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Compartment (development)

August 24, 2023

Compartments can be simply defined as separate, different, adjacent cell populations, which upon juxtaposition, create a lineage boundary.[1] This boundary prevents cell movement from cells from different lineages across this barrier, restricting them to their compartment.[2] Subdivisions are established by morphogen gradients and maintained by local cell-cell interactions, providing functional units with domains of different regulatory genes, which give rise to distinct fates.[1] Compartment boundaries are found across species. In the hindbrain of vertebrate embryos, rhombomeres are compartments of common lineage [3] outlined by expression of Hox genes.[4] In invertebrates, the wing imaginal disc of Drosophila provides an excellent model for the study of compartments. Although other tissues, such as the abdomen,[5] and even other imaginal discs are compartmentalized, much of our understanding of key concepts and molecular mechanisms involved in compartment boundaries has been derived from experimentation in the wing disc of the fruit fly.

Function

By separating different cell populations, the fate of these compartments are highly organized and regulated.[6] In addition, this separation creates a region of specialized cells close to the boundary,[7] which serves as a signaling center for the patterning, polarizing and proliferation[8] of the entire disc. Compartment boundaries establish these organizing centers [5][7] by providing the source of morphogens [9] that are responsible for the positional information required for development and regeneration.[9][10] The inability of cell competition to occur across the boundary, indicates that each compartment serves as an autonomous unit of growth.[8][11] Differences in growth rates and patterns in each compartment, maintain the two lineages separated [12] and each control the precise size of the imaginal discs.[13]

Cell separation

These two cell populations are kept separate by a mechanism of cell segregation linked to the heritable expression of a selector gene.[7] A selector gene is one that is expressed in one group of cells but not the other,[5] giving the founder cells and their descendants different instructions.[12] Eventually these selector genes become fixed in either an expressed or unexpressed state and are stably inherited to the descendants,[5][8] specifying the identity of the compartment and preventing these genetically different cell populations from intermixing.[13] Therefore, these selector genes are key for the formation and maintenance of lineage compartments.[14]

Central dogma

The difference in selector gene activity not only establishes two compartments, but also leads to the formation of a boundary between these two that serves as a source of morphogen gradients. In the central dogma of compartments, first, morphogen gradients position founder compartment cells.[2][8] Then, active/inactive selector genes give a unique genetic identity to cells within a compartment, instructing their fate and their interactions with the neighboring compartment.[8][14] Finally, border cells, established by short-range signaling from one compartment to its neighboring compartment [15] emit long-range signals that spread to both compartments to regulate the growth and pattering of the entire tissue.[8][16]

A/P boundary

In 1970, by means of clonal analysis, the Anterior-Posterior boundary was identified.[2] The founder cells, found at the border between parasegments 4 and 5 of embryo, are already determined at the early blastoderm stage and defined into the two populations they will generate by stripes of the engrailed gene.[2][8][17] The selector gene, engrailed (en), is a key determinant in boundary formation between the anterior and posterior compartments.[12] As the wing imaginal disc expands, posterior, but not anterior cells will express engrailed and maintain this expression state as they expand and form the disc.[17] Engrailed mutant clones of posterior origin will gain anterior affinity and move towards the anterior compartment and intermix with those cells. Within the posterior compartment these clones will sort out and form an ectopic border where they meet other posterior cells.[12][16][18] Similarly, a clone of anterior cells expressing engrailed will gain posterior identity and create an ectopic boundary where the clone meets other anterior cells in this compartment.[16] In addition, to its cell autonomous role in specifying posterior compartment identity, engrailed also has a non-cell autonomous function in the general growth and patterning of the wing disc, through the activation of signaling pathways such as Hedgehog (Hh) and Decapentaplegic (Dpp).[18][19][20] The presence of engrailed in the posterior cells leads to the secretion of the short-range inducer Hh [8] which can cross over to the anterior compartment to activate the long-range morphogen, Dpp.[15][16] Cells in the posterior compartment produce Hh, but only anterior cells can transduce the signal.[6]Optomotor-blind (omb) is involved in the transcriptional response of Dpp, which is only required in the anterior cells to interpret Hh signaling for boundary formation and maintenance.[21] In addition, Cubitus interruptus (Ci), the signal transducer of the Hh signal, is expressed throughout the anterior compartment, particularly in anterior border cells.[18] In posterior cells engrailed prevents the expression of Ci, such it is only expressed in anterior cells and hence only these cells can respond to Hh signaling by up-regulating the expression of dpp.[15][22] Loss of engrailed function in posterior cells, results in anterior transformation, where Hh expression is decreased and dpp, ci and patched (ptc) is increased, resulting in the formation of a new A/P boundary, suggesting that en positively regulates hh, while negatively regulating ci, ptc and dpp.[18][19]

