Cecilia Sahlgren scite author profile

Cancer is a global public health concern. Alterations in epigenetic processes are among the earliest genomic aberrations occurring during cancer development and are closely related to progression. Unlike genetic mutations, aberrations in epigenetic processes are reversible, which opens the possibility for novel pharmacological treatments. Non-coding RNAs (ncRNAs) represent an essential epigenetic mechanism, and emerging evidence links ncRNAs to carcinogenesis. Epigenetic drugs (epidrugs) are a group of promising target therapies for cancer treatment acting as coadjuvants to reverse drug resistance in cancer. The present review describes central epigenetic aberrations during malignant transformation and explains how epidrugs target DNA methylation, histone modifications and ncRNAs. Furthermore, clinical trials focused on evaluating the effect of these epidrugs alone or in combination with other anticancer therapies and other ncRNA-based therapies are discussed. The use of epidrugs promises to be an effective tool for reversing drug resistance in some patients with cancer. Contents1. Introduction 2. Epigenetic mechanisms in cancer, roles in carcinogenesis and therapeutic approaches 3. ncRNAs in epigenetic control 4. Conclusions

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The nervous system of Tricladida. I. Neuroanatomy ofProcerodes littoralis (Maricola, Procerodidae): An immunocytochemical study

Reuter

Gustafsson

Sahlgren

et al. 1995

Invertebrate Neuroscience

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The organization of the nervous system of Procerodes littoralis (Tricladida, Maricola, Procerodidae) was studied by immunocytochemistry, using antibodies to authentic flatworm neuropeptide F (NPF) (Moniezia expansa). Compared to earlier investigations of the neuroanatomy of tricladid flatworms, the pattern of NPF immunoreactivity in Procerodes littoralis reveals differences in the following respects: 1. Shape and structure of the brain. 2. Number and composition of longitudinal nerve cords. 3. Shape of branches of, and transverse connections between, main ventral nerve cords. 4. Composition of the pharyngeal nervous system. The rich innervation by NPF immunoreactive (IR) fibres and cells of the subepithelial muscle layer, the pharynx musculature and the musculature of the male copulatory apparatus indicates a neurotransmitter or neuromodulatory influence on muscular activity.

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iGIST - a kinetic bioassay for pertussis toxin based on its effect on inhibitory GPCR signaling

Paramonov

Sahlgren

Rivero-Müller

et al. 2020

Preprint

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Detection of pertussis toxin (PTX) activity is instrumental for the development and manufacturing of pertussis vaccines. These quality and safety measures require annually thousands of mice. Here, we describe iGIST (Interference in Gαi-mediated Signal Transduction) - an animal-free kinetic bioassay for detection of PTX by measuring its effect on inhibitory G protein-coupled receptor (GPCR) signaling. PTX ADP-ribosylates inhibitory α-subunits of the heterotrimeric G proteins, thereby perturbing the inhibitory GPCR signaling. iGIST is based on HEK293 cells co-expressing a somatostatin receptor 2 (SSTR2), which is an inhibitory GPCR controllable by a high affinity agonist octreotide, and a luminescent 3′5′-cyclic adenosine monophosphate (cAMP) probe. iGIST has a low sensitivity threshold in picogram/ml range of PTX, surpassing by 100-fold in a parallel analysis the currently used in vitro end-point technique to detect PTX, the cluster formation assay (CFA) in Chinese hamster ovary cells. iGIST also detects PTX in complex samples, i.e. a commercial PTX-toxoid containing pertussis vaccine that was spiked with an active PTX. iGIST has an objective digital readout and is observer-independent, offering prospects for automation. iGIST emerges as a promising animal-free alternative to detect PTX activity in the development and manufacturing of pertussis vaccines. iGIST is also expected to facilitate basic PTX research, including identification and characterization of novel compounds interfering with PTX.

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