Competence and determination in the process of in vitro shoot organogenesis

Leaf explants of Convolvulus arvensis produce shoots when cultured on Murashige and Skoog salts, sucrose, vitamins and 0.05 mg/liter IAA plus 7.0 mg/liter 2-isopentenyl adenine. Shoot-inducing, root-inducing, or callus-inducing medium (SIM, RIM, or CIM) will cause small amounts of callus to form at the cut edges of the explant. This first-formed callus is developmentally interchangeable: SIM induces shoots in callus formed on CIM or SIM with equal effect and efficiency. Once induction begins in competent callus, the callus is no longer interchangeable. Under the continued influence of SIM, cells, or groups of cells become determined for shoot formation. This determination is strongly canalized for shoot formation: subsequent transfer to root-inducing medium does not affect the formation of shoots by the explant. The control of organogenesis by the auxin/cytokinin balance must occur between the time the tissue becomes competent and the time it is determined for shoot (or root) development. It is not known whether this control is a single or multiple phenomenon.     

Abscisic acid promotes shoot regeneration in Arabidopsis zygotic embryo explants

An efficient shoot organogenesis protocol for Arabidopsis zygotic embryo explants of Landsberg erecta ecotype was established. This de novo shoot organogenesis protocol has three different steps, i.e., induction of callus in an auxin-rich callus induction medium, the formation of green-organogenic callus in the shoot induction medium (SIM), and the final morphological differentiation of shoot in the hormone-free shoot development medium (SDM). Abscisic acid (ABA), auxin, and cytokinin (CK) were used in the SIM. Individual plant growth regulators as well as their combination were studied to understand their importance in the shoot induction treatment. We found that a combination of ABA + CK and ABA + CK + auxin induced higher shoot organogenic ability in the callus than ABA, CK, and auxin alone. Optimum ABA concentration on shoot organogenesis was determined to be 10^?5 M. Morphological characterization of callus induction and shoot organogenesis events indicated that calli were derived from the cotyledons of zygotic embryo explants and the formation of green organogenic calli was specific to the exogenous inclusion of ABA + CK in the SIM. During the time of shoot development, the green organogenic callus became darker green due to the formation of anthocyanins. Shoot organogenic calli in the SIM and the SDM were easily identified by the green-colored calli and anthocyanin pigments, respectively. Furthermore, we demonstrated the significance of exogenous and endogenous ABA in shoot organogenesis by fluridone treatments. The inclusion of ABA in SIM has a significant effect on shoot formation.     

Inorganic nitrogen requirements during shoot organogenesis in tobacco leaf discs

The role of nitrate, ammonium, and culture medium pH on shoot organogenesis in Nicotiana tabacum zz100 leaf discs was examined. The nitrogen composition of a basal liquid shoot induction medium (SIM) containing 39.4 mM and 20.6 mM was altered whilst maintaining the overall ionic balance with Na(+) and Cl(-) ions. Omission of total nitrogen and nitrate, but not ammonium, from SIM prevented the initiation and formation of shoots. When nitrate was used as the sole source of nitrogen, a high frequency of explants initiated and produced leafy shoots. However, the numbers of shoots produced were significantly fewer than the control SIM. Buffering nitrate-only media with the organic acid 2[N-morpholino]ethanesulphonic acid (MES) could not compensate for the omission of ammonium. Ammonium used as the sole source of nitrogen appeared to have a negative effect on explant growth and morphogenesis, with a significant lowering of media pH. Buffering ammonium-only media with MES stabilized pH and allowed a low frequency of explants to initiate shoot meristems. However, no further differentiation into leafy shoots was observed. The amount of available nitrogen appears to be less important than the ratio between nitrate and ammonium. Shoot formation was achieved with a wide range of ratios, but media containing 40 mM nitrate and 20 mM ammonium (70:30) produced the greatest number of shoots per explant. Results from this study indicate a synergistic effect between ammonium and nitrate on shoot organogenesis independent of culture medium pH.     

