<Emphasis Type="Italic">In vitro</Emphasis> plant regeneration through somatic embryogenesis and direct shoot organogenesis in <Emphasis Type="Italic">Pennisetum glaucum</Emphasis> (L.) R. Br.

An efficient in vitro plant regeneration protocol through somatic embryogenesis and direct shoot organogenesis has been developed for pearl millet (Pennisetum glaucum). Efficient plant regeneration is a prerequisite for a complete genetic transformation protocol. Shoot tips, immature inflorescences, and seeds of two genotypes (843B and 7042-DMR) of pearl millet formed callus when cultured on Murashige and Skoog (MS) medium supplemented with varying levels of 2,4-dichlorophenoxyacetic acid (2,4-D; 4.5, 9, 13.5, and 18 μM). The level of 2,4-D, the type of explant, and the genotype significantly effected callus induction. Calli from each of the three explant types developed somatic embryos on MS medium containing 2.22 μM 6-benzyladenine (BA) and either 1.13, 2.25, or 4.5 μM of 2,4-D. Somatic embryos developed from all three explants and generated shoots on MS medium containing high levels of BA (4.4, 8.8, or 13.2 μM) combined with 0.56 μM 2,4-D. The calli from the immature inflorescences exhibited the highest percentage of somatic embryogenesis and shoot regeneration. Moreover, these calli yielded the maximum number of differentiated shoots per callus. An efficient and direct shoot organogenesis protocol, without a visible, intervening callus stage, was successfully developed from shoot tip explants of both genotypes of pearl millet. Multiple shoots were induced on MS medium containing either BA or kinetin (4.4, 8.8, 17.6, or 26.4 μM). The number of shoots formed per shoot tip was significantly influenced by the level of cytokinin (BA/kinetin) and genotype. Maximum rooting was induced in 1/2 strength MS with 0.8% activated charcoal. The regenerated plants were transferred to soil in pots, where they exhibited normal growth.     

Genotype, explant and position effects on organogenesis and somatic embryogenesis in eggplant (Solanum melongena L.)

The relative importance of genotype and explant, and their interactionsfor in vitro plant regeneration via both organogenesis and somaticembryogenesis in Solanum melongena (eggplant) has been studied.Hypocotyl, cotyledon and leaf explants of four commerciallygrown Indian cultivars, Pusa Purple Long, Long White Cluster,Pusa Kranti, and Pusa Purple Cluster were used in the study.A combination of benzyladen-ine (11.1 µM) and indoleaceticacid (2.9 µM) was found to be optimum for shoot regeneration.Naphthalene acetic acid induced embryogenesis in all the threeexplants; 32.2µM was optimum for hypocotyl explants while10.7µM yielded maximum number of somatic embryos fromcotyledon and leaf explants. Genotype, explant and genotype-explantinteraction had highly significant effects on both organogenesisand somatic embryogenesis with genotype exerting maximum effecton both these processes. Pusa Purple Long was found to be themost responsive genotype for regeneration of both adventitiousshoots and somatic embryos among the cultivars. Among the explants,hypocotyls yielded the maximum number of adventitious shootsfollowed by cotyledons and leaves. The embryogenic responseof leaves and cotyledons was, however, significantly higherthan that of hypocotyl explants. Significant differences formorphogenetic potential were also observed within a single explant(hypocotyl). There was a basipetal gradient for organogenesis(i.e. decrease in number of shoots from base to apex) whilethe terminal hypocotyl segments showed better embryogenic potentialthan the median segments. Key words: Solarium melongena, organogenesis, somatic embryogenesis, genotype, explant, position effect     

The growth regulators used for bud regeneration and shoot rooting affect the competence for flowering and seed set in regenerated plants of protein peas