Cell segregation

To explain how anterior and posterior cells are kept separated, the differential adhesion hypothesis proposes that these two cell populations express different adhesion molecules, producing different affinities for each other that minimize their contact.[6][8] The selector affinity model proposes that difference in cell affinity between compartments is a result of differential selector gene expression.[14] The presence or absence of selector genes in a given compartment produces compartment-specific adhesion or recognition molecules that are different from those in its counterpart.[13] For example, engrailed expressed in the posterior, but not the anterior, cells provides the differential affinity that keeps these compartments separately. It is also possible that this difference in cell adhesion/affinity is not directly due to en expression, but rather to the ability to receive Hh signaling.[16][18] Anterior cells, capable of Hh transduction, will express given adhesive molecules that would differ from those present in posterior cells, creating differential affinity that would prevent them from intermixing.[13] This signaling-affinity model is supported by experiments that demonstrate the importance of Hh signaling. Clones mutant for the Smoothened (smo), the gene responsible for transducing Hh signaling, retain anterior-like features, but move into the posterior compartment without any changes in the expression engrailed or invected.[13] This demonstrates that Hh signaling, rather than the absence of en, is what gives cells their compartmental identity.[16][18] Nonetheless, this signaling-affinity model is incomplete: smo mutant clones of anterior origin that migrate into the posterior compartment, do not completely associate with these cells, but rather form a smooth boundary with these posterior cells. If signaling-affinity were the only factor determining compartment identity, then these clones, which are no longer receiving Hh signaling, would have the same affinity as the other posterior cells in that compartment and be able to intermix with them.[13] These experiments indicate that although Hh signaling could be having an effect in adhesive properties, this effect is limited to the border cells rather than throughout both compartments.[5] It is also possible that both compartments produce the same cell adhesion molecules, but a difference in its abundance or activity could result in sorting between the two compartments. In vitro, transfected cells with high levels of a given adhesion molecule will segregate from cells that expressing lower levels of this same molecule.[23] Finally, differences in cell bond tension could also play a role in the establishment of the boundary and the separation of the two different cell populations. Experimental data has shown that Myosin-II is up-regulated along both the dorsal-ventral and anterior-posterior boundaries in the imaginal wing disc.[24][25] The D/V boundary is characterized by the presence of filamentous actin and mutations in Myosin-II heavy chain impairs D/V compartmentalization.[25] Similarly, both F-actin and Myosin-II are increased along the A/P boundary, accompanied by a decrease of Bazooka, which was also observed in the D/V border. The Rho-kinase inhibitor Y-27632, of which Myosin-II is the main target, significantly reduces cell bond tension, suggesting that Myosin-II could be the main effector of this process. In support of the signaling-affinity model, creating an artificial interface between cells with active vs. inactive Hh signaling induces a junctional behavior that aligns the cell bonds of where these opposing cell types meet.[24] Moreover, a 2.5-fold increase in mechanical tension is observed along the A/P boundary, compared to the rest of the tissue. Simulations using a vertex model demonstrate that this increase in cell bond tension is enough to maintain proliferating cell populations in separate compartment boundaries.[24] Parameters used to measure cell bond tension are based cell-cell adhesion and cortical tension input.[6] It has also been suggested that boundary formation is not a result of differential mechanical tension between the two cell populations, but could be a result of the mechanical properties of the boundary itself.[26] The level the adhesion molecule, E-cadherin, was unaltered and the biophysical properties of cells between the two compartments were the same. Changes in cell properties, such as an enlarged apical cross-section area, are only observed in anterior and posterior border cells.[24] Along the boundary, orientation of cell divisions was random and there is no evidence that increased cell death or zones of non-proliferating cells are important for maintaining the A/P or D/V boundary.[5]

Future directions

Despite many attempts to identify the adhesion molecules important for the establishment and maintenance of compartment boundaries, none have been identified.[6][22] Continuation of our understanding of this process will benefit from further experimental data on cell bonds and cortical tension, as well as screens to identify molecules regulating differential cell affinity.

