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Here is the basic
information along with a report from the Canadian Government.
Stevia Rebaudiana Bertoni is a perennial herb that has been used for centuries in Paraguay and Southern Brazil. It has been used to sweeten foods and drinks (particularly yerbe mate tea). It has been grown commercially up until the introduction of sugar cane but is once again grown commercially for the sugar substitute market. Stevia currently accounts for over 40% of the sweetener consumption in Japan. Requirements: * Lots of Sunlight (preferably 16 hours
a day).
Where to Find the Plants: * Herbal Advantage, Inc. - Route 3, Box
93 Rogersville, MO 65742-9214 (800) 753-9199
The following information was emailed to
me by Dan Chase (thanks Dan). There is A LOT of information here and some
of it is rather technical and wordy. BUT, there is some really good information
on growing stevia plants. So read it at your own risk!
Stevia rebaudiana - Its biological, chemical and agricultural properties J.E. Brandle, A.N. Starratt and M. Gijzen
TABLE OF CONTENTS Introduction
References
Stevia FAQ
INTRODUCTION The worldwide demand for high potency sweeteners
is expected to increase especially with the new practice of blending different
sweeteners, the demand for alternatives is expected to increase. The sweet
herb of Paraguay, Stevia rebaudiana Bertoni produces, in its leaves, just
such an alternative with the added advantage that stevia sweeteners are
natural plant products. In addition, the sweet steviol glycosides have
functional and sensory properties superior to those of many other high
potency sweeteners. Stevia is likely to become a major source of high potency
sweetener for the growing natural food market in the future. The task at
hand is to convert stevia from a wild plant to a modern crop well suited
to efficient mechanized production.
BIOLOGY, ETHNOBOTANY AND HISTORY OF CULTIVATION Stevia rebaudiana Bert. is one of 154 members
of the genus Stevia and one of only two that produce sweet steviol glycosides
(Robinson 1930; Soejarto et al. 1982, 1983). It is native to the valley
of the Rio Monday in highlands of Paraguay, between 25 and 26 degrees south
latitude, where it grows in sandy soils near streams (Katayama et al. 1976).
Stevia was first brought to the attention of Europeans in 1887 when M.S.
Bertoni learned of its unique properties from the Paraguayan Indians and
Mestizos (Lewis, 1992). Various reports cited by Lewis (1992) indicate
that it was long known to the Guarani Indians of the Paraguayan highlands
who called it caa-jhj, meaning sweet herb. The leaves were used either
to sweeten mati or as a general sweetening agent. Seeds were sent to England
in 1942 in an unsuccessful attempt to establish production. The first reports
of commercial
Stevia is a member of the Compositae family. It is a small shrubby perennial growing up to 65 cm tall, with sessile, oppositely arranged lanceolate to oblancoelate leaves, serrated above the middle. Trichome structures on the leaf surface are of two distinct sizes, one large (4-5 5m), one small (2.5 5m) (Shaffert and Chetobar 1994b). The flowers are small (7-15 mm), white and arranged in an irregular cyme. The seed is an achene with a feathery pappus (Robinson 1930). Stevia is an obligate short day plant with
a critical day length of about 13 h. Extensive variability within populations
for day length
CROP PRODUCTION Stevia plants can be propagated from cuttings or seed. Since germination rates are poor and seedlings very slow to establish it is best grown as an annual or perrenial transplanted crop. Clonal propagation is practical for small scale production, but is probably not economically viable for large scale stevia production where labor costs are high. The cost of producing vegetatively propagated transplants in Canada is high, so low cost transplants produced from seed is the only viable method on which to base stevia production in Canada. Only production as an annual is possible in most regions of Canada. The discussion of crop production in this review will therefore be limited to seed-based propagation of an annual transplanted crop. In the temperate latitudes of the Northern hemisphere and South Western Ontario in Canada more specifically, the production cycle for annual stevia begins with the 6-7 week old plants grown from seed, in cells, in heated greenhouses. Seedlings are transplanted to the field in mid to late May. Fertilizer is banded along with the transplants. The crop is irrigated as required. Stevia is slow to establish under Canadian conditions and growth is sluggish until mid July. Most of the leaf yield is accumulated from July until mid to late September. The whole plant is harvested just above ground level, elevated into wagons and then dried. Following drying, the leaves are separated from the stems using a thesher. The leaves are then stored ready for processing. Seed Production and Quality Given stevia-s daylength requirements, seed production in the Northern hemisphere would be best situated between 20 and 30E N latitude. The crop could be transplanted in February or March and seed collected in late summer. Flowering under these conditions should occur between 54-104 d following transplanting, depending on the daylength sensitivity of the cultivars used for seed production (Katayama et al. 1979). One-thousand