The WUSCHEL gene promotes vegetative-to-embryonic transition in Arabidopsis

Formation of somatic embryos in plants is known to require high concentrations of auxin or 2,4-dichlorophenoxyacetic acid (2,4-D), which presumably acts to trigger a signalling cascade. However, very little is known about the molecular mechanism that mediates the vegetative-to-embryogenic transition. We have employed a genetic approach to dissect the signal transduction pathway during somatic embryogenesis. In a functional screen using a chemical-inducible activation-tagging system, we identified two alleles of Arabidopsis gene PGA6 whose induced overexpression caused high-frequency somatic embryo formation in all tissues and organs tested, without any external plant hormones. Upon inducer withdrawal, all these somatic embryos were able to germinate directly, without any further treatment, and to develop into fertile adult plants. PGA6 was found to be identical to WUSCHEL (WUS), a homeodomain protein previously shown to be involved in specifying stem cell fate in shoot and floral meristems. Transgenic plants carrying an estradiol-inducible XVE-WUS transgene can phenocopy pga6-1 and pga6-2. Our results suggest that WUS/PGA6 also plays a key role during embryogenesis, presumably by promoting the vegetative-to-embryogenic transition and/or maintaining the identity of the embryonic stem cells.     

Strategy for shoot meristem proliferation in plants

Shoot apical meristem (SAM) of plants harbors stem cells capable of generating the aerial tissues including reproductive organs. Therefore, it is very important for plants to control SAM proliferation and its density as a survival strategy. The SAM is regulated by the dynamics of a specific gene network, such as the WUS-CLV interaction of A. thaliana. By using a mathematical model, we previously proposed six possible SAM patterns in terms of the manner and frequency of stem cell proliferation. Two of these SAM patterns are predicted to generate either dichotomous or axillary shoot branch. Dichotomous shoot branches caused by this mechanism are characteristic of the earliest vascular plants, such as Cooksonia and Rhynia, but are observed in only a small minority of plant species of the present day. On the other hand, axillary branches are observed in the majority of plant species and are induced by a different dynamics of the feedback regulation between auxin and the asymmetric distribution of PIN auxin efflux carriers. During evolution, some plants may have adopted this auxin-PIN system to more strictly control SAM proliferation.     

拟南芥WUSCHEL基因在转基因烟草中的超表达(英文)

The Arabidopsis WUSCIHIEL (WUS） gene plays a key role in the specification of the stem cellsin the shoot apical meristem (SAM). A cDNA of WUShas been amplified with the RT-PCR approach fromArabidopsis. The plant overexpression vector was constructed. It was driven by a dual enhanced CaMV35Spromoter. The construct was transformed into tobacco (Nicotiana tabacum L.) via Agrobacterium mediation.Dramatic phenotypic changes appeared in the WUS overexpression transgenic plants. Aberrant celldivisions and ectopic organogenesis could be found in almost every aerial parts of the transgenic tobaccoexcept the meristems and the inner two floral whorls. The data showed a highly conserved function of WUSin tobacco, and suggested that WUS is involved in organogenesis. The leaves were malformed, whichstrongly matched those only described previously for plants grown in the presence of polar auxin transportinhibitors. It suggested a possible function of WUS in leaf development. These results provide usefulinformation for functional analysis of WUS and important biotechnological implication as well.     

A cellular analysis of meristem activity at the end of flowering points to cytokinin as a major regulator of proliferative arrest in Arabidopsis

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Reprogramming of Stem Cell Activity to Convert Thorns into Branches

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Leaf form diversification in an ornamental heirloom tomato results from alterations in two different HOMEOBOX genes

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