Martin B.A. ter Beest scite author profile

Novel, double-chained pyridinium compounds have been developed that display highly efficient DNA transfection properties. The transfection efficiency of several of these compounds is enhanced by an order of magnitude, when compared with the transfection efficiency accomplished with the widely used cationic lipid system, lipofectin. Most importantly, the pyridinium compounds were found to be essentially nontoxic toward cells. Using various reporter genes, such as ␤-galactosidase and pNEO (a gene construct that renders cells resistent to antibiotic derivatives of neomycin like G418), we demonstrate that the enhanced efficiency relates to the fact that a relative higher number of cells in the population is transfected (Ϸ50% in the case of COS cells) by the pyridinium derivatives, whereas the delivery of DNA per cell is also enhanced. Furthermore, application of the pyridinium derivatives shows little cellular preference in their ability to transfect cells. By systematically modifying the structure of the pyridinium amphiphile, i.e., by changing either the headgroup structure or the alkyl chains, some insight was obtained that may lead to unraveling the mechanism of amphiphile-mediated transfection, and thus to protocols that further optimize the carrier properties of the amphiphile. Our results reveal that unsaturated alkyl chains enhance the transfection properties of the pyridinium-based amphiphiles. Preliminary experiments suggest that the structure-dependent improvement of transfection efficiency, when comparing pyridinium derivatives with lipofectin, likely relates to the mechanism of delivery rather than the packaging of the amphiphile͞DNA complex.

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Pak1 and PIX regulate contact inhibition during epithelial wound healing

Zegers

Forget

Chernoff

et al. 2003

The EMBO Journal

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Wound healing in epithelia requires coordinated cell migration and proliferation regulated by signaling mechanisms that are poorly understood. Here we show that epithelial cells expressing constitutively active or kinase-dead mutants of the Rac/Cdc42 effector Pak1 fail to undergo growth arrest upon wound closure. Strikingly, this phenotype is only observed when the Pak1 kinase mutants are expressed in cells possessing a free lateral surface, i.e. one that is not engaged in contact with neighboring cells. The Pak1 kinase mutants perturb contact inhibition by a mechanism that depends on the Pak-interacting Rac-GEF PIX. In control cells, endogenous activated Pak and PIX translocate from focal complexes to cell-cell contacts during wound closure. This process is abrogated in cells expressing Pak1 kinase mutants. In contrast, Pak1 mutants rendered defective in PIX binding do not impede translocation of activated Pak and PIX, and exhibit normal wound healing. Thus, recruitment of activated Pak and PIX to cell-cell contacts is pivotal to transduction of growth-inhibitory signals from neighboring cells in epithelial wound healing.

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The Role of Syntaxins in the Specificity of Vesicle Targeting in Polarized Epithelial Cells

Beest

Chapin

Avrahami

et al. 2005

MBoC

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In polarized epithelial cells syntaxin 3 is at the apical plasma membrane and is involved in delivery of proteins from the trans-Golgi network to the apical surface. The highly related syntaxin 4 is at the basolateral surface. The complementary distribution of these syntaxins suggests that they play a role in the specificity of membrane traffic to the two surfaces. We constructed a chimeric syntaxin where we removed the N-terminal 29 residues of syntaxin 3 and replaced it with the corresponding portion of syntaxin 4. When expressed in polarized epithelial cells, this chimera was exclusively localized to the basolateral surface. This indicates that the N-terminal domain of syntaxin 3 contains information for its polarized localization. In contrast to the apical localization of syntaxin 3, the basolateral localization of syntaxin 4 was not dependent on its N-terminal domain. Syntaxin 3 normally binds to Munc18b, but not to the related Munc18c. Overexpression of the chimera together with overexpression of Munc18b caused membrane and secretory proteins that are normally sent primarily to the apical surface to exhibit increased delivery to the basolateral surface. We suggest that syntaxins may play a role in determining the specificity of membrane targeting by permitting fusion with only certain target membranes. INTRODUCTIONEukaryotic cells contain numerous intracellular membranous compartments that are connected by vesicular traffic. After vesicles bud off from a membrane, they must be targeted to and fuse with the correct target membrane. How vesicles are specifically targeted to the correct membrane and avoid fusion with the incorrect membrane remains a paramount question (Mostov et al., 2003;Nelson, 2003;Rodriguez-Boulan et al., 2005). Several classes of molecules may contribute to this specificity and it is possible that specificity is conferred by multiple layers of molecular machinery, which may act sequentially. For instance, at least in larger animal cells, vesicles may first reach the vicinity of their target membrane by using motor proteins and cytoskeletal filaments. Thus, some of the specificity may be achieved by binding and activation of the correct motor protein to the vesicle. In many trafficking steps, vesicles are then brought closer to the membrane by tethering complexes. For instance, the yeast exocyst and its homologous mammalian sec6/8 complex tether vesicles to the specific locations on the plasma membrane (Lipschutz and Mostov, 2002;Novick and Guo, 2002).SNARE proteins act later and may catalyze fusion itself (Sollner, 2003;Ungar and Hughson, 2003;Jahn, 2004). The original formulation of the SNARE hypothesis postulated that specific v-SNARES on the vesicle paired with cognate t-SNAREs on the target, thereby providing specificity to fusion (Sollner et al., 1993). This premise was challenged when SNARE proteins, lacking their membrane anchors, were produced. Soluble versions of v-and t-SNARES paired almost completely promiscuously, suggesting that pairing of specific SNAREs did not contribute ...

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A Bipartite Signal Regulates the Faithful Delivery of Apical Domain Marker Podocalyxin/Gp135

Chen

Lin

et al. 2007

MBoC

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Podocalyxin/Gp135 was recently demonstrated to participate in the formation of a preapical complex to set up initial polarity in MDCK cells, a function presumably depending on the apical targeting of Gp135. We show that correct apical sorting of Gp135 depends on a bipartite signal composed of an extracellular O-glycosylation-rich region and the intracellular PDZ domain-binding motif. The function of this PDZ-binding motif could be substituted with a fusion construct of Gp135 with Ezrin-binding phosphoprotein 50 (EBP50). In accordance with this observation, EBP50 binds to newly synthesized Gp135 at the Golgi apparatus and facilitates oligomerization and sorting of Gp135 into a clustering complex. A defective connection between Gp135 and EBP50 or EBP50 knockdown results in a delayed exit from the detergent-resistant microdomain, failure of oligomerization, and basolateral missorting of Gp135. Furthermore, the basolaterally missorted EBP50-binding defective mutant of Gp135 was rapidly retrieved via a PKC-dependent mechanism. According to these findings, we propose a model by which a highly negative charged transmembrane protein could be packed into an apical sorting platform with the aid of its cytoplasmic partner EBP50.

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Distinct roles of cadherin-6 and E-cadherin in tubulogenesis and lumen formation

Jia

Liu

Hansen

et al. 2011

MBoC

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