135 research outputs found
L1-determined ideals in group algebras of exponential Lie groups
A locally compact group is said to be -regular if the natural map
\Psi:\Prim C^\ast(G)\to\Prim_{\ast} L^1(G) is a homeomorphism with respect to
the Jacobson topologies on the primitive ideal spaces \Prim C^\ast(G) and
\Prim_{\ast} L^1(G). In 1980 J. Boidol characterized the -regular ones
among all exponential Lie groups by a purely algebraic condition. In this
article we introduce the notion of -determined ideals in order to discuss
the weaker property of primitive -regularity. We give two sufficient
criteria for closed ideals of to be -determined. Herefrom
we deduce a strategy to prove that a given exponential Lie group is primitive
-regular. The author proved in his thesis that all exponential Lie groups
of dimension have this property. So far no counter-example is known.
Here we discuss the example , the only critical one in dimension
A Small Genomic Region Containing Several Loci Required for Gastrulation in Drosophila
Genetic screens in Drosophila designed to search for loci involved in gastrulation have identified four regions of the genome that are required zygotically for the formation of the ventral furrow. For three of these, the genes responsible for the mutant phenotypes have been found. We now describe a genetic characterization of the fourth region, which encompasses the cytogenetic interval 24C3-25B, and the mapping of genes involved in gastrulation in this region. We have determined the precise breakpoints of several existing deficiencies and have generated new deficiencies. Our results show that the region contains at least three different loci associated with gastrulation effects. One maternal effect gene involved in ventral furrow formation maps at 24F but could not be identified. For a second maternal effect gene which is required for germ band extension, we identify a candidate gene, CG31660, which encodes a G protein coupled receptor. Finally, one gene acts zygotically in ventral furrow formation and we identify it as Traf4
Dynamic myosin phosphorylation regulates contractile pulses and tissue integrity during epithelial morphogenesis
Apical constriction is a cell shape change that promotes epithelial bending. Activation of nonmuscle myosin II (Myo-II) by kinases such as Rho-associated kinase (Rok) is important to generate contractile force during apical constriction. Cycles of Myo-II assembly and disassembly, or pulses, are associated with apical constriction during Drosophila melanogaster gastrulation. It is not understood whether Myo-II phosphoregulation organizes contractile pulses or whether pulses are important for tissue morphogenesis. Here, we show that Myo-II pulses are associated with pulses of apical Rok. Mutants that mimic Myo-II light chain phosphorylation or depletion of myosin phosphatase inhibit Myo-II contractile pulses, disrupting both actomyosin coalescence into apical foci and cycles of Myo-II assembly/disassembly. Thus, coupling dynamic Myo-II phosphorylation to upstream signals organizes contractile Myo-II pulses in both space and time. Mutants that mimic Myo-II phosphorylation undergo continuous, rather than incremental, apical constriction. These mutants fail to maintain intercellular actomyosin network connections during tissue invagination, suggesting that Myo-II pulses are required for tissue integrity during morphogenesis.National Institute of General Medical Sciences (U.S.) (Transgenic RNAi Project at Harvard Medical School, (R01-GM084947)
Semi-supervised learning for the identification of syn-expressed genes from fused microarray and in situ image data
Background:
Gene expression measurements during the development of the fly Drosophila melanogaster are routinely used to find functional modules of temporally co-expressed genes. Complimentary large data sets of in situ RNA hybridization images for different stages of the fly embryo elucidate the spatial expression patterns.
Results:
Using a semi-supervised approach, constrained clustering with mixture models, we can find clusters of genes exhibiting spatio-temporal similarities in expression, or syn-expression. The temporal gene expression measurements are taken as primary data for which pairwise constraints are computed in an automated fashion from raw in situ images without the need for manual annotation. We investigate the influence of these pairwise constraints in the clustering and discuss the biological relevance of our results.