Comparison of Benzyl Adenine Metabolism in Two Petunia hybrida Lines Differing in Shoot Organogenesis

The uptake and metabolism of the cytokinin benzyl adenine (BA) was compared in two lines of Petunia hybrida Vilm. differing in their shoot organogenic response. Leaf transfer experiments using shoot induction medium containing 4.4 micromolar BA showed that leaf explants from petunia line St40 required a shoot induction period of 6 to 10 days for commitment to shoot organogenesis; whereas leaf explants from petunia TLV1 required 12 to 28 days. The short induction period of petunia St40 and the higher organogenic response was positively associated with a threefold higher absorption of BA from the medium, an increased BA ribotide metabolite pool, the presence of BA within the explant during the shoot induction period, and the production of an unidentified metabolite C. However, the study of petunia TLV1 leaf explants showed that neither BA nor metabolite C are required during the shoot induction period for eventual shoot development. The longer shoot induction period of TLV1 was associated with low BA uptake during 24 days, a decreasing ribotide metabolite pool, the absence of benzyl adenosine triphosphate and metabolite C throughout the study, and the absence of BA within the explant during the shoot induction period. Differences in the shoot organogenic response of these related plant lines have been shown to be associated with differences in exogenous cytokinin uptake and the subsequent metabolism of that hormone.     

Direct shoot organogenesis from leaf explants of Populus deltoides and changes in selected enzymatic activities

The direct shoot organogenesis was achieved from leaf explant of two commercially important clones of Populus deltoides on MS medium enriched with 15 mg/l adenine sulphate, 5 mg/l Ascorbic acid, 250 mg/l (NH4)2SO4 (referred to as PD1 medium) supplemented with 2.5 µM each of 6-benzylaminopurine and indole-3-acetic acid. Higher shoot organogenic potential was recorded from the explants of clone ‘G48’ as compared to clone ‘L34’. The age of leaf explant also affected the shoot organogenic potential, and maximum shoot organogenesis was recorded in case of 5th leaf from the top of microshoot. Histological studies revealed altered cell division resulting in the formation of meristematic pockets after 5 days of culture, these meristematic pockets grew into dome protuberances by 10th day. Organized shoots were visible after 15 days of culture. A clear three phases of shoot organogenesis viz induction (0–4 days), initiation and organization (4–10 days) and growth (11–16 days onwards) were observed. Marked variation in the activity of enzymes such as catalase, peroxidase, polyphenol oxidase and acid phosphatase was observed during these phases. The activity of these enzymes was found to increase in cultures grown on the medium resulting in shoot organogenesis during shoot development (after 7 days of culture).     

Organogenesis in cultured petiole explants of Begonia erythrophylla: the timing and specificity of the inductive stimuli

Caulogenesis and rhizogenesis were studied in cultured petioleexplants of Begonia erythrophylla in order to link the developmentalstages of primordia initiation with the physiological requirementsof the explant. Petiole sections excised from B. etythrophyllaplants grown in vitro, were highly organogenic, with shootsand roots arising directly from cells of epidermal origin. Epidermalcells associated with glandular hairs appeared to be most responsiveto organogenic stimuli. The point of explant determination foreach form of organogenesis was ascertained by media transferexperiments. Explants became determined for caulogenesis after7 d exposure to shoot-inducing medium (SIM), while requiring3 d on root-inducing medium (RIM) for determination. Explantswere strongly canalized for caulogenesis once determined, but5 d on RIM were required before becoming strongly canalizedfor rhizogenesis. No organ specific differentiation was observedat the point of determination for explants exposed to eithershoot- or root-inducing conditions. Preculture on a basal mediumcontaining no growth regulators resulted in a gradual loss ofcompetence with time, but preculture for up to 2 d on SIM orRIM resulted in a reduction in the time for determination forboth forms of organogenesis. Key words: Organogenesis, Begonia erythrophylla, tissue culture, epidermis, determination     

Tiba inhibition of <Emphasis Type="Italic">in vitro</Emphasis> organogenesis in excised tobacco leaf explants

Summary Triiodobenzoic acid (TIBA), an anti-auxin, was found to inhibit both shoot and root formation in cultured excised leaf explants of tobacco (Nicotiana tabacum L.). The shoot formation (SF) medium used required only exogenous cytokinin (N⁶-benzyladenine) and the root formation (RF) medium required both auxin (indole-3-butyric acid) and cytokinin (kinetin). By transferring the explants from SF or RF media to SF or RF media with TIBA (4.0×10⁻⁵ M), respectively or vice versa, at different times in culture, it was found that TIBA inhibition was at the time of meristemoid formation and after determination of organogenesis. This indicates that TIBA interfered with endogenous auxin involvement in organized cell division.     

