Development and Growth Control Laboratory
Marco Milán
Principal Investigator
ICREA Research Professor
Office Tel : +34 93 403 49 02
Lab Tel : +34 93 403 49 01
e-mail : marco.milan
irbbarcelona.org
Background
A central question in modern developmental biology is how the growth and patterning of tissues are controlled on a molecular and genetic level. Drosophila melanogaster provides an ideal model system to address this issue because of its suitability for genetic and molecular manipulations and its well-described developmental biology. Systematic genetic screens for loss-of-function mutations, gain-of-function phenotypes and the detection of enhancers have revealed many of the genes involved in a number of developmentally important processes. In addition, the completion of the genomic sequencing project for Drosophila makes it possible to use reverse genetic approaches, such as RNA-mediated interference, targeted gene disruption as well as genome-wide expression analyses to address a wide variety of questions concerning the developmental biology of the fruit fly.
During the development of multicellular organisms, groups of cells assemble to form tissues that are initially homogenous. The elaboration of spatial pattern often begins when the field of cells subdivides into smaller territories. The imaginal discs of Drosophila provide well-characterized experimental systems in which subdivision of the tissue depends on mechanisms that limit cell mixing to produce stable boundaries. These stable subdivisions are called compartments. In the imaginal disc compartments, boundaries serve as signalling centres. Short-range interactions between cells in adjacent compartments induce the expression of the signalling proteins Wingless (Wg) and Decapentaplegic (Dpp) in cells adjacent to the compartment boundaries. Wg and Dpp form long-range extracellular protein gradients centred on the compartment boundaries. Stable boundaries between compartments result in tightly localized sources of these signalling proteins. Intermingling of cells at the compartment boundary causes disorganization of the signalling centre with disastrous consequences for patterning and growth control.
Research Interests
The Drosophila wing imaginal disc is a monolayered epidermal sac. The wing primordium arises from the embryonic ectoderm as a group of around 30 cells that proliferate extensively during larval development to reach about 50,000 cells. The wing primordium is subdivided into an anterior (A) and a posterior (P) compartment by the restricted expression and activity of the homeodomain protein Engrailed in P cells. This subdivision is inherited from the embryonic ectoderm. When the wing primordium consists of around 100 cells, it subdivides again into a dorsal (D) and a ventral (V) compartment by the restricted expression and activity of the LIM-homeodomain protein Apterous in D cells. We aim to determine how compartment boundaries are generated, how expression of the organizing molecules Wg and Dpp is induced at the compartment boundaries and how growth and patterning is organized by the activity of Wg and Dpp at these boundaries.
Research Lines
To achieve our objectives, our group is structured around 3 research lines:
- Compartment boundary formation: identification of new genes and properties
- Signaling molecules and growth control
- Compartments and growth control
Funding
This group receives financial support from the following sources:
- European Commission
- Ministerio de Educación y Ciencia (Spanish Ministry of Science and Education)
- Generalitat de Catalunya (DURSI)(Government of Catalonia)
- ICREA (Catalan Institute of Research and Advanced Studies)
- EMBO Young Investigator Programme
More info
Development and Growth Control Laboratory
Notch signalling coordinates tissue growth and wing fate specification in Drosophila
