Agrobacterium tumefaciens-mediated genetic transformation of Picrorhiza kurroa: an endangered medicinal herb of the alpine Himalayas

Picrorhiza kurroa Royle ex. Benth. is a medicinal herb of immense therapeutic value with restricted geographic distribution. Efficient plant regeneration via direct organogenesis and Agrobacterium tumefaciens-mediated genetic transformation was developed for this plant. Multiple shoot bud induction was achieved from leaf explants cultured in Gamborg??s B₅ medium containing 3?% (w/v) sucrose, 3?mg/l kinetin and 1?mg/l indole-3-butyric acid. More than 90?% of leaf explants formed shoot buds leading to whole plant regeneration. An Agrobacterium-mediated genetic transformation protocol was developed using A. tumefaciens strain GV3101 harboring binary vector pCAMBIA1302 containing the green fluorescent protein and hygromycin phosphotransferase genes. Leaf explants precultured for 2?d were the most suitable for co-cultivation with Agrobacterium and transformation efficiency was enhanced with 200???M acetosyringone. Putative transformants were selected using media containing 15?mg/l hygromycin. Transformation was verified by detection of the green fluorescent protein using fluorescence microscopy and by polymerase chain reaction. Approximately 56?% of the explants were transformed with an average of 3.4?±?0.4 transgenic plantlets per explant. An efficient regeneration and transformation protocol thus developed enabling a fresh perspective of metabolic engineering in P. kurroa using an Agrobacterium-mediated transformation. This is the first report of direct organogenesis from leaf explants and genetic transformation of P. kurroa.     

De novo shoot organogenesis: from art to science

In vitro shoot organogenesis and plant regeneration are crucial for both plant biotechnology and the fundamental study of plant biology. Although the importance of auxin and cytokinin has been known for more than six decades, the underlying molecular mechanisms of their function have only been revealed recently. Advances in identifying new Arabidopsis genes, implementing live-imaging tools and understanding cellular and molecular networks regulating de novo shoot organogenesis have helped to redefine the empirical models of shoot organogenesis and plant regeneration. Here, we review the functions and interactions of genes that control key steps in two distinct developmental processes: de novo shoot organogenesis and lateral root formation.     

Biosynthesis and accumulation of a medicinal compound,Picroside-I,in cultures of <Emphasis Type="Italic">Picrorhiza kurroa</Emphasis> Royle ex Benth

Establishment of callus cultures and plant regeneration from different explants coupled with estimation of Picrosides in morphogenetically different developmental stages showed that Picroside-I accumulates in shoot cultures of Picrorhiza kurroa with no detection of Picroside-II. The Picroside-I content was 1.9, 1.5, and 0.04 mg/g in leaf discs, stem and root segments, respectively. The Picroside-I content declined to almost non- detectable levels in callus cultures derived from leaf discs, stem segments with no change in Picroside-I content in root segments or calli derived thereof. The biosynthesis and accumulation of Picroside-I started in callus cultures differentiating into shoot primordia and reached to the concentrations comparable to original explants of leaf discs and stem segments in fully developed shoots with contents of 2.0 and 1.5 mg/g, respectively. The shoots formed from root-derived callus cultures were relatively slow in growth as well as the amount of Picroside-I content was comparatively low (1.0 mg/g) compared to shoots derived from callus cultures of leaf and stem segments, respectively. The current study concludes that the biosynthesis and accumulation of Picroside-I is developmentally regulated in different morphogenetic stages of P. kurroa tissue cultures.     

Isolation and HPLC assisted quantification of two iridoid glycoside compounds and molecular DNA fingerprinting in critically endangered medicinal Picrorhiza kurroa Royle ex Benth: implications for conservation