References

  1. ^ a b Irvine KD, Rauskolb C (2001). "Boundaries in development: formation and function". Annu Rev Cell Dev Biol. 17: 189–214. doi:10.1146/annurev.cellbio.17.1.189. PMID 11687488.
  2. ^ a b c d Garcia-Bellido A, Ripoll P, Morata G (1973). "Developmental compartmentalisation of the wing disk of Drosophila" (PDF). Nat New Biol. 245 (147): 251–3. doi:10.1038/newbio245251a0. hdl:10261/47426. PMID 4518369.
  3. ^ Lumsden A. (1990). "The cellular basis of segmentation in the developing hindbrain". Trends Neurosci. 13 (8): 329–35. doi:10.1016/0166-2236(90)90144-Y. PMID 1699318. S2CID 3997227.
  4. ^ Fraser S, Keynes R, Lumsden A (1990). "Segmentation in the chick embryo hindbrain is defined by cell lineage restrictions". Nature. 344 (6265): 431–5. Bibcode:1990Natur.344..431F. doi:10.1038/344431a0. PMID 2320110. S2CID 4355552.
  5. ^ a b c d e f Dahmann C, Basler K (1999). "Compartment boundaries: at the edge of development". Trends Genet. 15 (8): 320–6. doi:10.1016/S0168-9525(99)01774-6. PMID 10431194.
  6. ^ a b c d e Vincent JP, Irons D (2009). "Developmental biology: tension at the border". Curr Biol. 19 (22): 1028–30. doi:10.1016/j.cub.2009.10.030. PMID 19948137.
  7. ^ a b c Blair SS. (1995). "Compartments and appendage development in Drosophila". BioEssays. 17 (4): 299–309. doi:10.1002/bies.950170406. PMID 7741723. S2CID 25693875.
  8. ^ a b c d e f g h i Lawrence PA, Struhl G (1996). "Morphogens, compartments, and pattern: lessons from drosophila?". Cell. 85 (7): 951–61. doi:10.1016/S0092-8674(00)81297-0. PMID 8674123.
  9. ^ a b Meinhardt H. (1983). "A boundary model for pattern formation in vertebrate limbs". J Embryol Exp Morphol. 76: 115–37. PMID 6631316.
  10. ^ Meinhardt H. (1983). "Cell determination boundaries as organizing regions for secondary embryonic fields". Dev Biol. 96 (2): 375–85. doi:10.1016/0012-1606(83)90175-6. PMID 6832478.
  11. ^ Simpson P, Morata G (1981). "Differential mitotic rates and patterns of growth in compartments in the Drosophila wing". Dev Biol. 85 (2): 299–308. doi:10.1016/0012-1606(81)90261-X. PMID 7262460.
  12. ^ a b c d Morata G, Lawrence PA (1975). "Control of compartment development by the engrailed gene in Drosophila". Nature. 255 (5510): 614–7. Bibcode:1975Natur.255..614M. doi:10.1038/255614a0. PMID 1134551. S2CID 4299506.
  13. ^ a b c d e f Blair SS, Ralston A (1997). "Smoothened-mediated Hedgehog signalling is required for the maintenance of the anterior-posterior lineage restriction in the developing wing of Drosophila". Development. 124 (20): 4053–63. doi:10.1242/dev.124.20.4053. PMID 9374402.
  14. ^ a b c García-Bellido A. (1975). "Genetic control of wing disc development in Drosophila". Ciba Found Symp. Novartis Foundation Symposia (29): 161–82. doi:10.1002/9780470720110.ch8. hdl:10261/47429. ISBN 9780470720110. PMID 1039909.