Oxidative events during in vitro regeneration of sunflower

The changes in the activity of some antioxidant enzymes and endogenous H₂O₂ level in zygotic sunflower embryos during organogenesis and somatic embryogenesis were monitored. Pathways of regeneration were induced on media differing with sucrose concentration 87 mmol dm⁻³ for shoot [shoot induction medium (SIM) medium] and 350 mmol dm⁻³ [embryo induction medium (EIM) medium] for somatic embryo induction. Water potential of the explants cultured on SIM increased, while the embryos maintained on EIM showed middle water deficit stress. The pattern of superoxide dismutase (SOD) isoforms was similar in organogenic and embryogenic culture; however, the intensity of MnSOD bands was higher on SIM than on EIM. Differences in catalase activity were observed: high activity on SIM predominated, whereas on EIM it was reduced. The activity of guaiacol peroxidase in the explants producing shoots and somatic embryos differed at the beginning of culture, but became comparable at the time of shoot and somatic embryo formation (day 5). H₂O₂ content was unchanged in organogenic culture, but on EIM it increased on day 1 followed by significant decrease. The results indicate that sugar concentration per se, or via induction of different developmental pathways influences the activity of antioxidant enzymes and also H₂O₂ level in cultured sunflower embryos.     

An improved protocol for micropropagation of Mallotus repandus (Willd.) Müll.Arg.

Node and internode explants of Mallotus repandus were precultured on basal medium (BM: Murashige and Skoog (MS) medium with 3% sucrose and 0.55% Agargel) for 0–18 d before culture on shoot induction Medium (SIM: BM added with 4.44 μM of benzylaminopurine) for 4 wk. The cultures were subsequently transferred to BM for 4 wk for shoot elongation. Node explants precultured on BM for 14 d before incubation on SIM were at an optimum for shoot regeneration with the response rate of 95%, compared to a 21% response for the control without preculture. Internode explants precultured on BM for 16 d responded with an optimal shoot formation response rate of 69%, whereas the control response rate was 6%. The maximum shoot regeneration rates were 3.1 ± 0.3 and 2.7 ± 0.4 shoots/responding explant in node and internode explants, respectively. This study demonstrates for the first time that shoot organogenesis can be induced from internode explants of M. repandus. Furthermore, the results suggest that the explants need to acquire competence before shoot organogenesis. Rooting was obtained by incubation of regenerated shoots on half-strength MS with 10.74 μM of 1-naphthylacetic acid for a week before culture on half-strength MS for 4 wk. Regenerated plants were successfully transferred to soil.     

Developmental events and shoot apical meristem gene expression patterns during shoot development in Arabidopsis thaliana

Critical developmental and gene expression profiles were charted during the formation of shoots from root explants in Arabidopsis tissue culture. Shoot organogenesis is a two-step process involving pre-incubation on an auxin-rich callus induction medium (CIM) during which time root explants acquire competence to form shoots during subsequent incubation on a cytokinin-rich shoot induction medium (SIM). At a histological level, the organization of shoot apical meristems (SAMs) appears to occur during incubation on SIM about the time of shoot commitment, i.e. the transition from hormone-dependent to hormone-independent shoot development. Genes involved in SAM formation, such as SHOOTMERISTEMLESS (STM) and CLAVATA1 (CLV1), were upregulated at about the time of shoot commitment, while WUSCHEL (WUS) was upregulated somewhat earlier. Genes required for STM expression, such as CUP-SHAPED COTYLEDON 1 and 2 (CUC1 and 2) were upregulated prior to shoot commitment. Gene expression patterns were determined for two GFP enhancer trap lines with tissue-specific expression in the SAM, including one line reporting on CUC1 expression. CUC1 was generally expressed in callus tissue during early incubation on SIM, but later CUC1 was expressed more locally in presumptive sites of shoot formation. In contrast, the expression pattern of the enhancer trap lines during zygotic embryogenesis was more localized to the presumptive SAM even in early stages of embryogenesis.     