seed weights for stevia seed usually range between 0.15 and 0.30 g and, depending on plant density, seed yields of up to 8.1 kg ha-1 are possible (Carniero 1990). Seed germination is often poor and rates less than 50% are common (Miyazaki and Wantenabe 1974). Given the aforementioned conditions, seed produced on one ha could be enough to supply transplants for up to 200 ha of leaf production. Seed viability and yield are affected by growing conditions during pollination and seed filling. Excessive rainfall during pollination can affect both seed yield and germination (Carneiro 1990, Shuping and Shizhen 1995). Seed is best stored at 0E C, but even under low temperature conditions germination will still decline 50% over three years (Shuping and Shizhen 1995). Sealing of storage containers or using lower temperatures did not prevent the decrease in germination over time. Cultural Practices Planting densities ranging from 40,000 to 400,000 plants/ha have been tried in experiments conducted in Japan (Katayama et al. 1976). Leaf yield increased with increasing density up to 83,000 and 111,000 plants ha-1 for the first year of production. The concentration of stevioside in the leaves of stevia increases when the plants are grown under long days (Metvier and Viana 1979). Since glycoside synthesis is reduced at or just before flowering, delaying flowering with long days allows more time for glycoside accumulation. It follows that stevia production would be best situated in a long day environment where vegetative period is longer and steviol glycoside yields will be higher. Fertility requirements for stevia grown as an annual crop are moderate. Results from Japan demonstrate that, at the point of maximum dry matter accumulation, stevia plants consist of 1.4% N, 0.3% P, and 2.4% K (Katayama et al. 1976). In Ontario total biomass production of 7500 kg ha -1 are possible and of that total, 26% would be roots, 35% stems, and 39% leaves (R. Beyaert pers. comm.). Based on the composition observed by Katayama (1976) such biomass would require approximately 105 kg N, 23 kg P and 180 kg K from both soil and fertilizer. The actual rates of application will vary according to soil type and production environment, and need to be optimized for each specific situation. Two fungal diseases, Septoria steviae and Sclerotinia sclerotiorum, have been reported in stevia grown in Canada (Lovering and Reeleder 1996; Chang et al. 1997). Septoria disease was characterized by depressed, angular, shiny olive gray lesions, sometimes surrounded by a chlorotic halo, that rapidly coalesce. Sclerotinia disease was characterized by brown lesions on the stem, near the soil line, followed by wilting and eventually by the complete collapse of affected individuals. No means of controlling these diseases have yet been published. Since stevia is very slow to establish and does not compete well with weeds, herbicides or other means will be essential to control weed growth to produce ample yield and a clean crop. The herbicide trifluralin appears to be well tolerated by stevia (Katamaya 1979). Stevia is harvested just prior to flowering
when steviol glycoside content in the leaves is at its maximum (Sumida
1980, Xiang 1983). Following harvest the whole plant is dried and the leaves
separated from the stems for further processing (Murai 1988). The stems
have very low concentrations of sweet glycosides and are removed to minimize
processing costs (Brandle and Rosa 1992). Drying stevia under artificial
conditions is affected by a number of factors including loading rate, temperature,
and ambient air conditions (Van Hooren and Lester 1992). The effect of
drying conditions on glycoside levels or processing
Cultivar Development A variety of plant breeding procedures
have been used to improve leaf yield and rebaudioside A concentration in
the leaves. Based on cultivar descriptions from Japan, China and Korea
and our own work, it appears that sufficient genetic variability exists
to make significant genetic gains in leaf yield, rebaudioside A content
and the ratio of rebaudioside A to stevioside (Brandle and Rosa 1992; Lee
et al. 1979 and 1982; Shizhen 1995; Shyu et al. 1994; Morita 1987). Brandle
and Rosa (1992) found that the heritability of stevioside content to be
high (83%), based on calculations from a group of half-sib families. Heritabilities
for leaf yield (75 %) and leaf to stem ratio (83 %) were also substantial
indicating that selection would be effective. Total sweet glycoside concentration
in some lines from China was reported to be as high as 20.5%, and a rebaudioside
A to stevioside ratio of 9:1 was disclosed in the Japanese patent literature
(Shizhen 1995; Morita 1987). Two breeding methods reported by the latter
authors
Nakamura and Tamura (1985) studied a population
of 300 random individuals and found that total glycoside concentrations
at the seedling and harvest stages were not correlated suggesting that
early selection for total glycosides would not be effective. However, the
proportion of individual glycosides relative to the total was correlated
between seedlings and mature plants making early selection for glycoside
composition possible. The authors also observed a wide range of variation
in the four main glycosides and found that dulcoside A and stevioside,
and rebaudioside A and C, were positively correlated with each other.
