The spalt gene links the A/P compartment boundary to a linear adult structure in the Drosophila wing

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JOURNAL ARTICLES

The spalt gene links the A/P compartment boundary to a linear adult structure in the Drosophila wing

MA Sturtevant, B Biehs, E Marin and E Bier
Department of Biology, University of California, San Diego, La Jolla 92093-0116, USA.

During Drosophila embryogenesis, each segment is subdivided into an anterior and a posterior compartment through the action of the engrailed gene. Compartmental boundaries bisect imaginal disc primordia which give rise to adult appendages. In early larval development, a short-range Hedgehog signal originating from the posterior compartment of the imaginal wing disc activates expression of genes including decapentaplegic (dpp) in a stripe running along the anterior-posterior compartment boundary. Secreted Dpp emanating from the A/P boundary of wing discs then acts as a secondary signal to organize the wing over large distances. The transcription factor encoded by spalt major (salm) gene, which is expressed in a broad wedge centered over the dpp stripe, is one target of Dpp signaling. In this manuscript, we show that the anterior edge of the salm expression domain abuts a narrow stripe of rhomboid (rho)-expressing cells corresponding to the L2 longitudinal vein primordium. hh mis-expression along the anterior wing margin induces a surrounding domain of salm expression, the anterior edge of which abuts a displaced rho L2 stripe. salm plays a key role in defining the position of the L2 vein since loss of salm function in mosaic patches induces the formation of ectopic L2 branches, which comprise salm- cells running along clone borders where salm- cells confront salm+ cells. These data suggest that salm determines the position of the L2 vein primordium by activating rho expression in neighboring cells through a locally non-autonomous mechanism. rho then functions to initiate and maintain vein differentiation. We discuss how these data provide the final link connecting the formation of a linear adult structure to the establishment of a boundary by the maternal Bicoid morphogen gradient in the blastoderm embryo.
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				S. J. Harrison, R. Nishinakamura, and A. P. Monaghan Sall1 Regulates Mitral Cell Development and Olfactory Nerve Extension in the Developing Olfactory Bulb Cereb Cortex, July 1, 2008; 18(7): 1604 - 1617. [Abstract] [Full Text] [PDF]

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				Y. A. Zeng, M. Rahnama, S. Wang, W. Sosu-Sedzorme, and E. M. Verheyen Drosophila Nemo antagonizes BMP signaling by phosphorylation of Mad and inhibition of its nuclear accumulation Development, June 1, 2007; 134(11): 2061 - 2071. [Abstract] [Full Text] [PDF]

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				F. A. Martin, A. Perez-Garijo, E. Moreno, and G. Morata The brinker gradient controls wing growth in Drosophila Development, October 15, 2004; 131(20): 4921 - 4930. [Abstract] [Full Text] [PDF]

				M. Parrish, T. Ott, C. Lance-Jones, G. Schuetz, A. Schwaeger-Nickolenko, and A. P. Monaghan Loss of the Sall3 Gene Leads to Palate Deficiency, Abnormalities in Cranial Nerves, and Perinatal Lethality Mol. Cell. Biol., August 15, 2004; 24(16): 7102 - 7112. [Abstract] [Full Text] [PDF]

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				D. Sweetman, T. Smith, E. R. Farrell, A. Chantry, and A. Munsterberg The Conserved Glutamine-rich Region of Chick Csal1 and Csal3 Mediates Protein Interactions with Other Spalt Family Members. IMPLICATIONS FOR TOWNES-BROCKS SYNDROME J. Biol. Chem., February 14, 2003; 278(8): 6560 - 6566. [Abstract] [Full Text] [PDF]

				C. Netzer, L. Rieger, A. Brero, C.-D. Zhang, M. Hinzke, J. Kohlhase, and S. K. Bohlander SALL1, the gene mutated in Townes-Brocks syndrome, encodes a transcriptional repressor which interacts with TRF1/PIN2 and localizes to pericentromeric heterochromatin Hum. Mol. Genet., December 1, 2001; 10(26): 3017 - 3024. [Abstract] [Full Text] [PDF]

