CORONA, a member of the class III homeodomain leucine zipper gene family in Arabidopsis, regulates stem cell specification and organogenesis

Organogenesis at the shoot meristem requires a delicate balance between stem cell specification and differentiation. In Arabidopsis thaliana, WUSCHEL (WUS) is a key factor promoting stem cell identity, whereas the CLAVATA (CLV1, CLV2, and CLV3) loci appear to promote differentiation by repressing WUS expression. In a screen for mutations modifying clv1 mutants, we have identified a novel regulator of meristem development we term CORONA (CNA). Whereas cna single mutant plants exhibit subtle defects in meristem development, clv cna double mutants develop massively enlarged apices that display early loss of organogenesis, misexpression of WUS and CLV3, and eventual differentiation of the entire apex. The CNA gene was isolated by positional cloning and found to encode a class III homeodomain Leu zipper protein. A missense mutation resulting in the dominant-negative cna-1 allele was identified in a conserved domain of unknown function, and a likely null allele was shown to display a similar but weaker phenotype. CNA is expressed in developing vascular tissue, diffusely through shoot and flower meristems, and within developing stamens and carpels. Our analysis of WUS expression in wild-type, clv, and clv cna plants revealed that, contrary to current models, WUS is neither necessary nor sufficient for stem cell specification and that neither WUS nor CLV3 is a marker for stem cell identity. We propose that CNA functions in parallel to the CLV loci to promote organ formation.     

拟南芥WUSCHEL基因在转基因烟草中的超表达

WUSCHEL(WUS)是近年报道的一个重要的干细胞调控基因.本实验用RT-PCR技术从拟南芥(Arabidopsisthaliana L.)中克隆到其cDNA并构建了双增强的CaMV3 5S启动子驱动的超表达载体pBKB.借助农杆菌(Agrobacterium tumefaciens)介导转化烟草(Nicotiana tabacum L.),获得转基因植株.PCR和RT-PCR鉴定分别证明,外源WUS已整合到烟草基因组并已表达.转基因烟草地上部分出现大量异位增生的突起,扫描电镜观察表明:突起部分的细胞与分生组织细胞相似,部分突起能够发育为叶芽、花芽,表明WUS超表达引起烟草细胞异常分裂并在已分化组织中重新启动了器官形成.茎尖和花的内两轮器官没有上述变化.结合拟南芥的有关研究,推测烟草中可能也存在类似拟南芥WUS和其阻抑蛋白CLAVATA3、AGAMOUS间的反馈调节机制.转基因烟草叶发育表型变化明显,与生长素极性运输受抑制引起的表型相似,因此,作为生长点调控基因,WUS可能通过生长素对叶的发育进行调控.本研究为WUS基因的功能分析和有关生物技术应用提供了有意义的信息.     

Key divisions in the early Arabidopsis embryo require POL and PLL1 phosphatases to establish the root stem cell organizer and vascular axis

Arabidopsis development proceeds from three stem cell populations located at the shoot, flower, and root meristems. The relationship between the highly related shoot and flower stem cells and the very divergent root stem cells has been unclear. We show that the related phosphatases POL and PLL1 are required for all three stem cell populations. pol pll1 mutant embryos lack key asymmetric divisions that give rise to the root stem cell organizer and the central vascular axis. Instead, these cells divide in a superficially symmetric fashion in pol pll1 embryos, leading to a loss of embryonic and postembryonic root stem cells and vascular specification. We present data that show that POL/PLL1 drive root stem cell specification by promoting expression of the WUS homolog WOX5. We propose that POL and PLL1 are required for the proper divisions of shoot, flower, and root stem cell organizers, WUS/WOX5 gene expression, and stem cell maintenance.     

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.     

APETALA2 regulates the stem cell niche in the Arabidopsis shoot meristem

Postembryonic organ formation in higher plants relies on the activity of stem cell niches in shoot and root meristems where differentiation of the resident cells is repressed by signals from surrounding cells. We searched for mutations affecting stem cell maintenance and isolated the semidominant l28 mutant, which displays premature termination of the shoot meristem and differentiation of the stem cells. Allele competition experiments suggest that l28 is a dominant-negative allele of the APETALA2 (AP2) gene, which previously has been implicated in floral patterning and seed development. Expression of both WUSCHEL (WUS) and CLAVATA3 (CLV3) genes, which regulate stem cell maintenance in the wild type, were disrupted in l28 shoot apices from early stages on. Unlike in floral patterning, AP2 mRNA is active in the center of the shoot meristem and acts via a mechanism independent of AGAMOUS, which is a repressor of WUS and stem cell maintenance in the floral meristem. Genetic analysis shows that termination of the primary shoot meristem in l28 mutants requires an active CLV signaling pathway, indicating that AP2 functions in stem cell maintenance by modifying the WUS-CLV3 feedback loop.     