Picrorhiza kurroa is a medicinally important, high altitude perennial herb, endemic to the Himalayas. It possesses strong hepato-protective bioactivity that is contributed by two iridoid picroside compounds viz Picroside-I (P-I) and Picroside-II (P-II). Commercially, many P. kurroa based hepato-stimulatory Ayurvedic drug brands that use different proportions of P-I and P-II are available in the market. To identify genetically heterozygous and high yielding genotypes for multiplication, sustained use and conservation, it is essential to assess genetic and phytochemical diversity and understand the population structure of P. kurroa. In the present study, isolation and HPLC based quantification of picrosides P-I and P-II and molecular DNA fingerprinting using RAPD, AFLP and ISSR markers have been undertaken in 124 and 91 genotypes, respectively. The analyzed samples were collected from 10 natural P. kurroa Himalayan populations spread across four states (Jammu & Kashmir, Sikkim, Uttarakhand and Himachal Pradesh) of India. Genotypes used in this study covered around 1000 km geographical area of the total Indian Himalayan habitat range of P. kurroa. Significant quantitative variation ranging from 0.01 per cent to 4.15% for P-I, and from 0.01% to 3.18% in P-II picroside was observed in the analyzed samples. Three molecular DNA markers, RAPD (22 primers), ISSR (15 primers) and AFLP (07 primer combinations) also revealed a high level of genetic variation. The percentage polymorphism and effective number of alleles for RAPD, ISSR and AFLP analysis varied from 83.5%, 80.6% and 72.1%; 1.5722, 1.5787 and 1.5665, respectively. Further, the rate of gene flow (Nm) between populations was moderate for RAPD (0.8434), and AFLP (0.9882) and comparatively higher for ISSR (1.6093). Fst values were observed to be 0.56, 0.33, and 0.51 for RAPD, ISSR and AFLP markers, respectively. These values suggest that most of the observed genetic variation resided within populations. Neighbour joining (NJ), principal coordinate analysis (PCoA) and Bayesian based STRUCTURE grouped all the analyzed accessions into largely region-wise clusters and showed some inter-mixing between the populations, indicating the existence of distinct gene pools with limited gene flow/exchange. The present study has revealed a high level of genetic diversity in the analyzed populations. The analysis has resulted in identification of genetically diverse and high picrosides containing P. kurroa genotypes from Sainj, Dayara, Tungnath, Furkia, Parsuthach, Arampatri, Manvarsar, Kedarnath, Thangu and Temza in the Indian Himalayan region. The inferences generated in this study can be used to devise future resource management and conservation strategies in P. kurroa.Supplementary InformationThe online version contains supplementary material available at 10.1007/s12298-021-00972-w.     

Chemical composition,antioxidant and macromolecule damage protective effects of Picrorhiza kurroa Royle ex Benth

In the present study, we identified the chemical constituents of 70% hydroalcoholic fraction of Picrorhiza kurroa by LC–ESI–MS/MS which showed the presence of iridoid glucosides such as picroside I, picroside II, picroside III, picroside IV, kutkoside, pikuroside and flavonoids like apocynin and vanillic acid. P. kurroa exhibited DPPH radical scavenging and metal chelating activities with IC₅₀ of 75.16 ± 3.2 and 55.5 ± 4.8 μg/mL and also showed potent reducing power and total antioxidant activities. The extract inhibited macromolecule damage such as H₂O₂ induced plasmid DNA damage and AAPH induced oxidation of bovine serum albumin and lipid peroxidation of rat hepatic tissues.     

Chlorogenic acid participates in the regulation of shoot,root and root hair development in Hypericum perforatum

Chlorogenic acid (CGA), a product of the phenylpropanoid pathway, is one of the most widespread soluble phenolic compounds in the plant kingdom. Although CGA is known to have important roles in plant function, its relevance in plant de novo organogenesis is not yet understood. With a series of experiments, here we show that CGA has a potential role in shoot, root and root hair development. In the first phase of our investigation, we developed an efficient and novel thin cell layer (TCL) regeneration protocol for Hypericum perforatum which could bridge all the in vitro morphogenetic stages between single cell and complete plant. Tissues at different morphogenetic states were analysed for their phenolic profile which revealed that shoot differentiation from callus tissues of H. perforatum is accompanied by the onset of CGA production. Further, the relevance of CGA in de novo organogenesis was deciphered by culturing highly organogenic root explants on media augmented with various concentrations of CGA. Results of this experiment showed that CGA concentrations lower than 10.0 mg l^?1 did not affect shoot organogenesis, whereas, higher concentrations significantly reduced this process in a concentration-dependent manner. In spite of the differential concentration-dependent effects of CGA on shoot regeneration, supplementation of CGA did not have any effect on the production of lateral roots and root hairs. Interestingly, CGA showed a concentration-dependent positive correlation with lateral roots and root hairs production in the presence of α-naphthaleneacetic acid (NAA). When the culture medium was augmented with 2-aminoindane-2-phosphonic acid (AIP), an inhibitor of phenylalanine ammonia lyase (PAL), induction of shoots, lateral roots and root hairs from the explants was significantly affected. Addition of an optimum concentration of CGA in these cultures partially restored all these organogenic processes.     