Summary The production of whole plants from explants of protein pea (Pisum sativum L.) using an efficient, reliable and rapid strategy, while maintaining trueness to type, will be required before regeneration can be exploited for genetic transformation. Seeds of the pea genotypes Terese, Solara, Frisson and P64 (a hypernodulating mutant line of Frisson) were surface-sterilized and imbibed overnight, whereafter embryo axes were dissected and germinated on hormone-free medium for 7–10 d. Hypocotyl sections lacking pre-existing meristems were harvested and cultured on a range of media with various concentrations and combinations of growth regulators in order to induce either caulogenesis or somatic embryogenesis. Differences in responsiveness were apparent between genotypes, but regeneration via caulogenesis was consistently more reliable than via the induction of somatic embryos. Few explants underwent somatic embryo production and their conversion into plants has remained elusive so far, irrespective of the genotype studied. Conversely, large numbers of buds were produced within 10 d by organogenesis, and healthy, rootable shoots were obtained. A clear relationship was observed between the growth regulators employed for bud regeneration and shoot rooting phases and the subsequent competence of the regenerated plants for flowering, pod formation and viable seed production.     

In vitro propagation of an endangered medicinal plant Saussurea involucrata Kar. et Kir.

An efficient micropropagation system for Saussurea involucrata Kar. et Kir., an endangered Chinese medicinal plant, has been developed. Shoot organogenesis occurred from S. involucrata leaf explants inoculated on medium with appropriate supplements of plant growth regulators. 66.0% of shoot regeneration frequency and 5.2 shoots per leaf explant were achieved when cultured on a medium containing 10 μM 6-benzylaminopurine (BAP) and 2.5 μM 1-naphthaleneacetic acid (NAA). Shoot organogenesis was improved further when the leaf explants were pre-incubated at low temperature, and 80.6% of shoot regeneration frequency was recorded with 9.3 shoots per leaf explant at 4°C by 5-day pretreatment period. Up to 87.0% of the regenerated shoots formed complete plantlets on a medium containing 2.5 μM indole-3-acetic acid (IAA) within 28 days, and 85.2% of the regenerated plantlets survived and grew vigorously in greenhouse condition. The phytochemical profile of the micropropagated plants was similar to that of wild plants. The regeneration protocol developed in this study provides a basis for germplasm conservation and for further investigation of medicinally active constituents of the elite medicinal plant.     

Regeneration of <Emphasis Type="Italic">Pelargonium × hederaefolium</Emphasis> ‘Bonete’ from petiole explants

The adventitious shoot regeneration from petiole explants of Pelargonium × hederaefolium ‘Bonete’ was achieved via a mixed pathway i.e. organogenesis and somatic embryogenesis. The histological study of regenerated structures revealed the presence of both shoot primordia and embryo-like structures. The initial growth in petiole explants occurred on media with BAP + auxin or TDZ alone. However, the most effective regeneration (24 structures/explant) was noted in the presence of TDZ (2 mg l⁻¹) and IBA (0.1 or 0.2 mg l⁻¹). Moreover, the application of TDZ in the induction phase reduced the time needed for the formation of adventitious structures and positively influenced the further shoot development on the medium containing m-topolin and IBA.     

Somatic embryogenesis and plant regeneration from floral explants of cacao (Theobroma cacao L.) using thidiazuron

Summary A procedure for the regeneration of cacao (Theobroma cacao) plants from staminode explants via somatic embryogenesis was developed. Rapidly growing calli were induced by culturing staminode explants on a DKW salts-based primary callus growth (PCG) medium supplemented with 20 g glucose per L, 9 μM 2,4-D, and thidiazuron (TDZ) at various concentrations. Calli were subcultured onto a WPM salts-based secondary callus growth medium supplemented with 20 g glucose per L, 9 μM 2,4-D, and 1.4 nM kinetin. Somatic embryos were formed from embryogenic calli following transfer to a hormone-free DKW salts-based embryo development medium containing sucrose. The concentration of TDZ used in PCG medium significantly affected the rate of callus growth, the frequency of embryogenesis, and the number of somatic embryos produced from each responsive explant. A TDZ concentration of 22.7 nM was found to be the optimal concentration for effective induction of somatic embryos from various cacao genotypes. Using this procedure, we recovered somatic embryos from all 19 tested cacao genotypes, representing three major genetic group types. However, among these genotypes, a wide range of variation was observed in both the frequency of embryogenesis, which ranged from 1 to 100%, and the average number of somatic embryos produced from each responsive explant, which ranged from 2 to 46. Two types of somatic embryos were identified on the basis of their visual appearance and growth behavior. A large number of cacao plants have been regenerated from somatic embryos and established in soil in a greenhouse. Plants showed morphological and growth characteristics similar to those of seed-derived plants. The described procedure may allow for the practical use of somatic embryogenesis for clonal propagation of elite cacao clones and other applications that require the production of a large number of plants from limited source materials.     