  15. ^ a b c Basler K, Struhl G (1994). "Compartment boundaries and the control of Drosophila limb pattern by hedgehog protein". Nature. 368 (6468): 208–14. Bibcode:1994Natur.368..208B. doi:10.1038/368208a0. PMID 8145818. S2CID 4354288.
  16. ^ a b c d e f Zecca M, Basler K, Struhl G (1995). "Sequential organizing activities of engrailed, hedgehog and decapentaplegic in the Drosophila wing" (PDF). Development. 121 (8): 2265–78. doi:10.1242/dev.121.8.2265. PMID 7671794.
  17. ^ a b Vincent JP.. (1998). "Compartment boundaries: where, why and how?". Int J Dev Biol. 42 (3): 311–5. PMID 9654014.
  18. ^ a b c d e f Tabata T, Schwartz C, Gustavson E, Ali Z, Kornberg TB (1995). "Creating a Drosophila wing de novo, the role of engrailed, and the compartment border hypothesis". Development. 121 (10): 3359–69. doi:10.1242/dev.121.10.3359. PMID 7588069.
  19. ^ a b Guillén I, Mullor JL, Capdevila J, Sánchez-Herrero E, Morata G, Guerrero (1995). "The function of engrailed and the specification of Drosophila wing pattern". Development. 121 (10): 3447–56. doi:10.1242/dev.121.10.3447. hdl:10261/150365. PMID 7588077.
  20. ^ Tabata T, Kornberg TB (1994). "Hedgehog is a signaling protein with a key role in patterning Drosophila imaginal discs". Cell. 76 (1): 89–102. doi:10.1016/0092-8674(94)90175-9. PMID 8287482. S2CID 2364822.
  21. ^ Shen J, Dahmann C (2005). "The role of Dpp signaling in maintaining the Drosophila anteroposterior compartment boundary". Dev Biol. 279 (1): 31–43. doi:10.1016/j.ydbio.2004.11.033. PMID 15708556.
  22. ^ a b Végh M, Basler K (2003). "A genetic screen for hedgehog targets involved in the maintenance of the Drosophila anteroposterior compartment boundary". Genetics. 163 (4): 1427–38. doi:10.1093/genetics/163.4.1427. PMC 1462513. PMID 12702686.
  23. ^ Steinberg MS, Takeichi M (1994). "Experimental specification of cell sorting, tissue spreading, and specific spatial patterning by quantitative differences in cadherin expression". Proc. Natl. Acad. Sci. USA. 91 (1): 206–9. Bibcode:1994PNAS...91..206S. doi:10.1073/pnas.91.1.206. PMC 42915. PMID 8278366.
  24. ^ a b c d Landsberg KP, Farhadifar R, Ranft J, Umetsu D, Widmann TJ, Bittig T, Said A, Jülicher F, Dahmann C (2009). "Increased cell bond tension governs cell sorting at the Drosophila anteroposterior compartment boundary". Curr Biol. 19 (22): 1950–5. doi:10.1016/j.cub.2009.10.021. PMID 19879142.
  25. ^ a b Major RJ, Irvine KD (2006). "Localization and requirement for Myosin II at the dorsal-ventral compartment boundary of the Drosophila wing". Dev Dyn. 235 (11): 3051–8. doi:10.1002/dvdy.20966. PMID 17013876.
  26. ^ Martin AC, Wieschaus EF (2010). "Tensions divide". Nat Cell Biol. 12 (1): 5–7. doi:10.1038/ncb0110-5. PMID 20027198. S2CID 19552256.

