Investigation of cytokinin-deficient phenotypes in Arabidopsis by ectopic expression of orchid DSCKX1

The plant hormone cytokinin plays a major role in regulating plant growth and development. Here we generated cytokinin-reduction Arabidopsis plants by overexpressing a heterologous cytokinin oxidase gene DSCKX1 from Dendrobium orchid. These transgenic plants exhibited reduced biomass, rapid root growth, decreased ability to form roots in vitro, and reduced response to cytokinin in growing calli and roots. Furthermore, the expression of KNAT1, STM, and CycD3 genes was significantly reduced in the transgenic plants, suggesting that cytokinin may function to control the cell cycles and shoot/root development via regulation of these genes.     

Stress associated protein 1 regulates the development of glandular trichomes in Artemisia annua

Undifferentiated plant cells in culture represent a renewable system conducive to understanding biological processes and a valuable alternative for secondary metabolite production. Additionally, manipulation of these systems by plant growth regulators (PGRs) may result in redifferentiation/organogenesis and hence changes in metabolic profiles. The aim of the study was to investigate the effects of combining auxin (2,4-dichlorophenoxyacetic acid) and cytokinin (kinetin) at concentrations of 2, 4, 6 and 9 µM on undifferentiated Moringa oleifera callus cells, at a metabolome level. Results indicated that the callus became habituated, i.e. developed the ability to grow without added stimulatory PGRs, and no organogenesis was observed on any of the different PGR combinations under investigation. Methanolic extracts were screened for total phenolic content (TPC) and anti-oxidant activity, and further analysed using liquid chromatography coupled to mass spectrometry combined with multivariate data analysis to facilitate analysis of the metabolite profiles. While the anti-oxidant capacity of extracts from the various treatments exhibited little variation, the TPC differed significantly. Despite the observed habituation phenomenon, the calli retained responsiveness towards external PGRs and each of the 25 conditions generated a unique metabolome as found by principal component analysis. This was also reflected by a number of phytochemicals that were annotated as biomarkers from PGR-treated calli. These findings demonstrate the differential influence of 2,4-D and kinetin on M. oleifera callus for the production of secondary metabolites.

     

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.     

Role of AUX1 in the control of organ identity during in vitro organogenesis and in mediating tissue specific auxin and cytokinin interaction in <Emphasis Type="Italic">Arabidopsis</Emphasis>

Classic plant tissue culture experiments have shown that exposure of cell culture to a high auxin to cytokinin ratio promotes root formation and a low auxin to cytokinin ratio leads to shoot regeneration. It has been widely accepted that auxin and cytokinin play an antagonistic role in the control of organ identities during organogenesis in vitro. Since the auxin level is highly elevated in the shoot meristem tissues, it is unclear how a low auxin to cytokinin ratio promotes the regeneration of shoots. To identify genes mediating the cytokinin and auxin interaction during organogenesis in vitro, three allelic mutants that display root instead of shoot regeneration in response to a low auxin to cytokinin ratio are identified using a forward genetic approach in Arabidopsis. Molecular characterization shows that the mutations disrupt the AUX1 gene, which has been reported to regulate auxin influx in plants. Meanwhile, we find that cytokinin substantially stimulates auxin accumulation and redistribution in calli and some specific tissues of Arabidopsis seedlings. In the aux1 mutants, the cytokinin regulated auxin accumulation and redistribution is substantially reduced in both calli and specific tissues of young seedlings. Our results suggest that auxin elevation and other changes stimulated by cytokinin, instead of low auxin or exogenous auxin directly applied, is essential for shoot regeneration. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Light-regulated, tissue-specific, and cell differentiation-specific expression of the Arabidopsis Fe(III)-chelate reductase gene AtFRO6

