Biotechnological approaches for cultivation and enhancement of secondary metabolites in Arnica montana L.

Arnica montana L. (Asteraceae) is a valuable medicinal plant with anti-inflammatory and cicatrizing properties attributed to the sesquiterpene lactones, flavonoids and essential oil produced in the flower heads. In many European countries, the populations of A. montana are close to extinction in their natural habitats because of uncontrolled eradication and indiscriminate collection of the plants. Various approaches for in vitro propagation of the species and also, biosynthesis of secondary metabolites in tissue and cell cultures are assessed in the current review. Special attention is paid to the biological activity and chemical composition of compounds produced by the species as well as the opportunities of in vitro methods to isolate high-productive clones. The influence of different factors on the micropropagation, callusogenesis, genetic transformation and identification of certain biologically active substances is discussed in detail. By the reference to the available issues we concluded that biotechnology applied to A. montana cultivation may improved the plant preservation and increased the production of sesquiterpene lactones and other secondary metabolites.     

Biotechnological production of eleutherosides: current state and perspectives

Eleutherosides, the phenylpropanoid and lignan glycosides, are the active ingredients accumulated in the roots and stems of Eleutherococcus species and in Eleutherococcus senticosus in particular. Syringin (=eleutheroside B) and (?) syringaresinol-di-O-β-d-glucoside (=eleutheroside E) appear as the most important bioactive compounds which are used as adaptogens, besides their abundant antidiabetic and anticancer properties. As the availability of “Eleuthero” is becoming increasingly limited because of its scanty natural distribution, the production of these compounds by biotechnological means has become an attractive alternative. In E. senticosus and other closely related species, Eleutherococcus sessiliflorus, Eleutherococcus chiisanensis, and Eleutherococcus koreanum, organogenic cultures have been induced for the production of eleutherosides. Bioreactor cultures have been established and various parameters, which influence on the accumulation of biomass and secondary metabolites, have been thoroughly investigated. Pilot-scale cultures have also been accomplished for the large-scale production of somatic embryos containing abundant amounts of eleutherosides. This review describes the biotechnological approaches and challenges for the production of eleutherosides.     

The biosynthesis and genetic engineering of bioactive indole alkaloids in plants

Indole alkaloids are widely distributed secondary metabolites that exhibit a broad range of pharmacological activities. They are synthesized through plant biosynthetic pathways involving complex enzyme activities and regulatory strategies. Since many compounds of indole alkaloids are structurally too complex to be manufactured economically by chemical synthesis, they have to be isolated from naturally grown or cultivated plants. Therefore, the biotechnological production of high-value plant secondary metabolites in cultivated cells or transgenic plants is potentially an attractive alternative. The present review describes the regulation of indole alkaloids biosynthesis, as well as their pharmacological functions in plants such as anti-microbes, anti-inflammatory and anti-tumor. Furthermore, it discusses different strategies by which the genetic engineering of indole alkaloids biosynthesis through the reconstruction of the pathway achieves high production of specific compounds.     

Biotechnological approaches to enhance the biosynthesis of ginkgolides and bilobalide in Ginkgo biloba

Ginkgo biloba is one of the oldest living tree species and its extracts or powdered leaves are one of the best selling herbal preparations. The main bioactive constituents are flavonoids and the terpene trilactones, ginkgolides and bilobalide, which are responsible for their pharmacological activity. However, there are many difficulties for ginkgo leaves supply and the chemical synthesis is far from of being applicable for commercial-scale production. G. biloba cell cultures have arisen as a useful alternative source of pharmacologically active terpene trilactones. This review sheds light on the chemistry and biosynthesis of terpene trilactones with the aim of increasing the production of these high value compounds by biotechnological approaches. Different biotechnological strategies to improve ginkgolides and bilobalide production will be discussed, including screening and selection of in vitro ginkgo cultures, cell differentiation levels of these cultures, optimization of culture conditions, feeding and elicitation strategies. Special attention will be paid in developing new methodologies to enhance ginkgo cell biomass and provide high amounts of these bioactive terpene trilactones using large-scale cell cultures.     