THE CHEMISTRY OF THE DITERPENE GLYCOSIDE SWEETENERS The sweet diterpene glycosides of stevia
have been the subject of a number of reviews (Kinghorn and Soejarto 1985,
Crammer and Ikan 1986, and Hanson and De Oliveira 1993). Although interest
in the chemistry of the sweet principles dates from very early in the century,
significant progress towards chemical characterization was not made until
1931, with the isolation of stevioside (Bridel and Lavieille 1931a). Treatment
of this substance with the digestive juice of a snail yielded three moles
of glucose and one mole of steviol, while acid hydrolysis gave isosteviol
(Bridel and Lavieille 1931b). Isosteviol
Structure of steviol, isosteviol and stevioside The structure, stereochemistry and absolute configuration of steviol and isosteviol were established, through a series of chemical reactions and correlations over 20 years after the pioneering work of Bridel and Lavieille (Mosettig and Nes, 1955; Dolder et al. 1960; Djerassi et al. 1961; Mosettig et al. 1963). Structures of these and other diterpenes and diterpene glucosides are presented in Fig. 1. Concurrent studies on the parent glycoside indicated that one D-glucopyranose residue, hydrolyzed under alkaline conditions yielding steviolbioside, was attached to a carboxyl group (Wood et al. 1955) while the other two were components of a sophorosyl group (Vis and Fletcher 1956) bound to the aglycone through a $-glycosidic linkage (Yamasaki et al. 1976). Support for the proposed stereochemistry was achieved by the synthetic transformation of steviol into stevioside (Ogawa et al. 1980). Earlier, several approaches to the in vitro synthesis of steviol had been reported (Cook and Knox 1970; Nakahara et al. 1971; Mori et al. 1972; Ziegler and Kloek 1977). Recently, spectroscopic data concerning stevioside and steviolbioside were published (Van Calsteren et al. 1993). Other diterpenoid glycosides Further investigation of extracts of S.
rebaudiana leaves resulted in the isolation and identification of seven
other sweet diterpenoid glycosides. Kohda et al. (1976) obtained the first
two of these, rebaudiosides A and B, from methanol extracts together with
the major sweet substance stevioside and steviolbioside, a minor constituent
which was first prepared from stevioside by alkaline hydrolysis (Wood et
al. 1955). Subsequently, it was suggested that rebaudioside B was an artifact
formed from rebaudioside A during the isolation (Kaneda et al. 1977; Sakamoto
et al. 1977b). Stevioside has been converted
Methods of diterpenoid glycoside analysis A wide range of analytical techniques have
been employed to assess the distribution and level of sweet diterpenoid
glycosides in S. rebaudiana. These include thin layer chromatography (Tanaka
1982; Metivier and Viana 1979; Kinghorn et al. 1984; Nikolova-Damyanova
et al. 1994), over pressured layer chromatography (Fullas et al. 1989),
droplet counter-current chromatography (Kinghorn et al. 1982), and capillary
electrophoresis (Liu and Li 1995; Mauri et al. 1996). Stevioside levels
have also been determined enzymatically (Mizukami et al. 1982) and by near
infrared reflectance spectroscopy (Nishiyama et al. 1992) in plant strains
producing mainly stevioside. The most common analytical method, however,
has been high performance liquid chromatography. Although separations have
been also achieved using silica gel (Nikolova-Damyanova et al. 1994), hydroxyapatite
(Kasai et al. 1987), hydrophilic (Hashimoto et al. 1978), and size exclusion
(Ahmed and Dobberstein 1982a,1982b) columns, amino bonded columns have
been used most frequently for the analysis of the sweet glycosides
Other constituents In addition to the sweet diterpenoid glycosides,
several other diterpenes have been isolated from stevia. Since these compounds
may be part of the waste stream produced during stevia processing, their
availability in large quantities could make them into valuble co-products.