Iron is an essential element for almost all living organisms, actively involved in a variety of cellular activities. To acquire iron from soil, strategy I plants such as Arabidopsis (Arabidopsis thaliana) must first reduce ferric to ferrous iron by Fe(III)-chelate reductases (FROs). FRO genes display distinctive expression patterns in several plant species. However, regulation of FRO genes is not well understood. Here, we report a systematic characterization of the AtFRO6 expression during plant growth and development. AtFRO6, encoding a putative FRO, is specifically expressed in green-aerial tissues in a light-dependent manner. Analysis of mutant promoter-beta-glucuronidase reporter genes in transgenic Arabidopsis plants revealed the presence of multiple light-responsive elements in the AtFRO6 promoter. These light-responsive elements may act synergistically to confer light responsiveness to the AtFRO6 promoter. Moreover, no AtFRO6 expression was detected in dedifferentiated green calli of the korrigan1-2 (kor1-2) mutant or undifferentiated calli derived from wild-type explants. Conversely, AtFRO6 is expressed in redifferentiated kor1-2 shoot-like structures and differentiating calli of wild-type explants. In addition, AtFRO7, but not AtFRO5 and AtFRO8, also shows a reduced expression level in kor1-2 green calli. These results suggest that whereas photosynthesis is necessary but not sufficient, both light and cell differentiation are necessary for AtFRO6 expression. We propose that AtFRO6 expression is light regulated in a tissue- or cell differentiation-specific manner to facilitate the acquisition of iron in response to distinctive developmental cues.     

Overexpression of Arabidopsis response regulators,ARR4/ATRR1/IBC7 and ARR8/ATRR3, alters cytokinin responses differentially in the shoot and in callus formation

Arabidopsis ARR4/ATRR1/IBC7 and ARR8/ATRR3 are homologous genes of prokaryotic response regulators that are involved in the His-Asp phosphorelay signal transduction. We analyzed the function of these genes as response regulators using transgenic plants. Overexpression of ARR4 in cultured stems of the transgenics markedly promoted shoot formation in the presence of cytokinin, while overexpression of ARR8 repressed shoot formation and greening of calli. The expression level of cytokinin-inducible genes, cycD3 and cab increased in the ARR4 overexpressor but decreased in the ARR8 overexpressor. By contrast, two drought stress-inducible genes, rd29A and erd1, were expressed in both overexpressors as that in control plants. These results suggest that ARR4 and ARR8 are involved in cytokinin signal transduction, and that ARR4 functions as a positive-regulator, whereas ARR8 functions as a negative-regulator. Furthermore, microarray analysis showed that several genes were up-regulated in the ARR4 overexpressor. Consistent with these results, ARR4 and ARR8 might play important roles in the sensoring system of cytokinin signal transduction pathway in various developmental and environmental conditions and the regulation of gene expression.     

Cytokinesis, cell expansion, and the potential for cytokinin-autonomous growth in tobacco pith

Pith tissue from Nicotiana tabacum L. cv `Maryland Mammoth' or `Wisconsin 38' was isolated, free of vascular tissue, and cultured on a medium containing auxin but no cytokinin. Explants from the apical 1 cm of stem, within the pith rib meristem, initiated callus growth with 100% efficiency. Macroscopically visible callus was evident 5 days after the tissue was isolated, and the cultures grew persistently in the absence of cytokinin. Heat treatment, sometimes used to initiate cytokinin habituation, was not required. Explants from tissue basipetal to the pith rib meristem declined in the frequency of habituation with increasing distance from the shoot apex. Although pith tissue which was growing, in vivo, was more prone than mature tissue to establish cytokinin-habituated callus, the basipetal decline in habituation frequency extended well beyond the zone of cell expansion. Explants from mature pith 40 centimeters or more from the shoot apex grew in the absence of cytokinin with 18% frequency, although the response required at least 2 weeks of culture. Further analysis demonstrated that tissue near the periphery of mature pith was more prone to cytokinin-habituation than tissue from the pith center.     

Transcriptome analysis of age-related gain of callus-forming capacity in Arabidopsis hypocotyls

Callus-forming capacity is enhanced with hypocotyl maturity in Arabidopsis. However, the genetic regulation of age-related gain in capacity for callus formation is unclear. We used a gene expression microarray assay to characterize the underlying mechanisms during callus formation in young and mature hypocotyl explants of Arabidopsis. As expected, genes involved in photosynthesis and cell wall thickening showed altered expression during hypocotyl maturation. In addition, genes involved in cytokinin perception were enriched in mature hypocotyl tissues. Phytohormone-induced callus formation in hypocotyl explants was accompanied by increased expression of genes mainly related to the cell cycle, histones and epigenetics. The induction level of these genes was higher in mature hypocotyl explants than young explants during callus formation. We identified a number of genes, including those with unknown function, potentially involved in age-related gain in callus formation. Our results provide insight into the effect of hypocotyl age on callus formation. Altered cytokinin signaling components, cell cycle regulation and epigenetics may work in concert to lead to gain of callus-forming capacity in hypocotyls with age.     