Genotype and explant-type dependent morphogenesis and silicon response of common reed (Phragmites australis) tissue cultures

The effects of silicon on the growth and development of Phragmites australis (Cav.) Trin. Ex Steud. (common reed) stem nodal and root embryogenic calli were investigated. Silicon is considered to be a beneficial or quasi-essential nutrient for several Gramineaceous plants, including reed. Seven callus lines of four geographical locations (genotypes 1-4) within Hungary were investigated. Callus lines 1A, 2A and 3A were produced from stem nodal explants, while lines 1B, 2B, 3B and 4 were produced from roots. For the assay of silicon-dependent growth of callus lines of identical genotype but originating from different explants, we measured the increase of fresh weight of lines 1A and 1B. The studied developmental parameters were the increase of the number of somatic embryos (for callus lines 1A and 1B) and plant or root production from somatic embryos (for all genotypes/callus lines). Silicon was added to the culture medium as sodium silicate. In control cultures, plant or root regeneration from embryogenic calli was strongly genotype- and explant type-dependent. Stem nodal explants developed plants on regeneration medium in case of callus lines 2A and 3A, while line 1A produced roots only. All root derived calli developed roots on regeneration medium. Silicon stimulated the growth of both stem nodal and root calli (callus lines 1A, B) however, the concentration optima were different. Somatic embryogenesis of root calli, but not of stem nodal calli, was stimulated by silicate at low concentrations. However, for both of these callus lines, root development was stimulated by silicon. It had genotype-dependent influences on plant regeneration: while stimulation was observed in case of callus line 2A, inhibition occurred for line 3A. Root morphogenesis on calli was significantly influenced by silicon and depended on the callus line studied. Root production was stimulated on callus lines 1A, B and 2B, while in case of callus line 3B, it was significantly inhibited. The morphogenetic effects of Si were similar for different explants of the same geographical origin, i.e. plant or root production was similarly stimulated or inhibited by this element. We can conclude that the effects of Si on plant or root development depend on reed genotype used for callus induction. Its effect on growth and somatic embryogenesis depends on the explant type used for callus production. This is the first detailed report on the role of silicon in plant vegetative development and morphogenesis of a Gramineaceous plant.     

Plant Regeneration from Wheat Leaf Explants

The factors affecting the callus formation and regeneration capacity of leaf explants of four genotypes of the genus Triticum, viz. T. aestivum, cvs. Taezhnaya and Chinese Spring; T. durum, cv. Kollektivnaya; and T. persicum, were investigated. The process of callus formation did not depend on the explant genotype. Apical leaf segments were characterized by the lowest capacity of callus formation. In contrast, the rate of plant regeneration was correlated with the genotype and the explant developmental stage. The highest number of regenerants was obtained from a basal segment of three-day-old seedlings ofT. aestivum, cv. Taezhnaya. The yield of plants from one explant was doubled due to the use of maltose in the regeneration medium. The prospects of using leaf segments as the explants for the genetic transformation of wheat plants are discussed.     