The first to be characterized were jhanol and austroinulin, previously
obtained from other plants, and 6-O-acetylaustroinulin (Sholichin et al.
1980). Also reported were the triterpenes $-amyrin acetate and three esters
of lupeol and the sterols stigmasterol and $-sitosterol, previously isolated
from leaves by Nabeta et al. (1976). Jhanol, austroinulin, 6-O-acetylaustroinulin
and 7-O-acetylaustroinulin as well as stevioside and rebaudioside A have
been obtained from stevia
Other chemical constituents of stevia have
been reported. Rajbhandari and Roberts (1983) identified six flavonoid
glycosides in an aqueous methanol extract of leaves: apigenin-4'-O-glucoside,
luteolin-7-O-glucoside, kaempferol-3-O-rhamnoside, quercitrin, quercetin-3-O-glucoside
and quercetin-3-O-arabinoside and 5, 7, 3'-trihydroxy-3, 6, 4'-trimethoxyflavone
(centaureidin). The major identified components in the essential oil were
the sesquiterpenes $-caryophyllene, trans-$-farnesene, "-humulene, *-cadinene,
caryophyllene oxide and nerolidol and the monoterpenes linalool, terpinen-4-ol
and "-terpineol (Fujita et al. 1977). Later, Martelli et al. (1985) identified
54 components of a steam distillate of dried leaves from Brazil. Of these,
caryophyllene
BIOSYNTHESIS OF THE SWEET GLYCOSIDES Steviol glycosides are derived from the mevalonic acid pathway. This is a fundamental metabolic route that provides the two C5 building block molecules, isopentenyl pyrophosphate (IPP) and dimethylallyl pyrophosphate (DMAPP), that are required for synthesis of all isoprenoid compounds (Chappell 1995; McGarvey and Croteau 1995). Steviol Biosynthesis from Geranylgeranyl Pyrophosphate Steviol biosynthesis was first investigated
over 30 years ago (Fig. 2) (Ruddat et al. 1965; Bennett et al., 1967; Hanson
and White 1968). This early work established that the initial steps leading
to the steviol glycosides from GGPP are identical to those in gibberellin
biosynthesis. Thus, GGPP is converted to ent-copalyl pyrophosphate (CPP)
by CPP synthase (also called ent-kaurene synthase A) and ent-kaurene is
produced from CPP by ent-kaurene synthase (also called ent-kaurene synthase
B). Subsequent oxidation of this product at the C-19 position to ent-kaurenoic
acid is assumed to occur via the action of one or more P450 monooxygenases
that have yet to be identified (Hedden and Kamiya, 1997). At this point
the pathways to the steviol glycosides
The Glycan Side Chains The two oxygenated functional groups of
steviol, the C-19 carboxylate and the C-13 alcohol, provide attachment
points for the sugar side chains that determine the identity of the 8 different
glycosides identified to date. These glycan side chains are comprised predominately
of glucose residues but may also contain rhamnose (Fig. 1). The biosynthetic
sequence of glycosylations that give rise to the different glycan side
chains is still in the early stages of elucidation. At least three distinct
glucosyltransferase activities have been identified (Shibata et al. 1991,
1995). Two of these activities have been purified and characterized. Activity
I transfers glucose from UDP-glucose to the 13-hydroxy position of steviol
to afford steviolmonoside.
Compartmentation of Biosynthesis and Storage Diterpene biosynthesis has been found to
occur generally in plastids of plant cells (McGarvey and Croteau 1995;
Hedden and Kamiya 1997). There is good evidence that steviol biosynthesis
conforms to this pattern and is localized in leaf chloroplasts. High levels
of HMG-CoA reductase activity can be extracted from isolated stevia chloroplasts
and the ent-kaurenoic acid 13-hydroxylase that converts ent-kaurenoic acid
to steviol was purified from the chloroplast stroma (Kim et al. 1996a,
1996b). In contrast, the UDP-glucosyl transferases performing the glycosylations
on the steviol skeleton are operationally soluble enzymes, indicating that
these reactions happen outside of the chloroplast. Steviol glycosides are
transported to the cell vacuole where they
FUNCTIONAL AND SENSORY PROPERTIES OF STEVIOL
GLYCOSIDE SWEETENERS
Of the four major sweet diterpene glycoside
sweeteners present in stevia leaves only two, stevioside and rebaudioside
A, have had their physical and sensory properties well characterized. Stevioside
and rebaudioside A were tested for stability in carbonated beverages and
found to be both heat and pH stable (Chang and Cook 1983). However, rebaudioside
A was subject to degradation upon long term exposure to sunlight. Kinghorn
and Soejarto (1985) also cite numerous Japanese studies that demonstrate
that stevioside is very stable.