In Vitro Culture of Pimpinella anisum L. (anise)

A simple in vitro protocol has been developed for large scale multiplication of plants from various explants of Pimpinella anisum L., a medicinally important plant belonging to family Apiaceae. Browning of cultures was observed during the maintenance. Frequent subculture at an interval of about 15–17 days was essential for obtaining embryogenic callus cultures and preventing browning of cultures. High frequency of multiple shoot formation was achieved from callus cultures derived from shoot apices, root and stem explants, and also from seed-derived calli. Somatic embryogenesis was observed in callus cultures derived from seeds and shoot apices. Complete plants developed from these embryoids. Direct regeneration of plantlets from shoot apices was also observed. Roots formation occurred in all the cultures. The requirement for exogenous auxin and cytokinin for differentiation was found to be varying in different tissues.     

Analysis of the protein expression profiling during rice callus differentiation under different plant hormone conditions

Plant hormones function to coordinate plant growth and development. While the plant hormones, mainly auxin and cytokinin, are exogenously added to various plant tissue cultures, their effects on the organogenesis are apparent, but little is known concerning the molecular mechanisms by which they function in cultured cells. Rice, as a model plant in monocots, is also suitable to tissue culture studies. Here, we used four types of regeneration mediums with different relative concentrations of cytokinin and auxin for rice callus differentiation, the calli at different differentiation stages were collected for proteomic analysis. 2-dimensional electrophoresis revealed that 213 protein spots significantly differentially expressed during callus differentiation under different hormone conditions. By using mass spectrometry, 183 differentially expressed protein spots were identified to match 157 unique proteins. Most of these differential proteins were cellular/metabolic process-related proteins, whose different expression patterns may be correlated with the cytokinin and auxin regulation. Several hormone-related proteins were prominently featured in differentiated calli as compared with the initiated calli, such as alpha-amylase isoforms, mannose-binding rice lectin, putative dehydration stress-induced protein, cysteine endopeptidase and cystatin. All these results provide a novel insight into how the two plant hormones effect the callus differentiation in rice on the proteomic level.     

The CUP-SHAPED COTYLEDON genes promote adventitious shoot formation on calli

In Arabidopsis, shoots regenerate on calli derived from hypocotyl explants. Mutations in CUC1 and CUC2 (CUP-SHAPED COTYLEDON) reduce the induction of adventitious shoots on calli. To elucidate the function of CUC1 and CUC2 during this process, these genes were overexpressed in calli. Our results indicate that CUC1 and CUC2 promote adventitious shoot formation on calli. To clarify their functions, the concentrations of auxin and cytokinin in the shoot-inducing medium were changed. Calli of the single and double mutants of cuc1 and cuc2, as well as calli overexpressing either of the CUC genes, responded similarly. This suggests that neither of the genes are involved in synthesis or sensitivity of these hormones. During embryogenesis, CUC1 and CUC2 induce shoot apical meristem formation through activation of STM (SHOOT MERISTEMLESS). Our analyses using the stm mutant and an STM::GUS construct suggest that CUC1 and CUC2 also function upstream of STM even in calli.     

Identification of plant cytokinin biosynthetic enzymes as dimethylallyl diphosphate:ATP/ADP isopentenyltransferases

It has been believed that the key step in cytokinin biosynthesis is the addition of a 5-carbon chain to the N(6) of AMP. To identify cytokinin biosynthesis enzymes that catalyze the formation of the isopentenyl side chain of cytokinins, the Arabidopsis genomic sequence was searched for genes that could code for isopentenyltransferases. This resulted in the identification of nine putative genes for isopentenyltransferases. One of these, AtIPT4, was subjected to detailed analysis. Overexpression of AtIPT4 caused cytokinin-independent shoot formation on calli. As shoot formation on calli normally occurs only when cytokinins are applied, it suggested that this gene product catalyzed cytokinin biosynthesis in plants. Recombinant AtIPT4 catalyzed the transfer of an isopentenyl group from dimethylallyl diphosphate to the N(6) of ATP and ADP, but not to that of AMP. AtIPT4 did not exhibit the DMAPP:tRNA isopentenyltransferase activity. These results indicate that cytokinins are, at least in part, synthesized from ATP and ADP in plants.