Markus Dürrenberger scite author profile

Cell-penetrating peptides (CPPs) are cationic peptides which, when linked to genes, proteins, or nanoparticles, facilitate the transport of these entities across the cell membrane. Despite their potential use for gene transfer and drug delivery, the mode of action of CPPs is still mysterious. It has even been argued that the observed transport across the cell membrane is an artifact caused by chemical fixation of the cells, a common preparation method for microscopic observation. Here we have synthesized a fluorescent derivative of the HIV-1 TAT protein transduction domain [Fg-CPP(TAT(PTD))] and have observed its uptake into nonfixated living fibroblasts with time-lapse confocal microscopy, eliminating the need for fixation. We observe that Fg-CPP(TAT(PTD)) enters the cytoplasm and nucleus of nonfixated fibroblasts within seconds, arguing against the suggested artifact of cell fixation. Using differential interference contrast microscopy, dense aggregates are detected on the cell surface. Several observations suggest that these aggregates consist of Fg-CPP(TAT(PTD)) bound to membrane-associated heparan sulfate (HS). The aggregates grow in parallel with Fg-CPP(TAT(PTD)) uptake and are detected only on fibroblasts showing Fg-CPP(TAT(PTD)) uptake. These observations resemble earlier reports of "capping" of cell surface molecules combined with a polarized endocytotic flow. Enzymatic removal of extracellular HS reduced the rate of both Fg-CPP(TAT(PTD)) uptake and aggregate formation, demonstrating that HS is involved in the uptake mechanism. The functionality of the fibroblasts during the CPP uptake was investigated with a cytosensor microphysiometer measuring the extracellular acidification rate (ECAR). Short exposures (2.5 min) to the CPP reduced the ECAR which was, however, reversible upon reperfusion with buffer only. In contrast, no recovery to baseline values was observed after repeated exposures to the CPP, suggesting that the CPP is toxic in long-term applications.

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A Combined Ex Vivo and In Vivo RNAi Screen for Notch Regulators in Drosophila Reveals an Extensive Notch Interaction Network

Saj

et al. 2010

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Notch signaling plays a fundamental role in cellular differentiation and has been linked to human diseases, including cancer. We report the use of comprehensive RNAi analyses to dissect Notch regulation and its connections to cellular pathways. A cell-based RNAi screen identified 900 candidate Notch regulators on a genome-wide scale. The subsequent use of a library of transgenic Drosophila expressing RNAi constructs enabled large-scale in vivo validation and confirmed 333 of 501 tested genes as Notch regulators. Mapping the phenotypic attributes of our data on an interaction network identified another 68 relevant genes and revealed several modules of unexpected Notch regulatory activity. In particular, we note an intriguing relationship to pyruvate metabolism, which may be relevant to cancer. Our study reveals a hitherto unappreciated diversity of tissue-specific modulators impinging on Notch and opens new avenues for studying Notch regulation and function in development and disease.

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Lethal overproduction of the Escherichia coli nucleoid protein H-NS: ultramicroscopic and molecular autopsy

et al. 1992

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The Escherichia coli hns gene, which encodes the nucleoid protein H-NS, was deprived of its natural promoter and placed under the control of the inducible lambda PL promoter. An hns mutant yielding a protein (H-NS delta 12) with a deletion of four amino acids (Gly112-Arg-Thr-Pro115) was also obtained. Overproduction of wild-type (wt) H-NS, but not of H-NS delta 12, resulted in a drastic loss of cell viability. The molecular events and the morphological alterations eventually leading to cell death were investigated. A strong and nearly immediate inhibition of both RNA and protein synthesis were among the main effects of overproduction of wt H-NS, while synthesis of DNA and cell wall material was inhibited to a lesser extent and at a later time. Upon cryofixation of the cells, part of the overproduced protein was found in inclusion bodies, while the rest was localized by immunoelectron microscopy to the nucleoids. The nucleoids appeared condensed in cells expressing both forms of H-NS, but the morphological alterations were particularly dramatic in those overproducing wt H-NS; their nucleoids appeared very dense, compact and almost perfectly spherical. These results provide direct evidence for involvement of H-NS in control of the organization and compaction of the bacterial nucleoid in vivo and suggest that it may function, either directly or indirectly, as transcriptional repressor and translational inhibitor.

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The efficiency of immunolabel on Lowicryl sections compared to theoretical predictions.

Kellenberger¹,

Dürrenberger²,

Villiger³

et al. 1987

J Histochem Cytochem.

189

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The surface of thin sections of aldehyde-fixed biological material shows a specimen-related relief of 2-6 nm with Lowicryl. Epon sections are about three times smoother. The relief is the consequence of thin-sectioning being in reality a cleavage. Epitopes are supposed to be laid open (or set free) because cleavage follows the interfaces between protein and Lowicryl. We have developed a simple theory on this basis and have theoretically estimated the efficiency of on-section labeling and compared it with experimental data. For randomly dispersed proteins in cytoplasm, Lowicryl sections will yield significant label only when the concentration of the antigen is about 10 microM or more. The complex situation of more compact proteins, as represented by fibers, sheets, and biological membranes is discussed and the difficulty of significant calculations is explained. Pre-embedding labeling and melted cryosections should give 10-30 times more label. The possible reasons for the observed much smaller gain of not more than two to three times are discussed.

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Export of Plasmodium falciparum calcium‐dependent protein kinase 1 to the parasitophorous vacuole is dependent on three N‐terminal membrane anchor motifs

Möskes

Burghaus

Wernli

et al. 2004

Molecular Microbiology

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SummaryCalcium-dependent protein kinases play a pivotal role in calcium signalling in plants and some protozoa, including the malaria parasites. They are found in various subcellular locations, suggesting an involvement in multiple signal transduction pathways. Recently, Plasmodium falciparum calcium-dependent protein kinase 1 (PfCDPK1) has been found in the membrane and organelle fraction of the parasite. The kinase contains three motifs for membrane binding at its Nterminus, a consensus sequence for myristoylation, a putative palmitoylation site and a basic motif. Endogenous PfCDPK1 and the in vitro translated kinase were both shown to be myristoylated. The supposed membrane attachment function of the basic cluster was experimentally verified and shown to participate together with N -myristoylation in membrane anchoring of the kinase. Using immunogold electron microscopy, the protein was detected in the parasitophorous vacuole and the tubovesicular system of the parasite. Mutagenesis of the predicted acylated residues and the basic motif confirmed that dual acylation and the basic cluster are required for correct targeting of Aequorea victoria green fluorescent protein to the parasitophorous vacuole, suggesting that PfCDPK1 as the leishmanial hydrophilic acylated surface protein B is a representative of a novel class of proteins whose export is dependent on a 'non-classical' pathway involving N -myristoylation/palmitoylation.

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