August 24, 2023
compartment, development, compartments, simply, defined, separate, different, adjacent, cell, populations, which, upon, juxtaposition, create, lineage, boundary, this, boundary, prevents, cell, movement, from, cells, from, different, lineages, across, this, ba. Compartments can be simply defined as separate different adjacent cell populations which upon juxtaposition create a lineage boundary 1 This boundary prevents cell movement from cells from different lineages across this barrier restricting them to their compartment 2 Subdivisions are established by morphogen gradients and maintained by local cell cell interactions providing functional units with domains of different regulatory genes which give rise to distinct fates 1 Compartment boundaries are found across species In the hindbrain of vertebrate embryos rhombomeres are compartments of common lineage 3 outlined by expression of Hox genes 4 In invertebrates the wing imaginal disc of Drosophila provides an excellent model for the study of compartments Although other tissues such as the abdomen 5 and even other imaginal discs are compartmentalized much of our understanding of key concepts and molecular mechanisms involved in compartment boundaries has been derived from experimentation in the wing disc of the fruit fly Contents 1 Function 2 Cell separation 3 Central dogma 4 A P boundary 5 Cell segregation 6 Future directions 7 ReferencesFunction EditBy separating different cell populations the fate of these compartments are highly organized and regulated 6 In addition this separation creates a region of specialized cells close to the boundary 7 which serves as a signaling center for the patterning polarizing and proliferation 8 of the entire disc Compartment boundaries establish these organizing centers 5 7 by providing the source of morphogens 9 that are responsible for the positional information required for development and regeneration 9 10 The inability of cell competition to occur across the boundary indicates that each compartment serves as an autonomous unit of growth 8 11 Differences in growth rates and patterns in each compartment maintain the two lineages separated 12 and each control the precise size of the imaginal discs 13 Cell separation EditThese two cell populations are kept separate by a mechanism of cell segregation linked to the heritable expression of a selector gene 7 A selector gene is one that is expressed in one group of cells but not the other 5 giving the founder cells and their descendants different instructions 12 Eventually these selector genes become fixed in either an expressed or unexpressed state and are stably inherited to the descendants 5 8 specifying the identity of the compartment and preventing these genetically different cell populations from intermixing 13 Therefore these selector genes are key for the formation and maintenance of lineage compartments 14 Central dogma EditThe difference in selector gene activity not only establishes two compartments but also leads to the formation of a boundary between these two that serves as a source of morphogen gradients In the central dogma of compartments first morphogen gradients position founder compartment cells 2 8 Then active inactive selector genes give a unique genetic identity to cells within a compartment instructing their fate and their interactions with the neighboring compartment 8 14 Finally border cells established by short range signaling from one compartment to its neighboring compartment 15 emit long range signals that spread to both compartments to regulate the growth and pattering of the entire tissue 8 16 A P boundary EditIn 1970 by means of clonal analysis the Anterior Posterior boundary was identified 2 The founder cells found at the border between parasegments 4 and 5 of embryo are already determined at the early blastoderm stage and defined into the two populations they will generate by stripes of the engrailed gene 2 8 17 The selector gene engrailed en is a key determinant in boundary formation between the anterior and posterior compartments 12 As the wing imaginal disc expands posterior but not anterior cells will express engrailed and maintain this expression state as they expand and form the disc 17 Engrailed mutant clones of posterior origin will gain anterior affinity and move towards the anterior compartment and intermix with those cells Within the posterior compartment these clones will sort out and form an ectopic border where they meet other posterior cells 12 16 18 Similarly a clone of anterior cells expressing engrailed will gain posterior identity and create an ectopic boundary where the clone meets other anterior cells in this compartment 16 In addition to its cell autonomous role in specifying posterior compartment identity engrailed also has a non cell autonomous function in the general growth and patterning of the wing disc through the activation of signaling pathways such as Hedgehog Hh and Decapentaplegic Dpp 18 19 20 The presence of engrailed in the posterior cells leads to the secretion of the short range inducer Hh 8 which can cross over to the anterior compartment to activate the long range morphogen Dpp 15 16 Cells in the posterior compartment produce Hh but only anterior cells can transduce the signal 6 Optomotor blind omb is involved in the transcriptional response of Dpp which is only required in the anterior cells to interpret Hh