The role of cytokinins in shoot organogenesis in apple

Effective regeneration in vitro is a necessary precondition for the implementation of different biotechnological approaches in plant breeding. Numerous studies have reported on regeneration from apple somatic tissues, and organogenesis has been proved to be influenced by several factors including mother shoots (genotype, size, type, and age of explant), in vitro conditions (dark period, light intensity, and quality), and others (wounding, orientation of leaf explants). However, one of the most important factors before and during the regeneration process is the type and concentration of cytokinin applied. Thidiazuron and benzyladenine are the most frequently used cytokinins in the regeneration systems, but their efficiency depends on genotype and other factors. Other cytokinins (e.g., zeatin and kinetin) have also been tested in several experiments and they were found in general to be less active. The organogenic ability of explants can also be increased by a properly selected cytokinin pre-treatment. Cytokinins applied in the pre-treatments can influence the leaf structure, which in turn can alter the regeneration capacity of the leaf explant. Interactions between factors of pre-treatments (hormones, light, and culture conditions) and factors of the regeneration phase should be considered. This review brings into focus the role of different cytokinins during in vitro shoot development, discussing their effects on the histology of leaves developed in vitro, and how this affects the subsequent regeneration process.     

Adventitious shoot regeneration from Begonia × erythrophylla petiole sections is developmentally sensitive to light quality

The influence of light quality on organogenesis in vitro was investigated using Begonia  ×  erythrophylla petiole explants. Pre-treatment of in vitro donor plants by growth in the dark or under far-red or blue light reduced their competence for shoot formation when compared with those grown under red or white light. Culture of competent petiole explants under far-red, blue light or in the dark reduced the number of shoots produced per explant compared to those cultured under red or white light. Explants were found to be developmentally sensitive to both far-red and blue light, because meristem, but not primordia development was inhibited. In addition, blue light inhibition of shoot formation is not mediated directly through phytochrome, as few shoots formed on explants cultured under a mixture of red and blue light which resulted in a high P _fr/ P _tot (0.82) and would allow shoot formation in the absence of blue light. Unlike the inhibitory influence of far-red light, which is reversible, exposure to blue light permanently reduces an explant's competence for shoot formation. Our results suggest that phytochrome and an independent blue light photoreceptor, possibly a cryptochrome, can regulate shoot production from B. erythrophylla petiole explants.     

Developmental phases and STM expression during Arabidopsis shoot organogenesis

Shoot organogenesis in Arabidopsis thaliana wasstudied with regard to the timing of key developmental phases and expression ofthe SHOOTMERISTEMLESS (STM) gene.Shoot regeneration in the highly organogenic ecotype C24 was affected byexplanttype and age. The percentage of C24 cotyledon explants producing shootsdecreased from 90% to 26% when donor seedlings were more than 6 dold, but 96% of root explants produced shoots regardless of the age of thedonorplant. Using explant transfer experiments, it was shown that C24 cotyledonexplants required about 2 days to become competent and another 8-10 days tobecome determined for shoot organogenesis. A C24 line containing the promoterofthe SHOOTMERISTEMLESS (STM) genelinked to the -glucuronidase(GUS) gene was used as a tool for determining the timingofde novo shoot apical meristem (SAM) development incotyledon and root explants. Cotyledon and root explants from anSTM:GUS transgenic C24 line were placed on shoot inductionmedium and GUS expression was examined after 6-16 days ofculture. GUS expression could be found in localizedregionsof callus cells on root and cotyledon explants after 12 days indicating thatthese groups of cells were expressing the STM gene, hadreached the key time point of determination, and were producing an organizedSAM. This was consistent with the timing of determination as indicated byexplant transfer experiments. Root explants from anSTM:GUStransgenic Landsberg erecta line and a two-step tissue culture method revealedasimilar pattern of localized GUS expression duringde novo shoot organogenesis. This is the first studydocumenting the timing and pattern of expression of theSTMgene during de novo shoot organogenesis.     