Production of podophyllotoxin from Podophyllum hexandrum: a potential natural product for clinically useful anticancer drugs

Podophyllum hexandrum Royle of family Berberidaceae is an endangered medicinal plant. Rhizome ofP.hexandrum contains several lignans which posses antitumor activity. Podphyllotoxin is the most active cytotoxic natural product. It is used as starting compound for the synthesis of anticancer drug etoposide and teniposide. Podophyllotoxin acts as an inhibitor of microtubule assembly. These drugs are used for lung cancer, testicular cancer, neuroblastoma, hepatoma and other tumors. Besides this, it also shows antiviral activities by interfering with some critical viral processes. Availabilityof podophyllotoxin from plants has its limitations because of its intense collection from nature and lack of organized cultivation. The chemical synthesis of podophyllotoxin is considered to be very complicated as yet. The use of biotechnological approaches for the production of podophyllotoxin using cell cultures, organ cultures, and biotransformation route or by manipulating biosynthetic pathway proves to be an attractive alternative for production of podophyllotoxin. The present paper discusses the current status of research, limitations and future prospects for theproduction of podophyllotoxinin vitro.     

A rational approach to improving the biotechnological production of taxanes in plant cell cultures of Taxus spp.

Taxol is a complex diterpene alkaloid scarcely produced in nature and with a high anticancer activity. Biotechnological systems for taxol production based on cell cultures of Taxus spp. have been developed, but the growing commercial demand for taxol and its precursors requires the optimization of these procedures. In order to increase the biotechnological production of taxol and related taxanes in Taxus spp. cell cultures, it is necessary not only to take an empirical approach that strives to optimize in-put factors (cell line selection, culture conditions, elicitation, up-scaling, etc.) and out-put factors (growth, production, yields, etc.), but also to carry out molecular biological studies. The latter can provide valuable insight into how the enhancement of taxane biosynthesis and accumulation affects metabolic profiles and gene expression in Taxus spp. cell cultures.     

Plants Probiotics as a Tool to Produce Highly Functional Fruits: The Case of Phyllobacterium and Vitamin C in Strawberries

The increasing interest in the preservation of the environment and the health of consumers is changing production methods and food consumption habits. Functional foods are increasingly demanded by consumers because they contain bioactive compounds involved in health protection. In this sense biofertilization using plant probiotics is a reliable alternative to the use of chemical fertilizers, but there are few studies about the effects of plant probiotics on the yield of functional fruits and, especially, on the content of bioactive compounds. In the present work we reported that a strain of genus Phyllobacterium able to produce biofilms and to colonize strawberry roots is able to increase the yield and quality of strawberry plants. In addition, the fruits from plants inoculated with this strain have significantly higher content in vitamin C, one of the most interesting bioactive compounds in strawberries. Therefore the use of selected plant probiotics benefits the environment and human health without agronomical losses, allowing the production of highly functional foods.     

Purple-Pigmented Violacein-Producing <Emphasis Type="Italic">Duganella</Emphasis> spp. Inhabit the Rhizosphere of Wild and Cultivated Olives in Southern Spain

Bacteria have evolved mechanisms that allow them to grow and survive in highly competitive environments like soil and the rhizosphere. Using classical microbiological, physiological, and genetic analyses, we isolated and identified for the first time Duganella spp. associated with the rhizosphere of woody plants in Mediterranean environments that are able to produce violacein, a blue–purple secondary metabolite of considerable biotechnological interest. Based on physiological and biochemical characterization and phylogenetic analysis of different genes including 16S rRNA, gyrB, and vioA (implicated in the synthesis of violacein), the seven Duganella spp. strains isolated and studied were differentiated according to their host of origin (wild versus cultivated olives) and potentially might belong to new species. All the Duganella spp. strains produced violacein in vitro, with natural production levels significantly higher than that previously reported for other violacein-producing bacteria without optimizing growing conditions. The important biological, medical, and industrial applications of violacein make these bacteria good candidates for their biotechnological exploitation because low violacein yields are considered as one of the main limitations of using wild-type strains for extensive exploitation and pigment production. Independent of violacein production, purple-pigmented strains from olives showed proteolytic and lipolytic activities and a weak siderophore production. No in vitro inhibitory activity was demonstrated for bacteria or crude violacein filtrates against plant-pathogenic Gram-negative bacteria and fungi, but they did inhibit Gram-positive bacteria.     