Plant regeneration via somatic embryogenesis in cotton

An efficient in vitro plant regeneration system characterized by rapid and continuous production of somatic embryos using leaf and stem explants of abnormal seedling as an explant have been developed in Gossypium hirsutum L. Embryogenic callus and somatic embryos have been obtained directly from the explants of cotton abnormal seedlings. Plant growth regulators influenced the induction of cotton somatic embryogenesis. The optimal medium for direct somatic embryogenesis was modified MS medium supplemented with 0.1 mg l^-1 ZT and 2 g l^-1 activated carbon. On this medium, an average of 28.0 and 28.1 matured somatic embryos formed from per leaf and stem explants respectively. The highest frequency of somatic embryogenesis was 100%. The somatic embryos were converted into normal plantlets when cultured on modified MS medium supplemented with 0.1 mg l^-1 ZT. Upon transfer to soil, plants grew well and appeared normal. Plants could be regenerated within 60–80 days. The system of cotton somatic embryogenesis and plant regeneration described here will facilitate the application of plant tissue culture and genetic engineering on cotton genetic improvement. This revised version was published online in June 2006 with corrections to the Cover Date.     

Somatic embryogenesis and organogenesis inGuizotia Abyssinica

Summary Induction of somatic embryogenesis, shoot organogenesis, and subsequent plant regeneration in niger seem to be dependent on genotype, choice of explant, and composition of media growth regulators. Two distinct regeneration protocols have been developed for somatic embryogenesis and shoot organogenesis. Somatic embryogenesis was induced from epicotyls and cotyledonary explants (9 to 35%) (but not from hypocotyls and roots) in presence of 2,4-dichlorophenoxyacetic acid, 2,4,5-trichlorophenoxyacetic acid, and 2,4,5-trichlorophenoxypropionic acid. These embryos matured in MS medium containing Kinetin plus naphthalene acetic acid (NAA), Kinetin plus Zeatin, and Kinetin plus abscisic acid (ABA). Matured embryos could be germinated on LS and MS basal media without hormones. Non-embryogenic callus initiated on Linsmaier and Skoog&#x2019;s (LS) medium from cotyledons of six different genotypes produced shoots (9 to 32%) on Murashige and Skoog&#x2019;s (MS) medium fortified with 6-benzylaminopurine (BAP, 0.5 mg &#x00B7; liter^&#x2212;1), and BAP (1 mg &#x00B7; liter^&#x2212;1) plus NAA (0.1 mg &#x00B7; liter^&#x2212;1). These shoots were rooted with 100% frequency by using indole-3-acetic acid or NAA and transferred successfully to the soil.     

<Emphasis Type="Italic">Brassica</Emphasis> biotechnology: Progress in cellular and molecular biology

Summary Considerable progress has been accomplished in the cellular and molecular biology of Brassica species in the past few years. Plant regeneration has been increasingly optimized via organogenesis and somatic embryogenesis using various explants; with tissue culture improvements focusing on factors such as age of the explant, genotype, and media additives. The production of haploids and doubled haploids using microspores has accelerated the production of homozygous lines in the Brassica species. Somatic cell fusion has facilitated the development of interspecific and intergeneric hybrids in the sexually incompatible species of Brassica. Crop improvement using somaclonal variation has also been achieved. The use of molecular markers in marker-assisted selection and breeding, transformation technology for the introduction of desirable traits, and a comparative analysis of these as well as their future prospects are important parts of the current research that is reviewed.     

In vitro plant regeneration of Arachis correntina (Leguminosae) through somatic embryogenesis and organogenesis