Stages in the Initiation of Root and Shoot Organogenesis in Cultured Leaf Explants of Nicotiana tabacum cv. Xanthi nc.

Reciprocal transfers of Nicotiana tabacum cv. Xanthi nc. leafexplants were made daily between root inducing medium (RIM)and shoot inducing medium (SIM), SIM and a basal medium containingno growth regulators (BM), and RIM and BM. It was found thatthe explants became determined for shoot production after 6d, while roots were produced after only 1 d on RIM before transferto BM. The competence of the explant to produce roots was greatlyreduced by culture on BM prior to culture on RIM. There wasfar less reduction in shoot numbers with preculture on BM. Explantswere found to be only weakly canalized for both caulogenesisand rhizogenesis for the first 2 d after determination. Thereafterthey became strongly canalized. Transfers were also made fromBM to SIM and back to BM, which revealed that the explants becamecompetent for caulogenesis in the absence of cytokinins priorto determination. The period for which SIM is required can bereduced to only 1 d. Key words: Nicotiana tabacum, in vitro, organogenesis, competence, determination     

Changes in the starch content during organogenesis in in vitro cultured Begonia rex stem explants

Stem explants, excised from greenhouse-grown Begonia rex plants, were cultured on basal medium (T. Murashige and F. Skoog, Physiol. Plant. 15: 473–497, 1962) contained in sterile Petri dishes. The medium was supplemented with benzyladenine (0.1 mg 1⁻¹) naphthaleneacetic acid (0.01 mg 1⁻¹) and, according to experimental requirements, with either sucrose (3%) or mannitol (3%). Histochemical and biochemical examination of the starch content of the explant was carried out over several days. There was no starch deposition or organogenesis in tissue cultured on mannitol and carbohydrate-free growth medium. The most dramatic finding was the heavy accumulation of starch in tissue cultured on sucrose medium. This copious accumulation preceded any organ formation and was mainly in regions which ultimately gave rise to shoot primordia. The heavy build-up of starch preceding organogenesis was also observed when explants previously cultured on mannitol medium were transferred to medium containing sucrose. During shoot primordia development there was a decrease in the starch content of the cultured tissue indicating the utilization of the polyglucan in the organogenic process.     

CUC2 as an early marker for regeneration competence in Arabidopsis root explants

CUP SHAPED COTELYDON 2 (CUC2) was tested as a marker for shoot induction to monitor and facilitate the optimization of in vitro regeneration of Arabidopsis thaliana. The expression of a pCUC2::3XVENUS-N7 fluorescent marker allowed the observation of early steps in the initiation and development of shoots on root explants. The explants were first incubated on an auxin-rich callus induction medium (CIM) and then transferred to a cytokinin-rich shoot induction medium (SIM). CUC2-expression occurred prior to visible shoot formation during the incubation of the root explant on CIM. Shoot formation was invariably preceded by the accumulation of CUC2 expression at dispersed sites along the root explant. These patches of CUC2-expression also marked the site of lateral root primordium formation in root explants that were transferred to hormone free medium. Thus, CUC2 is a predictive marker for the acquisition of root explant competence for root and shoot organogenesis.     

<Emphasis Type="Italic">In vitro</Emphasis> regeneration of <Emphasis Type="Italic">Salvia nemorosa</Emphasis> L. from shoot tips and leaf explants

Summary Shoot tips and leaves excised from in vitro shoot cultures of Salvia nemorosa were evaluated for their organogenic capacity under in vitro conditions. The best shoot proliferation from shoot tips was obtained on Murashige and Skoog (MS) medium supplemented with 8.9 μM 6-benzylaminopurine (BA) and 2.9 μM indole-3-acetic acid (IAA). Leaf lamina and petiole explants formed shoots through organogenesis via callus stage and/or directly from explant tissue. The highest values for shoot regeneration were obtained with 0.9 μM BA and 2.9 μM IAA for lamina explants. No shoot organogenesis was obtained on leaf explants cultured on MS medium supplemented with α-naphthaleneacetic acid (NAA). The regenerated shoots rooted the best on MS medium containing 0.6 μM IAA or 0.5 μM NAA. In vitro-propagated plants were transferred to soil with a survival rate of 85% after 3 mo.     