Biotechnology of flavonoids and other phenylpropanoid-derived natural products. Part I: Chemical diversity, impacts on plant biology and human health

Plant natural products derived from phenylalanine and the phenylpropanoid pathway are impressive in their chemical diversity and are the result of plant evolution, which has selected for the acquisition of large repertoires of pigments, structural and defensive compounds, all derived from a phenylpropanoid backbone via the plant-specific phenylpropanoid pathway. These compounds are important in plant growth, development and responses to environmental stresses and thus can have large impacts on agricultural productivity. While plant-based medicines containing phenylpropanoid-derived active components have long been used by humans, the benefits of specific flavonoids and other phenylpropanoid-derived compounds to human health and their potential for long-term health benefits have been only recognized more recently. In this part of the review, we discuss the diversity and biosynthetic origins of phenylpropanoids and particularly of the flavonoid and stilbenoid natural products. We then review data pertaining to the modes of action and biological properties of these compounds, referring on their effects on human health and physiology and their roles as plant defense and antimicrobial compounds. This review continues in Part II discussing the use of biotechnological tools targeting the rational reconstruction of multienzyme pathways in order to modify the production of such compounds in plants and model microbial systems for the benefit of agriculture and forestry.     

The production of cytotoxic lignans by plant cell cultures

Cytotoxic lignans derived from podophyllotoxin are currently used in cancer chemotherapy. Podophyllotoxin for semi-synthetic derivatization is isolated from the rhizomes of Podophyllum plants growing wild, some of which are counted as endangered species. An alternative source for podophyllotoxin or related lignans may in future be cell cultures derived from different plant species, such as Podophyllum spp or Linum spp. These cell cultures were shown to accumulate considerable amounts of podophyllotoxin or 5-methoxypodophyllotoxin. Optimization of the cell cultivation regime might lead to a renewable source of cytotoxic lignans for medicinal uses. This Mini-Review summarizes the attempts to establish plant cell cultures for the production of podophyllotoxin and related lignans and their optimization towards high levels of these target compounds. It also summarizes the results of studies on the biosynthesis of podophyllotoxin and 5-methoxypodophyllotoxin.     

Production and engineering of terpenoids in plant cell culture

Terpenoids are a diverse class of natural products that have many functions in the plant kingdom and in human health and nutrition. Their chemical diversity has led to the discovery of over 40,000 different structures, with several classes serving as important pharmaceutical agents, including the anticancer agents paclitaxel (Taxol) and terpenoid-derived indole alkaloids. Many terpenoid compounds are found in low yield from natural sources, so plant cell cultures have been investigated as an alternate production strategy. Metabolic engineering of whole plants and plant cell cultures is an effective tool to both increase terpenoid yield and alter terpenoid distribution for desired properties such as enhanced flavor, fragrance or color. Recent advances in defining terpenoid metabolic pathways, particularly in secondary metabolism, enhanced knowledge concerning regulation of terpenoid accumulation, and application of emerging plant systems biology approaches, have enabled metabolic engineering of terpenoid production. This paper reviews the current state of knowledge of terpenoid metabolism, with a special focus on production of important pharmaceutically active secondary metabolic terpenoids in plant cell cultures. Strategies for defining pathways and uncovering rate-influencing steps in global metabolism, and applying this information for successful terpenoid metabolic engineering, are emphasized.     

Exploring the bioprospecting and biotechnological potential of white-rot and anaerobic Neocallimastigomycota fungi: peptidases,esterases, and lignocellulolytic enzymes

Fungi constitute an invaluable natural resource for scientific research, owing to their diversity; they offer a promising alternative for bioprospecting, thus contributing to biotechnological advances. For a long time, extensive information has been exploited and fungal products have been tested as a source of natural compounds. In this context, enzyme production remains a field of interest, since it offers an efficient alternative to the hazardous processes of chemical transformations. Owing to their vast biodiversity and peculiar biochemical characteristics, two fungal categories, white-rot and anaerobic Neocallimastigomycota, have gathered considerable attention for biotechnological applications. These fungi are known for their ability to depolymerize complex molecular structures and are used in degradation of lignocellulosic biomass, improvement of animal feed digestibility, biogas and bioethanol production, and various other applications. However, there are only limited reports that describe proteolytic enzymes and esterases in these fungi and their synergistic action with lignocellulolytic enzymes on degradation of complex polymers. Thus, in this minireview, we focus on the importance of these organisms in enzyme technology, their bioprospecting, possibility of integration of their enzyme repertoire, and their prospects for future biotechnological innovation.