In vitro protocols for plant regeneration of Arachis correntina through both somatic embryogenesis and organogenesis were developed using immature leaves as explants. Morphologically normal somatic embryos were obtained on culture media composed of 20.70 or 41.41 μM picloram (PIC) with the addition of 0.044 μM 6-benzylaminopurine (BA), resulting in a 33 and 24% of conversion into plants, respectively. The source of explants and the developmental stage of the leaves had a marked effect on somatic embryogenesis. The second folded immature leaves from in vitro growing plants were the most responsive producing up to 30% embryogenesis in MS+41.41 μM PIC. Embryos converted into plants after transfer to MS medium devoid of growth regulators and these plants were successfully acclimatised. Adventitious shoots were obtained on culture media supplemented with 2,4-dichlorophenoxyacetic acid (2,4-D) or naphthaleneacetic acid (NAA) with or without 0.044 μM BA, achieving plant regeneration in the induction media. The highest percentage of bud formation was obtained on culture medium composed of␣MS+10.74 μM NAA+0.044 μM BA (12.5%). Roots were formed on all culture media tested. Regenerated plants were transferred to pots and grew well under greenhouse conditions.     

Developmental and hormonal regulation of direct shoot organogenesis and somatic embryogenesis in sugarcane (Saccharum spp. interspecific hybrids) leaf culture

Rapid and efficient in vitro regeneration methods that minimise somaclonal variation are critical for the genetic transformation and mass propagation of commercial varieties. Using a transverse thin cell layer culture system, we have identified some of the developmental and physiological constraints that limit high-frequency regeneration in sugarcane leaf tissue. Tissue polarity and consequently the orientation of the explant in culture, size and developmental phase of explant, and auxin concentration play a significant role in determining the organogenic potential of leaf tissue in culture. Both adventitious shoot production and somatic embryogenesis occurred on the proximal cut surface of the explant, and a regeneration gradient, decreasing gradually from the basal to the distal end, exists in the leaf roll. Importantly, auxin, when added to the culture medium, reduced this spatial developmental constraint, as well as the effect of genotype on plant regeneration. Transverse sections (1-2 mm thick) obtained from young leaf spindle rolls and orienting explants with its distal end facing the medium (directly in contact with medium) are critical for maximum regeneration. Shoot regeneration was observed as early as 3 weeks on MS medium supplemented with alpha-naphthalenencetic acid (NAA) and 6-benzyladenine, while somatic embryogenesis or both adventitious shoot organogenesis and somatic embryogenesis occurred on medium with NAA and chlorophenoxyacetic acid. Twenty shoots or more could be generated from a single transverse section explant. These shoots regenerated roots and successfully established after transplanted to pots. Large numbers of plantlets can be regenerated directly and rapidly using this system. SmartSett, the registered name for this process and the plants produced, will have significant practical applications for the mass propagation of new cultivars and in genetic modification programs. The SmartSett system has already been used commercially to produce substantial numbers of plants of orange rust-resistant and new cultivars in Australia.     

Improvement of tissue culture,genetic transformation,and applications of biotechnology to Brassica

Development of in vitro plant regeneration method from Brassica explants via organogenesis and somatic embryogenesis is influenced by many factors such as culture environment, culture medium composition, explant sources, and genotypes which are reviewed in this study. An efficient in vitro regeneration system to allow genetic transformation of Brassica is a crucial tool for improving its economical value. Methods to optimize transformation protocols for the efficient introduction of desirable traits, and a comparative analysis of these methods are also reviewed. Hence, binary vectors, selectable marker genes, minimum inhibitory concentration of selection agents, reporter marker genes, preculture media, Agrobacterium concentration and regeneration ability of putative transformants for improvement of Agrobacterium-mediated transformation of Brassica are discussed.     

In vitro morphogenetic responses from obligatory apomictic Taraxacum belorussicum Val. N. Tikhom seedlings explants

