Faculty Opinions recommendation of Cell shape changes indicate a role for extrinsic tensile forces in Drosophila germ-band extension.

Drosophila embryos lacking hindsight gene function have a normal body plan and undergo normal germ-band extension. However, they fail to retract their germ bands. hindsight encodes a large nuclear protein of 1920 amino acids that contains fourteen C2H2-type zinc fingers, and glutamine-rich and proline-rich domains, suggesting that it functions as a transcription factor. Initial embryonic expression of hindsight RNA and protein occurs in the endoderm (midgut) and extraembryonic membrane (amnioserosa) prior to germ-band extension and continues in these tissues beyond the completion of germ-band retraction. Expression also occurs in the developing tracheal system, central and peripheral nervous systems, and the ureter of the Malpighian tubules. Strikingly, hindsight is not expressed in the epidermal ectoderm which is the tissue that undergoes the cell shape changes and movements during germ-band retraction. The embryonic midgut can be eliminated without affecting germ-band retraction. However, elimination of the amnioserosa results in the failure of germ-band retraction, implicating amnioserosal expression of hindsight as crucial for this process. Ubiquitous expression of hindsight in the early embryo rescues germ-band retraction without producing dominant gain-of-function defects, suggesting that hindsight's role in germ-band retraction is permissive rather than instructive. Previous analyses have shown that hindsight is required for maintenance of the differentiated amnioserosa (Frank, L. C. and Rushlow, C. (1996) Development 122, 1343–1352). Two classes of models are consistent with the present data. First, hindsight's function in germ-band retraction may be limited to maintenance of the amnioserosa which then plays a physical role in the retraction process through contact with cells of the epidermal ectoderm. Second, hindsight might function both to maintain the amnioserosa and to regulate chemical signaling from the amnioserosa to the epidermal ectoderm, thus coordinating the cell shape changes and movements that drive germ-band retraction.

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Mechanisms of early Drosophila mesoderm formation

Development ◽

10.1242/dev.116.supplement.23 ◽

1992 ◽

Vol 116 (Supplement) ◽

pp. 23-31 ◽

Cited By ~ 3

Author(s):

Maria Leptin ◽

José Casal ◽

Barbara Grunewald ◽

Rolf Reuter

Keyword(s):

Cell Shape ◽

Cell Populations ◽

Genetic Screens ◽

Germ Band ◽

Posterior Midgut ◽

Ventral Furrow ◽

Mesoderm Formation ◽

Cell Shape Changes ◽

Shape Changes ◽

Different Parts

Several morphogenetic processes occur simultaneously during Drosophila gastrulation, including ventral furrow invagination to form the mesoderm, anterior and posterior midgut invagination to create the endoderm, and germ band extension. Mutations changing the behaviour of different parts of the embryo can be used to test the roles of different cell populations in gastrulation. Posterior midgut morphogenesis and germ band extension are partly independent, and neither depends on mesoderm formation, nor mesoderm formation on them. The invagination of the ventral furrow is caused by forces from within the prospective mesoderm (i. e. the invaginating cells) without any necessary contribution from other parts of the embryo. The events that lead to the cell shape changes mediating ventral furrow formation require the transcription of zygotic genes under the control of twist and snail. Such genes can be isolated by molecular and genetic screens.

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Faculty Opinions recommendation of The RhoGEF Pebble is required for cell shape changes during cell migration triggered by the Drosophila FGF receptor Heartless.

Faculty Opinions – Post-Publication Peer Review of the Biomedical Literature ◽

10.3410/f.1019583.240595 ◽

2004 ◽

Author(s):

Deborah Andrew

Keyword(s):

Cell Migration ◽

Cell Shape ◽

Fgf Receptor ◽

Cell Shape Changes ◽

Shape Changes

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Faculty Opinions recommendation of The RhoGEF Pebble is required for cell shape changes during cell migration triggered by the Drosophila FGF receptor Heartless.

Faculty Opinions – Post-Publication Peer Review of the Biomedical Literature ◽

10.3410/f.1019583.222456 ◽

2004 ◽

Author(s):

Michel Labouesse

Keyword(s):

Cell Migration ◽

Cell Shape ◽

Fgf Receptor ◽

Cell Shape Changes ◽

Shape Changes

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A genetic screen for temperature-sensitive morphogenesis-defectiveCaenorhabditis elegansmutants

G3 Genes|Genome|Genetics ◽

10.1093/g3journal/jkab026 ◽

2021 ◽

Vol 11 (4) ◽

Author(s):

Molly C Jud ◽

Josh Lowry ◽

Thalia Padilla ◽

Erin Clifford ◽

Yuqi Yang ◽

...