Conclusion:
Spatial information contributes to a detailed, biological meaningful analysis of temporal gene expression data. Semi-supervised learning provides a flexible, robust and efficient framework for integrating data sources of differing quality and abundance
RhoA GTPase inhibition organizes contraction during epithelial morphogenesis
During morphogenesis, contraction of the actomyosin cytoskeleton within individual cells drives cell shape changes that fold tissues. Coordination of cytoskeletal contractility is mediated by regulating RhoA GTPase activity. Guanine nucleotide exchange factors (GEFs) activate and GTPase-activating proteins (GAPs) inhibit RhoA activity. Most studies of tissue folding, including apical constriction, have focused on how RhoA is activated by GEFs to promote cell contractility, with little investigation as to how GAPs may be important. Here, we identify a critical role for a RhoA GAP, Cumberland GAP (C-GAP), which coordinates with a RhoA GEF, RhoGEF2, to organize spatiotemporal contractility during Drosophila melanogaster apical constriction. C-GAP spatially restricts RhoA pathway activity to a central position in the apical cortex. RhoGEF2 pulses precede myosin, and C-GAP is required for pulsation, suggesting that contractile pulses result from RhoA activity cycling. Finally, C-GAP expression level influences the transition from reversible to irreversible cell shape change, which defines the onset of tissue shape change. Our data demonstrate that RhoA activity cycling and modulating the ratio of RhoGEF2 to C-GAP are required for tissue folding.American Cancer Society (125792-RSG-14-039-01-CSM
Specification of Drosophila Corpora Cardiaca Neuroendocrine Cells from Mesoderm Is Regulated by Notch Signaling
Drosophila neuroendocrine cells comprising the corpora cardiaca (CC) are essential for systemic glucose regulation and represent functional orthologues of vertebrate pancreatic α-cells. Although Drosophila CC cells have been regarded as developmental orthologues of pituitary gland, the genetic regulation of CC development is poorly understood. From a genetic screen, we identified multiple novel regulators of CC development, including Notch signaling factors. Our studies demonstrate that the disruption of Notch signaling can lead to the expansion of CC cells. Live imaging demonstrates localized emergence of extra precursor cells as the basis of CC expansion in Notch mutants. Contrary to a recent report, we unexpectedly found that CC cells originate from head mesoderm. We show that Tinman expression in head mesoderm is regulated by Notch signaling and that the combination of Daughterless and Tinman is sufficient for ectopic CC specification in mesoderm. Understanding the cellular, genetic, signaling, and transcriptional basis of CC cell specification and expansion should accelerate discovery of molecular mechanisms regulating ontogeny of organs that control metabolism
A Polarised Population of Dynamic Microtubules Mediates Homeostatic Length Control in Animal Cells
An analysis of cells grown on micro-patterned lines, and of cells during zebrafish development, identifies a population of microtubules that align along the long axis of cells to mediate homeostatic length control
Gα12/13 regulate epiboly by inhibiting E-cadherin activity and modulating the actin cytoskeleton
Epiboly spreads and thins the blastoderm over the yolk cell during zebrafish
gastrulation, and involves coordinated movements of several cell layers.
Although recent studies have begun to elucidate the processes that underlie
these epibolic movements, the cellular and molecular mechanisms involved remain
to be fully defined. Here, we show that gastrulae with altered
Gα12/13 signaling display delayed epibolic movement of
the deep cells, abnormal movement of dorsal forerunner cells, and dissociation
of cells from the blastoderm, phenocopying e-cadherin mutants.
Biochemical and genetic studies indicate that Gα12/13
regulate epiboly, in part by associating with the cytoplasmic terminus of
E-cadherin, and thereby inhibiting E-cadherin activity and cell adhesion.
Furthermore, we demonstrate that Gα12/13 modulate epibolic
movements of the enveloping layer by regulating actin cytoskeleton organization
through a RhoGEF/Rho-dependent pathway. These results provide the first in vivo
evidence that Gα12/13 regulate epiboly through two distinct
mechanisms: limiting E-cadherin activity and modulating the organization of the
actin cytoskeleton
- …