Phillips (1989) has summarized the early
sensory research. Stevioside was between 110 and 270 times sweeter than
sucrose, rebaudioside A between 150 and 320, and rebaudioside C between
40 and 60. Dulcoside A was 30 times sweeter than sucrose. Rebaudioside
A was the least astringent, the least bitter, had the least persistant
aftertaste and was judged to have the most favourable sensory attributes
of the four major steviol glycosides (Phillips 1989, Tanaka 1997). Dubois
and Stephanson (1984) have also confirmed that rebaudioside A is less bitter
than stevioside and demonstrated that the bitter notes in stevioside and
rebaudioside A are an inherent property of the compounds and not necessarily
the result of impurities in whole plant extracts. Relative to other high
potency sweeteners such as apsartame, bitterness tends to increase with
concentration for both stevioside
COMMERCIAL EXTRACTION OF STEVIOL GLYCOSIDES Most of the commercial processing of stevia
leaves occurs in Japan and there are dozens of patents describing methods
for the extraction of steviol glycosides. Kinghorn and Soejarto (1985)
have categorized the extraction patents into: those based on solvent (Haga
et al. 1976), solvent plus a decolorizing agent (Ogawa 1980), adsorption
chromatography (Itagaki and Ito 1979), ion exchange (Uneshi et al. 1977),
and selective precipitation of individual glycosides (Matsushita and Kitahara
1981). Phillips (1989) has indicated that the most favoured extraction
processes involve four steps: aqueous or solvent extraction, ion exchange,
precipitation or coagulation with filtration, then crystallization and
drying. New methods based on ultra-filtration have been disclosed recently
(Tan and Ueki 1994).
SAFETY OF STEVIA SWEETENERS Stevia sweeteners have a long history of use in South America and now in Japan and there are no reports of adverse effects. Nonetheless, the safety of stevia sweeteners has been the subject of controversy for a number of years (e.g. Bonvie et al. 1997, Pendergast 1991). Planas and Kuc (1968) reported that 5 % solution of stevia leaf extract had a strong anti-fertility effect in both male and female rats. Subsequent studies conducted to confirm this result have all been negative (Sincholle and Marcorelles 1989, Yodyingyuad and Bunyawong 1991). In studies of acute toxicity, a LD50 of 8.2 g kg-1 for a refined stevioside extract was cited by Katayama et al. (1979). An acceptable daily stevioside intake of 7.9 mg kg-1 was suggested by Xili et al. (1992). Yodyingyuad and Bunyawong (1991) reported that neither growth nor reproduction were affected in hamsters fed pure stevioside at levels up to 2.5 g kg-1 day-1 for 4 months. Stevioside and rebaudioside A are both non-cariogenic (Das et al. 1992). Pezzuto and co-workers (1985) reported that metabolically activated steviol is mutagenic, a result that has been confirmed in another more recent study (Matsui et al. 1996). Kinghorn and Soejarto (1985) and Kinghorn (1992) conducted two reviews of the literature related to safety of stevia sweeteners and concluded that stevia leaves and stevioside are safe for human consumption. However, the activated steviol metabolite that is mutagenic has not yet been identified and it is not known if the activation of steviol actually occurs in humans (Procinska et al. 1991, Matsui et al. 1996). Matsui et al. (1996) concluded that further work is required to determine what risk steviol glycosides pose to humans. CONCLUSION Stevia represents a new opportunity for researchers and farmers alike. A great deal of information relating to production practices and disease control is required to optimize annual transplant production for Canada. Such basic things as herbicide and fungicides registration, optimum planting and harvest times, fertilizer recommendations are all essential. Since markets exist for stevia now, production and optimization must occur in parallel. The production of remarkably high levels of one class of secondary metabolite is of significant interest for chemists, biochemists and geneticists and may prove to be a foundation for the production of new metabolites in the future. Because the safety of stevia for human consumption remains controversial, there is a clear need for further experimentation with respect to the metabolic fate of steviol glycosides. REFERENCES Ahmed, M. S., Dobberstein, R. H. and Farnsworth,
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