signaling for boundary formation and maintenance 21 In addition Cubitus interruptus Ci the signal transducer of the Hh signal is expressed throughout the anterior compartment particularly in anterior border cells 18 In posterior cells engrailed prevents the expression of Ci such it is only expressed in anterior cells and hence only these cells can respond to Hh signaling by up regulating the expression of dpp 15 22 Loss of engrailed function in posterior cells results in anterior transformation where Hh expression is decreased and dpp ci and patched ptc is increased resulting in the formation of a new A P boundary suggesting that en positively regulateshh while negatively regulating ci ptc and dpp 18 19 Cell segregation EditTo explain how anterior and posterior cells are kept separated the differential adhesion hypothesis proposes that these two cell populations express different adhesion molecules producing different affinities for each other that minimize their contact 6 8 The selector affinity model proposes that difference in cell affinity between compartments is a result of differential selector gene expression 14 The presence or absence of selector genes in a given compartment produces compartment specific adhesion or recognition molecules that are different from those in its counterpart 13 For example engrailed expressed in the posterior but not the anterior cells provides the differential affinity that keeps these compartments separately It is also possible that this difference in cell adhesion affinity is not directly due to en expression but rather to the ability to receive Hh signaling 16 18 Anterior cells capable of Hh transduction will express given adhesive molecules that would differ from those present in posterior cells creating differential affinity that would prevent them from intermixing 13 This signaling affinity model is supported by experiments that demonstrate the importance of Hh signaling Clones mutant for the Smoothened smo the gene responsible for transducing Hh signaling retain anterior like features but move into the posterior compartment without any changes in the expression engrailed or invected 13 This demonstrates that Hh signaling rather than the absence of en is what gives cells their compartmental identity 16 18 Nonetheless this signaling affinity model is incomplete smo mutant clones of anterior origin that migrate into the posterior compartment do not completely associate with these cells but rather form a smooth boundary with these posterior cells If signaling affinity were the only factor determining compartment identity then these clones which are no longer receiving Hh signaling would have the same affinity as the other posterior cells in that compartment and be able to intermix with them 13 These experiments indicate that although Hh signaling could be having an effect in adhesive properties this effect is limited to the border cells rather than throughout both compartments 5 It is also possible that both compartments produce the same cell adhesion molecules but a difference in its abundance or activity could result in sorting between the two compartments In vitro transfected cells with high levels of a given adhesion molecule will segregate from cells that expressing lower levels of this same molecule 23 Finally differences in cell bond tension could also play a role in the establishment of the boundary and the separation of the two different cell populations Experimental data has shown that Myosin II is up regulated along both the dorsal ventral and anterior posterior boundaries in the imaginal wing disc 24 25 The D V boundary is characterized by the presence of filamentous actin and mutations in Myosin II heavy chain impairs D V compartmentalization 25 Similarly both F actin and Myosin II are increased along the A P boundary accompanied by a decrease of Bazooka which was also observed in the D V border The Rho kinase inhibitor Y 27632 of which Myosin II is the main target significantly reduces cell bond tension suggesting that Myosin II could be the main effector of this process In support of the signaling affinity model creating an artificial interface between cells with active vs inactive Hh signaling induces a junctional behavior that aligns the cell bonds of where these opposing cell types meet 24 Moreover a 2 5 fold increase in mechanical tension is observed along the A P boundary compared to the rest of the tissue Simulations using a vertex model demonstrate that this increase in cell bond tension is enough to maintain proliferating cell populations in separate compartment boundaries 24 Parameters used to measure cell bond tension are based cell cell adhesion and cortical tension input 6 It has also been suggested that boundary formation is not a result of differential mechanical tension between the two cell populations but could be a result of the mechanical properties of the boundary itself 26 The level the adhesion molecule E cadherin was unaltered and the biophysical properties of cells between the two compartments were the same Changes in cell properties such as an enlarged apical cross section area are only observed in anterior and posterior border cells 24 Along the boundary orientation of cell divisions was random and there is no evidence that increased cell death or zones of non proliferating cells are important for maintaining the A P or D V boundary 5 Future directions