Taraxacum belorussicum Val. N. Tikhom, a poorly known and obligatory apomictic species, is an attractive plant material for studying the embryological, genetic and molecular mechanisms of apomixis. This work aims to obtain an efficient protocol for Taraxacum belorussicum regeneration. Four types of explants (cotyledons, hypocotyls, meristems and roots) that were taken from 2-weeks-old seedlings were used for in vitro cultures, and a fast and efficient protocol of T. belorussicum regeneration was obtained. Various ½ MS-based media containing IAA (5.71 µM), TDZ (4.54 µM) and PSK (100 nM) were chosen to assess the morphogenetic abilities of selected T. belorussicum explants. Studies on the role of PSK were done in three independent experiments, where the most significant factors were always light and darkness. All explants produced callus by the third day of culture and adventitious shoots after 7 days, although in an asynchronous indirect manner, and with different intensities for all explant types. The most preferred medium culture for hypocotyl, cotyledon and meristem explants was ½ MS?+?TDZ, and ½ MS?+?IAA?+?TDZ?+?PSK for roots which were the only explant sensitive to PSK. A short darkness pretreatment (8 days) in PSK medium was found suitable to enhance organogenesis. Secondary organogenesis was observed for regenerated plants on meristem explants from the ½ MS?+?IAA?+?TDZ?+?PSK medium. A weak somatic embryogenesis was observed for hypocotyl and cotyledon explants from ½ MS?+?IAA?+?TDZ and ½ MS?+?IAA?+?TDZ?+?PSK media. Histological and scanning electron microscope images (SEM) of T. belorussicum confirmed indirect organogenesis and somatic embryogenesis. Plant material treated with aniline blue solution revealed the presence of callose in the cell walls of cotyledon and hypocotyl explants. The presence of extracellular matrix (ECM) and heterogenic structure of callus was also verified by scanning electron microscopy and light microscopy, confirming the high morphogenetic ability of T. belorussicum.

     

Production of plants resistant to <Emphasis Type="Italic">Alternaria carthami</Emphasis> via organogenesis and somatic embryogenesis of safflower cv. NARI-6 treated with fungal culture filtrates

The present study describes a system for efficient plant regeneration via organogenesis and somatic embryogenesis of safflower (Carthamus tinctorius L.) cv. NARI-6 in fungal culture filtrates (FCF)-treated cultures. FCF was prepared by culturing Alternaria carthami fungal mycelia in selection medium for host-specific toxin production. Cotyledon explants cultured on callus induction medium with different levels of FCF (10–50%) produced embryogenic callus. In organogenesis, 42.2% microshoots formed directly from embryogenic callus tissues in plant regeneration medium with 40% FCF. Isolated embryogenic callus cultured on embryo induction medium containing 40% FCF induced 50.2% somatic embryogenesis. Embryo germination percentage was decreased from 64.5 to 28 in embryo maturation medium containing 40% FCF. However, nine plantlets from organogenesis and 24 plantlets from somatic embryogenesis were selected as FCF-tolerant. Alternaria carthami fungal spores (5 × 10⁵ spores/ml) sprayed on the leaves of FCF-tolerant plants showed enhanced survival rate over control plants, which plants were more susceptible to fungal attack. The number of leaf spot lesions per leaf was decreased from 3.4 to 0.9 and their lesion length was also reduced from 2.9 to 0.7 mm in organogenic derived FCF-tolerant plants over control. In somatic embryo derived FCF-tolerant plants, the number of lesions was decreased from 3.1 to 0.4 and the lesion size was also reduced to 2.7–0.5 mm when compared to the control. This study also examined antioxidant enzyme activity in FCF-tolerant plants. Catalase (CAT) activity was slightly decreased whereas peroxidase (POD) activity was increased to a maximum of 42% (0.19 μmol min⁻¹ mg⁻¹ protein) from organogenesis and 47% (0.23 μmol min⁻¹ mg⁻¹ protein) from embryogenesis in FCF-tolerant plants. Superoxide dismutase (SOD) activity was also increased to 17% (149 U mg⁻¹ protein) and 19.5% (145 U mg⁻¹ protein) in FCF-tolerant plants derived from organogenesis and somatic embryogenesis when compared with control plants.     