     

Advances in phytochemistry,pharmacology and biotechnology of Bulgarian <Emphasis Type="Italic">Astragalus</Emphasis> species

The genus Astragalus L., Fabaceae (Leguminosae) is presented in Bulgarian flora by 31 species including local endemics, nine of them listed in the Red Data Book. The main biologically active compounds found in the Bulgarian Astragalus plants are saponins and flavonoids with a variety of effects: immunomodulatory, hepatoprotective, cytotoxic, antioxidant, antihypoxic and others. In the recent years volatiles with cytotoxic activity have also been determined. Saponins and flavonoids are still preferably produced by plants due to their complex structures. Variable quantities and qualities of the wild plant material, plants that need to grow several years before they are ready for harvesting and over-collecting of endangered Astragalus species are just a few of the problems connected with the production of these natural products. Therefore, cultured cells are possible alternative for production of high-value secondary metabolites. This review is focused on phytochemical, pharmacological and biotechnological studies of Bulgarian Astragalus plants and includes also results from our investigations.     

Tanshinone biosynthesis in Salvia miltiorrhiza and production in plant tissue cultures

Salvia miltiorrhiza Bunge (Lamiaceae) root, generally called Danshen, is an important herb in Chinese medicine widely used for treatment of cardiovascular diseases. Diterpenoid tanshinons are major bioactive constituents of Danshen with notable pharmacological activities and the potential as new drug candidates against some important human diseases. The importance of Danshen for traditional and modern medicines has motivated the research interest over two decades in the biosynthesis and biotechnological production of tanshinones. Although diterpenes in plants are presumably derived from the non-mevalonate (MVA) pathway, tanshinone biosynthesis in S. miltiorrhiza may also depend on the MVA pathway based on some key enzymes and genes detected in the early steps of these pathways. Plant tissue cultures are the major biotechnological processes for rapid production of tanshinones and other bioactive compounds in the herb. Various in vitro cultures of S. miltiorrhiza have been established, including cell suspension, adventitious root, and hairy root cultures, which can accumulate the major tanshinones as in the plant roots. Tanshinone production in cell and hairy root cultures has been dramatically enhanced with various strategies, including medium optimization, elicitor stimulation, and nutrient feeding operations. This review will summarize the above developments and also provide our views on future trends.     

The production of pyrethrins by plant cell and tissue cultures of Chrysanthemum cinerariaefolium and Tagetes species

Pyrethrins, the most economically important natural insecticide, comprise a group of six closely related monoterpene esters. The industrial production is based on their extraction from Chrysanthemum cinerariaefolium (Pyrethrum) capitula. The world production of natural pyrethrins still falls short of global market demand stimulating the research in in vitro production as an alternative to conventional cultivation methods. The different biotechnological alternatives such as callus cultures, shoot and root cultures, plant cell suspension cultures, and bioconversion of precursors by means of enzymatic synthesis or genetically engineered microorganisms, as well as the progress achieved in methods for the identification and quantitation of insecticidal compounds have been reviewed. Although technology for plant cell culture exists, industrial applications have, to date, been limited due to both the low economical viability and technological feasibility at large scale. Bioconversion of readily available precursors looks more attractive, but more research is needed before this technology is used for the industrial production of pyrethrins.     

Use of β-cyclodextrins to enhance phytosterol production in cell suspension cultures of carrot (Daucus carota L.)

Phytosterols are isoprenoid-derived compounds that play essential roles in plant growth and development as they are integral components of the plant cell membranes, and responsible for their permeability and fluidity. In this study, the effect of different types of beta-cyclodextrins (β-CD) on phytosterol production was evaluated using Daucus carota cell suspension cultures. A detailed analysis provides the optimal type and concentration of β-CD, elicitation time, and the optimal cell age and density. The highest levels of phytosterols produced by cells and secreted to the culture medium were obtained when 10 day-old D. carota cell suspension cultures, with an initial cell density of 200 g of fresh weight (FW) l^?1, were incubated in the presence of 50 mM of methylated-β-CD (M-β-CD) for 144 h. In addition, M-β-CD significantly promoted the accumulation of phytosterol in the extracellular medium of D. carota cell suspension cultures, which was not observed in control cell suspension cultures. Moreover, these high phytosterol levels did not improve when methyl jasmonate (MJ) was added to the cell suspension cultures alone or combined with 50 mM M-β-CD, although MJ stimulated the formation of defense-related compounds. Therefore, the use of carrot cell suspension cultures seems a promising biotechnological alternative since the addition of β-CD to the culture medium not only induced the biosynthesis of phytosterols but also promoted their secretion into the culture medium, where they were accumulated and could be isolated easily.     