Anatomical and ultrastructural analyses of in vitro organogenesis from root explants of commercial passion fruit (Passiflora edulis Sims)

This study aimed to characterize the anatomical events and ultrastructural aspects of direct and indirect in vitro organogenesis in Passiflora edulis. Root explants were cultured on induction medium, supplemented with 4.44 μM 6-benzyladenine. Roots at different stages of development were collected and processed for observation by light microscopy and scanning and transmission electron microscopy. Patterns of direct and indirect regeneration were observed in the explants. During direct organogenesis, the organogenic buds and nodules, formed from meristemoids, originated from the pericycle regions distant from the cut surface. Completely differentiated buds were observed after 20 days of culture. During indirect organogenesis, bud formation occurred via meristemoids at the periphery of the calli, which differentiated from the cortical region of the initial explant. Regardless of the regeneration pattern, the meristemoids had similar ultrastructural characteristics; however, differences were reported in the nuclear shape of the cells of the meristemoids formed directly and indirectly. This study provides important information for enhancing the understanding and characterization of the organogenic process in non-meristematic explants and provides information on the use of roots as explants in genetic transformation protocols for this important tropical species.     

Shoot organogenesis from petiole explants in the aquatic plant Nymphoides indica

A protocol for rapid shoot organogenesis from petiole explants of the ornamental aquatic plantNymphoides indica L. Thwaites O. Kuntze was developed for use in future mutation breeding and cultivar selection studies. Optimum culture conditions for shoot organogenesis were determined. Effects of factorial combinations of 2-iP, BA or kinetin (0–25 μM) in factorial combination with IAA or NAA (0–25 μM) were examined. On the basis of regeneration frequency (80%) and adventitious shoot number (11.5 shoots per explant), most efficient shoot organogenesis occurred on petiole explants cultured on a basal medium consisting of full-strength MS inorganic salts, 0.56 mM myo-inositol, 1.2 μM thiamine-HCl, 116.8 mM sucrose supplemented with 10 μM BA and 20 μM IAA and solidified with 0.8% TC agar. Formation of adventitious shoots by direct and indirect shoot organogenesis from the same explant was verified by histological sectioning. With the exception of variegated leaf production on a single adventitious shoot produced in the presence of 25 μM kinetin and 15 μM NAA, no visible phenotypic abnormalities were observedin vitro in any of the shoots generated. Solid achlorophyllous adventitious shoots were recovered following culture of this variegated leaf tissue. Plantlets were easily acclimatized toex vitro conditions. This revised version was published online in June 2006 with corrections to the Cover Date.     

Micropropagation of chinese redbud (<Emphasis Type="Italic">Cercis yunnanensis</Emphasis>) through axillary bud breaking and induction of adventitious shoots from leaf pieces

Summary Factors affecting in vitro shoot production and regeneration of Cercis yunnanensis Hu et Cheng were investigated by comparing various growth regulators and explant types. For optimum shoot production from axillary buds, Murashige and Skoog (MS) media containing 6-benzyladenine, either alone or in combination with a low concentration of thidiazuron, resulted in the greatest number of shoots formed per explant (>3). Explants (2 mm long) containing one axillary bud placed in directcontact with the medium yielded the most shoots per bud (1.6) when grown on growth regulator-free medium. Root formation on 70–80% of shoot explants was accomplished using either indole-3-butyric acid or α-naphthaleneacetic acid in the medium, with significantly more roots formed on explants possessing and apical bud than those without the bud. Direct shoot organogenesis from leaf explants occurred on MS medium containing 10–30 μM thidiazuron, with up to 42% of leaf explants producing shoots.