Keyword(s):

Cell Shape ◽

The Body ◽

Temperature Sensitive ◽

Restrictive Temperature ◽

Fundamental Biological Process ◽

Embryonic Morphogenesis ◽

Cell Shape Changes ◽

Development Temperature ◽

Multicellular Organisms ◽

Shape Changes

AbstractMorphogenesis involves coordinated cell migrations and cell shape changes that generate tissues and organs, and organize the body plan. Cell adhesion and the cytoskeleton are important for executing morphogenesis, but their regulation remains poorly understood. As genes required for embryonic morphogenesis may have earlier roles in development, temperature-sensitive embryonic-lethal mutations are useful tools for investigating this process. From a collection of ∼200 such Caenorhabditis elegans mutants, we have identified 17 that have highly penetrant embryonic morphogenesis defects after upshifts from the permissive to the restrictive temperature, just prior to the cell shape changes that mediate elongation of the ovoid embryo into a vermiform larva. Using whole genome sequencing, we identified the causal mutations in seven affected genes. These include three genes that have roles in producing the extracellular matrix, which is known to affect the morphogenesis of epithelial tissues in multicellular organisms: the rib-1 and rib-2 genes encode glycosyltransferases, and the emb-9 gene encodes a collagen subunit. We also used live imaging to characterize epidermal cell shape dynamics in one mutant, or1219ts, and observed cell elongation defects during dorsal intercalation and ventral enclosure that may be responsible for the body elongation defects. These results indicate that our screen has identified factors that influence morphogenesis and provides a platform for advancing our understanding of this fundamental biological process.

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Adaptation of a ciliary basal apparatus to cell shape changes in a contractile epithelium

Tissue and Cell ◽

10.1016/0040-8166(85)90051-5 ◽

1985 ◽

Vol 17 (3) ◽

pp. 321-334 ◽

Cited By ~ 12

Author(s):

M.C. Holley

Keyword(s):

Cell Shape ◽

Basal Apparatus ◽

Cell Shape Changes ◽

Shape Changes

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Estradiol promotes cell shape changes and glial fibrillary acidic protein redistribution in hypothalamic astrocytes in vitro: A neuronal-mediated effect

Glia ◽

10.1002/glia.440060305 ◽

1992 ◽

Vol 6 (3) ◽

pp. 180-187 ◽

Cited By ~ 65

Author(s):

Ignacio Torres-Aleman ◽

Maria Teresa Rejas ◽

Sebastian Pons ◽

Luis Miguel Garcia-Segura

Keyword(s):

Glial Fibrillary Acidic Protein ◽

Cell Shape ◽

Acidic Protein ◽

Cell Shape Changes ◽

Shape Changes

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Dependency relationships between IFT-dependent flagellum elongation and cell morphogenesis in Leishmania

Open Biology ◽

10.1098/rsob.180124 ◽

2018 ◽

Vol 8 (11) ◽

pp. 180124 ◽

Cited By ~ 3

Author(s):

Jack Daniel Sunter ◽

Flavia Moreira-Leite ◽

Keith Gull

Keyword(s):

Fluorescence Microscopy ◽

Cell Shape ◽

Electron Tomography ◽

Intraflagellar Transport ◽

Flagellar Pocket ◽

Cell Morphogenesis ◽

Multiple Functions ◽

Cell Shape Changes ◽

Shape Changes

Flagella have multiple functions that are associated with different axonemal structures. Motile flagella typically have a 9 + 2 arrangement of microtubules, whereas sensory flagella normally have a 9 + 0 arrangement. Leishmania exhibits both of these flagellum forms and differentiation between these two flagellum forms is associated with cytoskeletal and cell shape changes. We disrupted flagellum elongation in Leishmania by deleting the intraflagellar transport (IFT) protein IFT140 and examined the effects on cell morphogenesis. Δift140 cells have no external flagellum, having only a very short flagellum within the flagellar pocket. This short flagellum had a collapsed 9 + 0 (9v) axoneme configuration reminiscent of that in the amastigote and was not attached to the pocket membrane. Although amastigote-like changes occurred in the flagellar cytoskeleton, the cytoskeletal structures of Δift140 cells retained their promastigote configurations, as examined by fluorescence microscopy of tagged proteins and serial electron tomography. Thus, Leishmania promastigote cell morphogenesis does not depend on the formation of a long flagellum attached at the neck. Furthermore, our data show that disruption of the IFT system is sufficient to produce a switch from the 9 + 2 to the collapsed 9 + 0 (9v) axonemal structure, echoing the process that occurs during the promastigote to amastigote differentiation.

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