Anther culture with different genotypes of opium poppy (Papaver somniferum L.): effect of cold treatment

This study concerns anther culture and the production of microspore-derived calluses and plants of the opium poppy (Papaver somniferum L.). It was confirmed that growth regulators were necessary for microspore callus production. Cold treatment (7 d at 7°C) of the buds prior to culture lead to a twofold increase in the frequency of responsive anthers and in the number of calluses per 100 anthers plated. Callus was produced from cultured anthers of several genotypes, covering a wide genetic background. Step by step removal of growth regulators from the culture medium promoted organogenesis and plant regeneration. Most regenerated plants were diploid. The overall process of microspore embryogenesis closely resembled that described in previous reports on somatic callus production and plant regeneration from poppy hypocotyls in vitro.     

Genotypic response of cowpea Vigna unguiculata (L.) to in vitro regeneration from cotyledon explants

Summary A plant regeneration system applicable to 17 cowpea genotypes was developed. Cotyledons were initiated on 1/3 MS medium containing 15 to 35 mg N⁶-benzyladenine (BA) per 1 (66.6 to 155.3 μM) for 5 to 15 d. For shoot regeneration, the explants were transferred to a medium containing 1 mg BA per 1 (4.4 μM). Within 1 wk, shoot formation was visible at the proximal end of the cotyledons. Regeneration percentages (1% to 11%) and the numbers of shoots (4 to 12 per explant) were significantly influenced by genotype. Culture duration and BA concentration in the initiation stage significantly affected regeneration capacity. Explants initiated on media containing 15 mg BA per 1 for 5 d resulted in the highest percentage of explants capable of regeneration. Conversely, the highest number of shoots was obtained from explants initiated on media supplemented with 35 mg BA per 1. Whole plants were obtained on a plant growth regulator-free medium. To our knowledge, this is the first report of plant regeneration from U.S. commercial cowpea cultivars and breeding lines. This system is adaptable to diverse cowpea genotypes and will facilitate cowpea genetic transformation. Published with the approval of the Director of the Arkansas Agricultural Experiment Station.     

Influence of plant preservative mixture (PPM)TM on adventitious organogenesis in melon, petunia, and tobacco

Summary The influence of PPM^TM on somatic embryogenesis in melon, adventitious shoot organogenesis in petunia, and androgenesis in tobacco was studied by culturing explants in regeneration media supplemented with 0, 2, 5 or 10 ml l⁻¹ PPM for 8–12 wk. The percentage of melon cotyledon explants that produced callus and somatic embryos and the number of embryos per explant were reduced when incubated in embryo initiation and embryo development media containing more than 5 ml l⁻¹ PPM. Less PPM was required to inhibit petunia shoot organogenesis. The number of shoots and number of buds per Petri dish were reduced 3–6.9-fold when leaf explants were incubated in shoot regeneration medium containing more than 2 ml l⁻¹ PPM. In contrast, the addition of up to 10 ml l⁻¹ PPM to tobacco anther culture medium had no effect on androgenesis. Our results suggest that the influence of PPM on plant regeneration depends on the plant species. We recommend that experimenters examine a range of PPM concentrations when using it for the first time on an untested plant species.     

Recent advances in Pelargonium in vitro regeneration systems

Recent advances in the development of protocols for in vitro culture and genetic manipulation have provided new avenues for the development of novel varieties of Pelargonium and for use as model systems for investigating the factors controlling plant morphogenesis. Optimized techniques of meristem culture have supplemented the culture indexing methods in commercial greenhouse production resulting in availability of large-scale pathogen indexed planting material. Currently, technologies are available for the mass in vitro propagation of F1 hybrid Pelargonium through both organogenesis and somatic embryogenesis. The somatic embryogenesis model system has allowed researchers to identify critical factors controlling plant morphogenesis in vitro such as regulation of regeneration by growth regulators, choice of explant and characterization of induction and expression phases of morphogenesis in Pelargonium. Also, optimization of technologies for genetic transformation of Pelargonium opened up the possibilities for developing genotypes with novel characters, including resistance to some of the major diseases. Finally, the development of regeneration systems for Pelargonium spp. has facilitated conventional crop improvement programs, thereby providing a valuable resource to the horticultural industry.