Production of salidroside and tyrosol in cell suspension cultures of Rhodiola crenulata

Salidroside and its aglycone tyrosol are important compounds found in Rhodiola plants. In this study, callus derived from Rhodiola crenulata was induced and grown when explants were incubated on a Murashige and Skoog (MS) medium containing various concentrations of 6-benzyaldenine (BA), naphthalene acetic acid (NAA) and thidiazuron (TDZ). Callus was easily initiated from juvenile leaves in half strength MS medium supplemented with 0.5 mg/L BA and 3.0 mg/L NAA, while full strength MS containing 0.5 mg/L TDZ and 0.5 mg/L NAA was the best for callus subculture and subsequent cell suspension culture. The activities of l-phenylalanine ammonia lyase (PAL) and β-d-glucosidase, two key enzymes in salidroside synthesis, increased at first and subsequently decreased in cell suspension cultures. The salidroside and tyrosol levels in the cell suspension cultures were determined using high-performance liquid chromatography. High levels of salidroside and tyrosol were detected in cell suspension cultures of R. crenulata extracted with 75 % methanol, demonstrating that the biotechnological production of these compounds using plant cell suspension cultures derived from R. crenulata may be an attractive alternative to harvest-based production.     

Cell cultures of Maytenus ilicifolia Mart. are richer sources of quinone-methide triterpenoids than plant roots in natura

The quinone-methide triterpenoids (QMTs) are chemotaxonomic markers of the family Celastraceae and many compounds of this class possess important anticancer and anti-inflammatory activities. However, the levels of QMTs in the roots of Celastraceous species are typically very low (ca. 0.0003 %) and commercial production by extraction from such tissues would not be commercially viable. With the aim of determining if cells cultured in vitro might provide alternative sources of these bioactive triterpenoids, we have quantified and compared the concentrations of QMTs accumulated by the roots of plants of Maytenus ilicifolia Mart. ex Reissek (Celastraceae) aged 0.5–10 years, and in callus and suspension cultures derived from a cell line that had been subcultured over a period of 10 years. Comparing plants cultivated in natura, the highest levels of QMTs were detected in the root bark of 5-year old specimens. However, cell suspensions derived from the long-term cell line retained their capacity to synthesize and accumulate QMTs, and presented levels of maytenin, 22β-hydroxymaytenin, celastrol and pristimerin that were, respectively, 1.96-, 2.48-, 8.85- and 3.29-times higher than those in the roots of 5-year old plants. The results presented herein open up new possibilities for the large-scale production of QMTs and for the development of novel pharmaceuticals.     

Nuclear DNA content of Pongamia pinnata L. and genome size stability of in vitro-regenerated plantlets

Pongamia pinnata L. is a multipurpose versatile legume that is well known as a prospective feedstock biodiesel species. However, to date, there has been little genomic research aimed at the exploitation of the biotechnological potential of this species. Genetic characterization of any plant is a challenging task when there is no information about the genome size and organization of the species. Therefore, the genome size of P. pinnata was estimated by flow cytometry with respect to two standards (Zea mays and Pisum sativum), and compared with that of in vitro-raised plants (nodal segment, in vitro-rooted plantlets and acclimatized in vitro plants) to study the potential effect of somaclonal variation on genome size. This method can be used to support the establishment of true-to-type plants to encourage afforestation programs. Modified propidium iodide/hypotonic citrate buffer was used for isolation of the intact nuclei. The 2C DNA value of this species was estimated to be 2.51?±?0.01 pg. Statistically, there was no significant difference in the DNA content of the in vitro-grown plants and mother plant at α?=?0.05. As a result of the low genome size of P. pinnata, a species that has adapted itself to a wide range of edaphic and ecological condition, we can now proceed for its next generation sequencing and genomic diversity studies.     

Plant in vitro culture for the production of antioxidants--a review

Plant in vitro cultures are able to produce and accumulate many medicinally valuable secondary metabolites. Antioxidants are an important group of medicinal preventive compounds as well as being food additives inhibiting detrimental changes of easily oxidizable nutrients. Many different in vitro approaches have been used for increased biosynthesis and the accumulation of antioxidant compounds in plant cells. In the present review some of the most active antioxidants derived from plant tissue cultures are described; they have been divided into the main chemical groups of polyphenols and isoprenoids, and several examples also from other chemical classes are presented. The strategies used for improving the antioxidants in vitro production efficiency are also highlighted, including media optimization, biotransformation, elicitation, Agrobacterium transformation and scale-up.