EditDespite many attempts to identify the adhesion molecules important for the establishment and maintenance of compartment boundaries none have been identified 6 22 Continuation of our understanding of this process will benefit from further experimental data on cell bonds and cortical tension as well as screens to identify molecules regulating differential cell affinity References Edit a b Irvine KD Rauskolb C 2001 Boundaries in development formation and function Annu Rev Cell Dev Biol 17 189 214 doi 10 1146 annurev cellbio 17 1 189 PMID 11687488 a b c d Garcia Bellido A Ripoll P Morata G 1973 Developmental compartmentalisation of the wing disk of Drosophila PDF Nat New Biol 245 147 251 3 doi 10 1038 newbio245251a0 hdl 10261 47426 PMID 4518369 Lumsden A 1990 The cellular basis of segmentation in the developing hindbrain Trends Neurosci 13 8 329 35 doi 10 1016 0166 2236 90 90144 Y PMID 1699318 S2CID 3997227 Fraser S Keynes R Lumsden A 1990 Segmentation in the chick embryo hindbrain is defined by cell lineage restrictions Nature 344 6265 431 5 Bibcode 1990Natur 344 431F doi 10 1038 344431a0 PMID 2320110 S2CID 4355552 a b c d e f Dahmann C Basler K 1999 Compartment boundaries at the edge of development Trends Genet 15 8 320 6 doi 10 1016 S0168 9525 99 01774 6 PMID 10431194 a b c d e Vincent JP Irons D 2009 Developmental biology tension at the border Curr Biol 19 22 1028 30 doi 10 1016 j cub 2009 10 030 PMID 19948137 a b c Blair SS 1995 Compartments and appendage development in Drosophila BioEssays 17 4 299 309 doi 10 1002 bies 950170406 PMID 7741723 S2CID 25693875 a b c d e f g h i Lawrence PA Struhl G 1996 Morphogens compartments and pattern lessons from drosophila Cell 85 7 951 61 doi 10 1016 S0092 8674 00 81297 0 PMID 8674123 a b Meinhardt H 1983 A boundary model for pattern formation in vertebrate limbs J Embryol Exp Morphol 76 115 37 PMID 6631316 Meinhardt H 1983 Cell determination boundaries as organizing regions for secondary embryonic fields Dev Biol 96 2 375 85 doi 10 1016 0012 1606 83 90175 6 PMID 6832478 Simpson P Morata G 1981 Differential mitotic rates and patterns of growth in compartments in the Drosophila wing Dev Biol 85 2 299 308 doi 10 1016 0012 1606 81 90261 X PMID 7262460 a b c d Morata G Lawrence PA 1975 Control of compartment development by the engrailed gene in Drosophila Nature 255 5510 614 7 Bibcode 1975Natur 255 614M doi 10 1038 255614a0 PMID 1134551 S2CID 4299506 a b c d e f Blair SS Ralston A 1997 Smoothened mediated Hedgehog signalling is required for the maintenance of the anterior posterior lineage restriction in the developing wing of Drosophila Development 124 20 4053 63 doi 10 1242 dev 124 20 4053 PMID 9374402 a b c Garcia Bellido A 1975 Genetic control of wing disc development in Drosophila Ciba Found Symp Novartis Foundation Symposia 29 161 82 doi 10 1002 9780470720110 ch8 hdl 10261 47429 ISBN 9780470720110 PMID 1039909 a b c Basler K Struhl G 1994 Compartment boundaries and the control of Drosophila limb pattern by hedgehog protein Nature 368 6468 208 14 Bibcode 1994Natur 368 208B doi 10 1038 368208a0 PMID 8145818 S2CID 4354288 a b c d e f Zecca M Basler K Struhl G 1995 Sequential organizing activities of engrailed hedgehog and decapentaplegic in the Drosophila wing PDF Development 121 8 2265 78 doi 10 1242 dev 121 8 2265 PMID 7671794 a b Vincent JP 1998 Compartment boundaries where why and how Int J Dev Biol 42 3 311 5 PMID 9654014 a b c d e f Tabata T Schwartz C Gustavson E Ali Z Kornberg TB 1995 Creating a Drosophila wing de novo the role of engrailed and the compartment border hypothesis Development 121 10 3359 69 doi 10 1242 dev 121 10 3359 PMID 7588069 a b Guillen I Mullor JL Capdevila J Sanchez Herrero E Morata G Guerrero 1995 The function of engrailed and the specification of Drosophila wing pattern Development 121 10 3447 56 doi 10 1242 dev 121 10 3447 hdl 10261 150365 PMID 7588077 Tabata T Kornberg TB 1994 Hedgehog is a signaling protein with a key role in patterning Drosophila imaginal discs Cell 76 1 89 102 doi 10 1016 0092 8674 94 90175 9 PMID 8287482 S2CID 2364822 Shen J Dahmann C 2005 The role of Dpp signaling in maintaining the Drosophila anteroposterior compartment boundary Dev Biol 279 1 31 43 doi 10 1016 j ydbio 2004 11 033 PMID 15708556 a b Vegh M Basler K 2003 A genetic screen for hedgehog targets involved in the maintenance of the Drosophila anteroposterior compartment boundary Genetics 163 4 1427 38 doi 10 1093 genetics 163 4 1427 PMC 1462513 PMID 12702686 Steinberg MS Takeichi M 1994 Experimental specification of cell sorting tissue spreading and specific spatial patterning by quantitative differences in cadherin expression Proc Natl Acad Sci USA 91 1 206 9 Bibcode 1994PNAS 91 206S doi 10 1073 pnas 91 1 206 PMC 42915 PMID 8278366 a b c d Landsberg KP Farhadifar R Ranft J Umetsu D Widmann TJ Bittig T Said A Julicher F Dahmann C 2009 Increased cell bond tension governs cell sorting at the Drosophila anteroposterior compartment boundary Curr Biol 19 22 1950 5 doi 10 1016 j cub 2009 10 021 PMID 19879142 a b Major RJ Irvine KD 2006 Localization and requirement for Myosin II at the dorsal ventral compartment boundary of the Drosophila wing Dev Dyn 235 11 3051 8 doi 10 1002 dvdy 20966 PMID 17013876 Martin AC Wieschaus EF 2010 Tensions divide Nat Cell Biol 12 1 5 7 doi 10 1038 ncb0110 5 PMID 20027198 S2CID 19552256 Retrieved 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