				R. P. Ray and K. A. Wharton Context-dependent relationships between the BMPs gbb and dpp during development of the Drosophila wing imaginal disk Development, October 15, 2001; 128(20): 3913 - 3925. [Abstract] [Full Text] [PDF]

				T. Rusten, R Cantera, J Urban, G Technau, F. Kafatos, and R Barrio Spalt modifies EGFR-mediated induction of chordotonal precursors in the embryonic PNS of Drosophila promoting the development of oenocytes Development, January 3, 2001; 128(5): 711 - 722. [Abstract] [PDF]

				Y Funakoshi, M Minami, and T Tabata mtv shapes the activity gradient of the Dpp morphogen through regulation of thickveins Development, January 1, 2001; 128(1): 67 - 74. [Abstract] [PDF]

				N. J. Kilby, M. J. Fyvie, R. A. Sessions, G. J. Davies, and J. A.H. Murray Controlled induction of GUS marked clonal sectors in Arabidopsis J. Exp. Bot., May 1, 2000; 51(346): 853 - 863. [Abstract] [Full Text] [PDF]

				D Brentrup, H Lerch, H Jackle, and M Noll Regulation of Drosophila wing vein patterning: net encodes a bHLH protein repressing rhomboid and is repressed by rhomboid-dependent Egfr signalling Development, January 11, 2000; 127(21): 4729 - 4741. [Abstract] [PDF]

				A Baonza, J. de Celis, and A Garcia-Bellido Relationships between extramacrochaetae and Notch signalling in Drosophila wing development Development, January 6, 2000; 127(11): 2383 - 2393. [Abstract] [PDF]

				J Mohler, M Seecoomar, S Agarwal, E Bier, and J Hsai Activation of knot (kn) specifies the 3-4 intervein region in the Drosophila wing Development, January 1, 2000; 127(1): 55 - 63. [Abstract] [PDF]

				H Matakatsu, R Tadokoro, S Gamo, and S Hayashi Repression of the wing vein development in Drosophila by the nuclear matrix protein plexus Development, January 12, 1999; 126(23): 5207 - 5216. [Abstract] [PDF]

				G. Halder, P. Polaczyk, M. E. Kraus, A. Hudson, J. Kim, A. Laughon, and S. Carroll The Vestigial and Scalloped proteins act together to directly regulate wing-specific gene expression in Drosophila Genes & Dev., December 15, 1998; 12(24): 3900 - 3909. [Abstract] [Full Text]

				M. Milán, F. J. Diaz-Benjumea, and S. M. Cohen Beadex encodes an LMO protein that regulates Apterous LIM-homeodomain activity in Drosophila wing development: a model for LMO oncogene function Genes & Dev., September 15, 1998; 12(18): 2912 - 2920. [Abstract] [Full Text]

				S. D. Weatherbee, G. Halder, J. Kim, A. Hudson, and S. Carroll Ultrabithorax regulates genes at several levels of the wing-patterning hierarchy to shape the development of the Drosophila�haltere Genes & Dev., May 15, 1998; 12(10): 1474 - 1482. [Abstract] [Full Text]

				K Lunde, B Biehs, U Nauber, and E Bier The knirps and knirps-related genes organize development of the second wing vein in Drosophila Development, January 11, 1998; 125(21): 4145 - 4154. [Abstract] [PDF]

				B Biehs, M. Sturtevant, and E Bier Boundaries in the Drosophila wing imaginal disc organize vein-specific genetic programs Development, January 11, 1998; 125(21): 4245 - 4257. [Abstract] [PDF]

				T. Haerry, O Khalsa, M. O'Connor, and K. Wharton Synergistic signaling by two BMP ligands through the SAX and TKV receptors controls wing growth and patterning in Drosophila Development, January 10, 1998; 125(20): 3977 - 3987. [Abstract] [PDF]