Flowering and determinacy in Arabidopsis

Meristems provide new cells to produce organs throughout the life of a plant, and their continuous activity depends on regulatory genes that balance the proliferation of meristem cells with their recruitment to organogenesis. During flower development, this balance is shifted towards organogenesis, causing the meristem to terminate after producing a genetically determined number of organs. In Arabidopsis, WUSCHEL (WUS) specifies the self-renewing cells at the core of the shoot meristems and is a key target in the control of meristem stability. The development of a determinate floral meristem is initiated by APETALA1/CAULIFLOWER (AP1/CAL) and LEAFY (LFY). The latter activates AGAMOUS (AG), partly in co-operation with WUS. AG then directs the development of the innermost floral organs and at the same time antagonizes WUS to terminate the meristem, although the mechanism of WUS repression remains unknown. All these genes participate in a series of regulatory feedback loops that maintain stable expression patterns or promote sharp developmental transitions. Although the regulators of meristem maintenance and determinacy in Arabidopsis are widely conserved, their interactions may vary in other species.     

Regulation of CLV3 expression by two homeobox genes in Arabidopsis

The ability of meristems to continuously produce new organs depends on the activity of their stem cell populations, which are located at the meristem tip. In Arabidopsis, the size of the stem cell domain is regulated by two antagonistic activities. The WUS (WUSCHEL) gene, encoding a homeodomain protein, promotes the formation and maintenance of stem cells. These stem cells express CLV3 (CLAVATA3), and signaling of CLV3 through the CLV1/CLV2 receptor complex restricts WUS activity. Homeostasis of the stem cell population may be achieved through feedback regulation, whereby changes in stem cell number result in corresponding changes in CLV3 expression levels, and adjustment of WUS expression via the CLV signal transduction pathway. We have analyzed whether expression of CLV3 is controlled by the activity of WUS or another homeobox gene, STM (SHOOT MERISTEMLESS), which is required for stem cell maintenance. We found that expression of CLV3 depends on WUS function only in the embryonic shoot meristem. At later developmental stages, WUS promotes the level of CLV3 expression, together with STM. Within a meristem, competence to respond to WUS activity by expressing CLV3 is restricted to the meristem apex.     

Termination of stem cell maintenance in Arabidopsis floral meristems by interactions between WUSCHEL and AGAMOUS.

Floral meristems and shoot apical meristems (SAMs) are homologous, self-maintaining stem cell systems. Unlike SAMs, floral meristems are determinate, and stem cell maintenance is abolished once all floral organs are initiated. To investigate the underlying regulatory mechanisms, we analyzed the interactions between WUSCHEL (WUS), which specifies stem cell identity, and AGAMOUS (AG), which is required for floral determinacy. Our results show that repression of WUS by AG is essential for terminating the floral meristem and that WUS can induce AG expression in developing flowers. Together, this suggests that floral determinacy depends on a negative autoregulatory mechanism involving WUS and AG, which terminates stem cell maintenance.     

The WUSCHEL and SHOOTMERISTEMLESS genes fulfil complementary roles in Arabidopsis shoot meristem regulation

Continuous organ formation from the shoot apical meristem requires the integration of two functions: a set of undifferentiated, pluripotent stem cells is maintained at the very tip of the meristem, while their daughter cells in the periphery initiate organ primordia. The homeobox genes WUSCHEL (WUS) and SHOOTMERISTEMLESS (STM) encode two major regulators of meristem formation and maintenance in Arabidopsis, yet their interaction in meristem regulation is presently unclear. Here, we have addressed this question using loss- and gain-of-function approaches. We show that stem cell specification by WUS does not require STM activity. Conversely, STM suppresses differentiation independently of WUS and is required and sufficient to promote cell division. Consistent with their independent and distinct phenotypic effects, ectopic WUS and STM activities induce the expression of different downstream target genes. Finally, the pathways regulated by WUS and STM appear to converge in the suppression of differentiation, since coexpression of both genes produced a synergistic effect, and increased WUS activity could partly compensate for loss of STM function. These results suggest that WUS and STM share labour in the shoot apical meristem: WUS specifies a subset of cells in the centre as stem cells, while STM is required to suppress differentiation throughout the meristem dome, thus allowing stem cell daughters to be amplified before they are incorporated into organs.