Branching Morphogenesis of the<i>Drosophila</i>Tracheal System

Ghabrial, Amin S.; Luschnig, Stefan; Metzstein, Mark M.; Krasnow, Mark A.

doi:10.1146/annurev.cellbio.19.031403.160043

Cited by 307 publications

(306 citation statements)

References 100 publications

(98 reference statements)

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“…In Drosophila melanogaster, genetic studies have provided much insight into the regulatory networks that regulate the ordered formation of tracheal branches in the embryo, and into how the different branches coordinate their relative sizes, an issue that is of importance to the physical aspects of branched organ function (Affolter et al, 2003;Ghabrial et al, 2003;Uv et al, 2003). More recently, the development of live-imaging approaches in Drosophila have allowed researchers to take a deeper look at the behaviour of cells during the branching process, and have enabled events at the molecular level to be linked to the behaviour of individual cells or groups of cells.…”

Section: Introductionmentioning

confidence: 99%

Tracheal branching morphogenesis inDrosophila: new insights into cell behaviour and organ architecture

2008

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2055Our understanding of the molecular control of morphological processes has increased tremendously over recent years through the development and use of high resolution in vivo imaging approaches, which have enabled cell behaviour to be linked to molecular functions. Here we review how such approaches have furthered our understanding of tracheal branching morphogenesis in Drosophila, during which the control of cell invagination, migration, competition and rearrangement is accompanied by the sequential secretion and resorption of proteins into the apical luminal space, a vital step in the elaboration of the trachea's complex tubular network. We also discuss the similarities and differences between flies and vertebrates in branched organ formation that are becoming apparent from these studies. IntroductionBranching morphogenesis restructures epithelial sheets to give rise to organs of fascinating three-dimensional architecture, as exemplified by the adult lung, the kidney and the vasculature in humans. In Drosophila melanogaster, genetic studies have provided much insight into the regulatory networks that regulate the ordered formation of tracheal branches in the embryo, and into how the different branches coordinate their relative sizes, an issue that is of importance to the physical aspects of branched organ function (Affolter et al., 2003;Ghabrial et al., 2003;Uv et al., 2003). More recently, the development of live-imaging approaches in Drosophila have allowed researchers to take a deeper look at the behaviour of cells during the branching process, and have enabled events at the molecular level to be linked to the behaviour of individual cells or groups of cells.This combination of molecular genetics and live-imaging techniques has provided investigators with a unique opportunity to understand the morphological processes that occur during branching morphogenesis. This review focuses and builds on some of these recent insights, and assesses how they have led to a better understanding of the cellular and molecular processes that contribute to the transformation of simple, two-dimensional epithelial sheets into fascinating, three-dimensional tubular structures that can perform important functions in development and homeostasis. We focus here on the Drosophila tracheal system because several cellular and molecular paradigms, such as cell migration, competition and rearrangement, as well as the elaboration of a complex apical luminal environment, have recently been uncovered in this system that might serve related roles in the formation of other branched organs or tissues; these similarities might help us in the future to gain an even better understanding of how morphogenesis in general is regulated during development. Tracheal development in the fly embryoThe complex structure of the tracheal system consists of interconnected, metameric units of different-sized tubes that extend over the entire embryo shortly before hatching (Samakovlis et al., 1996b) (see Fig. 1, see also Movie 1 in the supplementary material)....

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Section: Introductionmentioning

confidence: 99%

Tracheal branching morphogenesis inDrosophila: new insights into cell behaviour and organ architecture

2008

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“…The development of the ductal network takes places through branching morphogenesis, a process by which a rudimentary ductal structure initiates, extends, bifurcates, and differentiates to give rise to the mature tubular organ (Affolter et al, 2003;Ghabrial et al, 2003). The iterative nature of ductal morphogenesis allows a large epithelial surface area to be generated in limited space, which is essential because these organs function in air/ fluid exchange and secretion.…”

