Articles by Edwin R. Lampugnani in JoVE
Profiling glicana de Polímeros da planta da parede celular usando Microarrays Isabel E. Moller1,2, Filomena A. Pettolino3, Charlie Hart1, Edwin R. Lampugnani1, William G.T. Willats4, Antony Bacic1,2 1Australian Centre of Excellence in Plant Cell Walls, School of Botany, University of Melbourne, 2Plant Cell Biology Research Centre, School of Botany, University of Melbourne, 3CSIRO Plant Industry, Black Mountain Laboratories, 4Department of Plant Biology and Biotechnology, University of Copenhagen Uma técnica chamada
Other articles by Edwin R. Lampugnani on PubMed
Regulation of Tissue-specific Expression of SPATULA, a BHLH Gene Involved in Carpel Development, Seedling Germination, and Lateral Organ Growth in Arabidopsis Journal of Experimental Botany. Mar, 2010 | Pubmed ID: 20176890 SPATULA is a bHLH transcription factor that promotes growth of tissues arising from the carpel margins, including the septum and transmitting tract. It is also involved in repressing germination of newly harvested seeds, and in inhibiting cotyledon, leaf, and petal expansion. Using a reporter gene construct, its expression profile was fully defined. Consistent with its known functions, SPT was expressed in developing carpel margin tissues, and in the hypocotyls and cotyledons of germinating seedlings, and in developing leaves and petals. It was also strongly expressed in tissues where no functions have been identified to date, including the dehiscence zone of fruits, developing anthers, embryos, and in the epidermal initials and new stele of root tips. The promoter region of SPT was dissected by truncation and deletion, and two main regions occupied by tissue-specific enhancers were identified. These were correlated with eight regions conserved between promoter regions of Arabidopsis, Brassica oleracea, and Brassica rapa. When transformed into Arabidopsis, the B. oleracea promoter drove expression in reproductive tissues mostly comparable to the equivalent Arabidopsis promoter. There is genetic evidence that SPT function in the gynoecium is associated with the perception of auxin. However, site-directed mutagenesis of three putative auxin-response elements had no detectable effect on SPT expression patterns. Even so, disruption of a putative E-box variant adjacent to one of these resulted in a loss of valve dehiscence zone expression. This expression was also specifically lost in mutants of another bHLH gene INDEHISCENT, indicating that IND may directly regulate SPT expression through this variant E-box.
PETAL LOSS is a Boundary Gene That Inhibits Growth Between Developing Sepals in Arabidopsis Thaliana The Plant Journal : for Cell and Molecular Biology. Sep, 2012 | Pubmed ID: 22507233 Flower primordia are partitioned by boundaries during their early development. Such boundaries occur between whorls of organs, and also between organs within whorls. PETAL LOSS (PTL) is a trihelix transcription factor gene that is expressed in boundaries between sepal primordia in the outer whorl. Over-expression of PTL results in growth suppression suggesting that PTL normally inhibits growth between newly arising sepals. We have tested this by examining the consequences of loss of PTL function using confocal imaging. The size of the inter-sepal zone in stage 4 buds expands radially by 35-40% in ptl-1 mutants as a consequence of additional cell proliferation. There is no change in the size of PTL-expressing cells. PTL expression does not overlap with the sites of petal initiation identified using the DR5 auxin response reporter. The latter are closer to the centre of the flower. Thus the consequence of loss of PTL function on petal initiation is indirect, perhaps through interference with a mobile petal-initiation signal or movement of the PTL protein. CUP-SHAPED COTYLEDON (CUC) genes are also involved in defining inter-sepal boundaries. However, genetic studies combining ptl with loss of cuc1 function, and gain of CUC function in extra early petals-1 (miR164c) mutants, have revealed that CUC and PTL act differently. CUC suppresses growth of sepal tissues from the boundary region whereas PTL acts to keep the size of the boundary in check.
Auxin Controls Petal Initiation in Arabidopsis Development (Cambridge, England). Jan, 2013 | Pubmed ID: 23175631 Floral organs are usually arranged in concentric whorls of sepals, petals, stamens and carpels. How founder cells of these organs are specified is unknown. In Arabidopsis, the PETAL LOSS (PTL) transcription factor functions in the sepal whorl, where it restricts the size of the inter-sepal zone. Genetic evidence suggests that PTL acts to support a petal initiation signal active in the adjacent whorl. Here we aimed to characterise the signal by identifying enhancers that disrupt initiation of the remaining petals in ptl mutants. One such enhancer encodes the auxin influx protein AUX1. We have established that auxin is a direct and mobile petal initiation signal by promoting its biosynthesis in the inter-sepal zone in ptl mutant plants and restoring nearby petal initiation. Consistent with this, loss of PTL function disrupts DR5 expression, an auxin-inducible indicator of petal-initiation sites. The signalling network was extended by demonstrating that: (1) loss of RABBIT EARS (RBE) function apparently disrupts the same auxin influx process as PTL; (2) the action of AUX1 is supported by AXR4, its upstream partner in auxin influx; (3) polar auxin transport, which is controlled by PINOID (PID) and PIN-FORMED1 (PIN1), functions downstream of PTL; and (4) the action of pmd-1d, a dominant modifier of the ptl mutant phenotype, is dependent on auxin transport. Thus, loss of PTL function disrupts auxin dynamics, allowing the role of auxin in promoting petal initiation to be revealed.