Agrobacterium rhizogenes-mediated transformation of Picrorhiza kurroa Royle ex Benth.: establishment and selection of superior hairy root clone

A protocol for induction and establishment of Agrobacterium rhizogenes-mediated hairy root cultures of Picrorhiza kurroa was developed through optimization of the explant type and the most suitable bacterial strain. The infection of leaf explants with the LBA9402 strain resulted in the emergence of hairy roots at 66.7% relative transformation frequency. Nine independent, opine and TL-positive hairy root clones were studied for their growth and specific glycoside (i.e., kutkoside and picroside I) productivities at different growth phases. Biosynthetic potentials for the commercially desirable active constituents have been expressed by all the tested hairy root clones, although distinct inter-clonal variations could be noted in terms of their quantity. The yield potentials of the 14-P clone, both in terms of biomass as well as individual glycoside contents (i.e., kutkoside and picroside I), superseded that of all other hairy root clones along with the non-transformed, in vitro-grown control roots of P. kurroa. The present communication reports the first successful establishment, maintenance, growth and selection of superior hairy root clone of Picrorhiza kurroa with desired phyto-molecule production potential, which can serve as an effective substitute to its roots and thereby prevent the indiscriminate up-rooting and exploitation of this commercially important, endangered medicinal plant species. CIMAP Publication No.: 2007-28J     

Radiation-induced Organogenesis and Isoenzyme Patterns in Long-term Callus Cultures of Datura innoxia

Effect of gamma irradiation on growth, shoot organogenesis andenzyme activities and isoenzyme patterns of -amylase and peroxidaseduring differentiation in long-term calluses of Datura innoxiahave been investigated. Radiation in doses of 0.2 and 1.0 kRstimulated the shoot regeneration frequency as well as the numberof shoots per regenerating callus. The 0.2 kR dose could induceshoot organogenesis even in calluses incubated in the dark oncallusing medium, although with less frequency. Such cultures,however, showed profuse shoot regeneration when sub-culturedonto regeneration medium under light conditions. A higher radiationdose (5.0 kR) was lethal to both growth and shoot differentiation.Prior to shoot regeneration, -amylase and peroxidase specificactivities increased to four- to fivefold and 7–24-fold,respectively. While the amylase isoenzyme pattern remained unchanged,specific changes in the isoperoxidase pattern were observedduring shoot differentiation in callus cultures. The most significantchange was the appearance of fast-moving anodic bands priorto visible shoot differentiation. Thus, such isoperoxidasesprovide useful biochemical markers for shoot differentiation. Datura innoxia, shoot organogenesis, isoenzyme pattern, gamma-radiation, growth regulators     

Hairy root culture of <Emphasis Type="Italic">Picrorhiza kurroa</Emphasis> Royle ex Benth.: a promising approach for the production of picrotin and picrotoxinin

Picrorhiza kurroa Royle ex Benth. is an endangered plant producing various compounds of medicinal importance. Hairy roots of P. kurroa were obtained following cocultivation of shoot tip explants with Agrobacterium rhizogenes strains A 4 and PAT 405. Bacterial strain A 4 appeared to be better than the strain PAT 405 in terms of both growth of respective hairy root cultures and secondary metabolite production. The optimal growth of both the hairy root cultures occurred on half-strength semisolid medium with 3% sucrose. Picrotin and picrotoxinin from the roots of wild type field grown plants were compared with 8-week-old hairy root cultures induced by the A 4 and PAT 405 strains of A. rhizogenes. Picrotin and picrotoxinin content were evaluated in hairy root cultures as well as roots of field grown plant of P. kurroa. In terms of the production of picrotin and picrotoxinin, the A 4 induced hairy roots appeared to be a better performer than the PAT 405 induced hairy root cultures. The picrotin and picrotoxinin content was highest in 8-week-old A 4 induced hairy roots (8.8 μg/g DW and 47.1 μg/g DW, respectively). Rapid growth of the hairy roots of P. kurroa with in vitro secondary metabolite production potential may offer an attractive alternative to the exploitation of this endangered plant species.     