Section: Introductionmentioning

confidence: 99%

Candidate regulators of mammary branching morphogenesis identified by genome‐wide transcript analysis

Kouros-Mehr¹,

Werb

2006

Developmental Dynamics

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The mammary gland develops in a process known as branching morphogenesis, whereby a distal epithelial bud extends and bifurcates to form an extensive ductal network. Compared with other branched organs, such as the lung and kidney, little is known about the molecular basis of branching in the mammary gland. Here we report a microarray profiling strategy to identify novel genes that may regulate mammary branching. We microdissected terminal end bud (TEB) and mature duct microenvironments from ␤-actin-green fluorescent protein reporter mice and compared their RNA expression profiles with epithelium-free mammary stroma by means of microarray. We identified 1,074 genes enriched in the TEB microenvironment, 222 genes enriched in the mature duct microenvironment, and 385 genes enriched in both TEB and mature duct microenvironments. The microarray correctly predicted the expression of genes known to be enriched in the epithelium (Ets-5) and stroma (MMP-14) of TEBs and in the mature duct microenvironment (MMP-3). The microarray also correctly predicted the localization of previously uncharacterized genes, such as the TEB-enriched SPRR-1a, the duct-enriched casein-␥, and the general epithelial marker pleiotrophin. Analysis of genes enriched in TEBs revealed several genes in the Wnt (Wnt-2, Wnt-5a, Wnt-7b, Dsh-3, Frizzled-1, Frizzled-2), hedgehog (Dhh), ephrin (Ephrin-B1, Eph-A2), and transcription factor (Twist-1, Twist-2, Snail) families. In situ hybridization verified that these genes were enriched in the TEB epithelium (Wnt-5a, Wnt-7b, Dhh, Eph-A2) or TEB stroma (Wnt-2, Frizzled-1, Ephrin-B1). We discuss the potential roles of these genes in mammary branching morphogenesis. Developmental Dynamics 235:3404 -3412, 2006.

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“…escargot encodes a zinc-finger protein with a role in the fusion of tracheal tubes (Zelzer and Shilo 2000;Ghabrial et al 2003) and PNS development (Norga et al 2003). Line BG02419, which has the P-element insertion 1 kb from the 59-end of escargot, had significantly reduced sleep in both males and females (Table 3).…”

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confidence: 99%

Quantitative Genetic Analysis of Sleep inDrosophila melanogaster

Harbison

Sehgal

2008

Genetics

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Although intensively studied, the biological purpose of sleep is not known. To identify candidate genes affecting sleep, we assayed 136 isogenic P-element insertion lines of Drosophila melanogaster. Since sleep has been negatively correlated with energy reserves across taxa, we measured energy stores (whole-body protein, glycogen, and triglycerides) in these lines as well. Twenty-one insertions with known effects on physiology, development, and behavior affect 24-hr sleep time. Thirty-two candidate insertions significantly impact energy stores. Mutational genetic correlations among sleep parameters revealed that the genetic basis of the transition between sleep and waking states in males and females may be different. Furthermore, sleep bout number can be decoupled from waking activity in males, but not in females. Significant genetic correlations are present between sleep phenotypes and glycogen stores in males, while sleep phenotypes are correlated with triglycerides in females. Differences observed in male and female sleep behavior in flies may therefore be related to sex-specific differences in metabolic needs. Sleep thus emerges as a complex trait that exhibits extensive pleiotropy and sex specificity. The large mutational target that we observed implicates genes functioning in a variety of biological processes, suggesting that sleep may serve a number of different functions rather than a single purpose.

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Branching Morphogenesis of theDrosophilaTracheal System

Cited by 307 publications

References 100 publications

Tracheal branching morphogenesis inDrosophila: new insights into cell behaviour and organ architecture

Tracheal branching morphogenesis inDrosophila: new insights into cell behaviour and organ architecture

Candidate regulators of mammary branching morphogenesis identified by genome‐wide transcript analysis

Quantitative Genetic Analysis of Sleep inDrosophila melanogaster

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