Rafel N and Milán M
Development, 135, 3995-4001 (2008)
A gain-of-function suppressor screen for genes involved in dorsal-ventral boundary formation in the Drosophila wing
Bejarano F, Luque CM, Herranz H, Sorrosal G, Rafel N, Pham TT and Milán M
Genetics, 178 (1), 307-323 (2008)
A Wingless and Notch double-repression mechanism regulates G1-S transition in the Drosophila wing
Herranz H, Pérez L, Martín FA and Milán M
EMBO J, 27 (11), 1633-1645 (2008)
A permissive role of Notch in maintaining the DV affinity boundary of the Drosophila wing
Becam I and Milán M
Dev Biol, 322 (1), 190-198 (2008)
Signalling molecules, growth regulators and cell cycle control in Drosophila
Herranz H and Milán M
Cell Cycle, 7 (21), 3335-3337 (2008)
Robustness and stability of the gene regulatory network involved in DV boundary formation in the Drosophila wing
Buceta J, Herranz H, Canela-Xandri O, Reigada R, Sagués F and Milán M
PloS ONE, 2 (7), e602 (2007)
Hedgehog restricts its expression domain in the Drosophila wing
Bejarano F, Pérez L, Apidianakis Y, Delidakis C and Milán M
EMBO Rep, 8 (8), 778-783 (2007)
Sculpting a fly leg: BMP boundaries and cell death
Milán M
Nat Cell Biol, 9 (1), 17-18 (2007)
Growth control in the proliferative region of the Drosophila eye-head primordium: the elbow-noc gene complex
Luque CM and Milán M
Dev Biol, 301 (2), 327-339 (2007)
Calderón encodes an organic cation transporter of the major facilitator superfamily required for cell growth and proliferation of Drosophila tissues
Herranz H, Morata G and Milán M
Development, 133 (14), 2617-2625 (2006)
Notch and affinity boundaries in Drosophila
Herranz H and Milán M
Bioessays, 28 (2), 113-116 (2006)
Self-refinement of Notch activity through the transmembrane protein Crumbs: modulation of gamma-secretase activity
Herranz H, Stamataki E, Feiguin F and Milán M
EMBO Rep, 7 (3), 297-302 (2006)
Proximodistal subdivision of Drosophila legs and wings: the elbow-no ocelli gene complex
Weihe U, Dorfman R, Wernet MF, Cohen SM and Milán M
Development, 131 (4), 767-774 (2004)
A re-evaluation of the contributions of Apterous and Notch to the dorsoventral lineage restriction boundary in the Drosophila wing
Milán M and Cohen SM
Development, 130 (3), 553-562 (2003)
Short-range cell interactions and cell survival in the Drosophila wing
Milán M, Pérez L and Cohen SM
Dev Cell, 2 (6), 797-805 (2002)
The LRR proteins capricious and Tartan mediate cell interactions during DV boundary formation in the Drosophila wing
Milán M, Weihe U, Pérez L and Cohen SM
Cell, 106 (6), 785-794 (2001)
Notch signaling is not sufficient to define the affinity boundary between dorsal and ventral compartments
Milán M and Cohen SM
Mol Cell, 4 (6), 1073-1078 (1999)
Regulation of LIM homeodomain activity in vivo: a tetramer of dLDB and apterous confers activity and capacity for regulation by dLMO
Milán M and Cohen SM
Mol Cell, 4 (2), 267-273 (1999)
Development and Growth Control Laboratory
Marco Milán
Principal Investigator
ICREA Research Professor
Office Tel : +34 93 403 49 02
Lab Tel : +34 93 403 49 01
e-mail : marco.milanirbbarcelona.org
Postdoctoral Fellow
Héctor Herranz
tel +34 93 403 49 01
hector.herranzirbbarcelona.org
Isabelle Becam
tel +34 93 403 49 01
isabelle.becamirbbarcelona.org
Andrés Dekanty
+34 93 403 49 01
andres.dekantyirbbarcelona.org
PhD Student
Duarte Mesquita
tel +34 93 403 49 01
duarte.mesquitairbbarcelona.org
Georgina Sorrosal
tel +34 93 403 49 01
georgina.sorrosalirbbarcelona.org
Neus Rafel Berge
tel +34 93 403 49 01
neus.rafelirbbarcelona.org
Lara Barrio
tel +34 93 403 49 01
lara.barrioirbbarcelona.org
Research Assistant
Lidia Pérez García
tel +34 93 403 49 01
lidia.perezirbbarcelona.org
MSc. Student
Ana Ferreira
tel +34 93 403 49 01
ana.ferreirairbbarcelona.org
Visiting student
Katrin Rein
tel +34 93 403 49 01
katrin.reinirbbarcelona.org
Development and Growth Control Laboratory