Influence of type of explant,plant growth regulators,salt composition of basal medium,and light on callogenesis and regeneration in <Emphasis Type="Italic">Passiflora suberosa</Emphasis> L. (Passifloraceae)

Passiflora suberosa is used in popular medicine, improvement programs, and as an ornamental plant. The goal of this study was to establish efficient protocols for plant regeneration and callus induction from nodal, internodal and leaf segments excised from in vitro-grown plants. The different morphogenetic responses were modulated by the type and concentration of plant growth regulators, according to the basal medium and light conditions. Shoot formation occurred through three pathways: (1) development of preexisting meristems, (2) direct organogenesis, and (3) indirect organogenesis. Development of preexisting meristems was observed from nodal segments (1 shoot/explant) in response to α-naphthaleneacetic acid (NAA), picloram (PIC), and 2,4-dichlorophenoxyacetic acid (2,4-D), using two basal media (MS and MSM). Direct organogenesis in this species was obtained for the first time in this work, through shoot development from internodal segments in the presence of 6-benzyladenine (BA). The highest regeneration rates were achieved on MSM medium, regardless of the BA concentration. Indirect organogenesis was achieved from all explant types on media supplemented with BA, used alone or in combination with NAA. The highest regeneration efficiency was obtained from internodal segments cultured on MSM medium plus 44.4 μM BA. Compact, friable, or mucilaginous non-morphogenic calluses were induced by thidiazuron, PIC, 2,4-D, and NAA. High-yielding friable calluses obtained on MSM medium supplemented with 28.9 μM PIC are being used for the establishment of suspension cultures and further analysis of the production of bioactive compounds.     

Molecular Analysis of In Vitro Shoot Organogenesis

Shoot organogenesis is one of the in vitro plant regeneration pathways. It has been widely employed in plant biotechnology for in vitro micropropagation and genetic transformation, as well as in study of plant development. Morphological and physiological aspects of in vitro shoot organogenesis have already been extensively studied in plant tissue culture for more than 50 years. Within the last ten years, given the research progress in plant genetics and molecular biology, our understanding of in vivo plant shoot meristem development, plant cell cycle, and cytokinin signal transduction has advanced significantly. These research advances have provided useful molecular tools and resources for the recent studies on the genetic and molecular aspects of in vitro shoot organogenesis. A few key molecular markers, genes, and probable pathways have been identified from these studies that are shown to be critically involved in in vitro shoot organogenesis. Furthermore, these studies have also indicated that in vitro shoot organogenesis, just as in in vivo shoot development, is a complex, well-coordinated developmental process, and induction of a single molecular event may not be sufficient to induce the occurrence of the entire process. Further study is needed to identify the early molecular event(s) that triggers dedifferentiation of somatic cells and serves as the developmental switch for de novo shoot development.     

Toward Molecular Understanding of In Vitro and In Planta Shoot Organogenesis

Shoot organogenesis, one of the in vitro plant regeneration processes that occur during in vitro micropropagation, is used in the study of plant development. Morphological, physiological, and molecular aspects of in vitro shoot organogenesis have been extensively studied for over 50 years. Because of the research progress in plant genetics and molecular biology, our understanding of in planta and in vitro shoot meristem development, the cell cycle and cytokinin signal transduction has advanced significantly. These research advances provide useful information as well as molecular tools to study further the genetic and molecular aspects of shoot organogenesis. A number of key molecular markers, genes, and pathways have been shown to play a critical role in the process of in vitro shoot organogenesis. Furthermore, these studies reveal that in vitro shoot organogenesis, as with in planta shoot development, is a complex, well-coordinated developmental process, given that the induction of a single molecular event is likely to be insufficient to induce the entire process. Continued study is required to identify additional molecular events that trigger dedifferentiation and act as developmental switches for de novo shoot development.     

Meta-topolin stimulates de novo shoot organogenesis and plant regeneration in cassava

A novel protocol for de novo shoot organogenesis from cassava has been developed utilizing meta-topolin to stimulate shoot regeneration from leaf, petiole and stem internode explants. While use of meta-topolin alone was capable of inducing shoot regeneration, a two-stage system combining meta-topolin with 2,4-D in a first stage medium, followed by subculture onto elevated levels of meta-topolin, was superior for inducing multiple shoot regeneration events in more than 35% of explants in cultivar TME 7. Caulogenesis was achieved in eleven additional cultivars. Meta-topolin was also found to be beneficial for stimulating shoot regeneration from somatic embryos and cotyledon explants. The shoot organogenesis techniques described enhance the capacity of existing embryogenic systems and present previously unavailable morphogenic pathways for developing genetic transformation and gene editing technologies in cassava.