Your search keyword '"L. Van Lommel"' showing total 4 results

1. Loss of Furin in β-Cells Induces an mTORC1-ATF4 Anabolic Pathway That Leads to β-Cell Dysfunction.

Author

Brouwers B, Coppola I, Vints K, Dislich B, Jouvet N, Van Lommel L, Segers C, Gounko NV, Thorrez L, Schuit F, Lichtenthaler SF, Estall JL, Declercq J, Ramos-Molina B, and Creemers JWM

Subjects

Animals, Diabetes Mellitus, Type 2 metabolism, Furin genetics, Humans, Male, Mice, Mice, Transgenic, Signal Transduction physiology, Activating Transcription Factor 4 metabolism, Furin metabolism, Insulin-Secreting Cells metabolism, Mechanistic Target of Rapamycin Complex 1 metabolism

Abstract

FURIN is a proprotein convertase (PC) responsible for proteolytic activation of a wide array of precursor proteins within the secretory pathway. It maps to the PRC1 locus, a type 2 diabetes susceptibility locus, but its specific role in pancreatic β-cells is largely unknown. The aim of this study was to determine the role of FURIN in glucose homeostasis. We show that FURIN is highly expressed in human islets, whereas PCs that potentially could provide redundancy are expressed at considerably lower levels. β-cell-specific Furin knockout (β Fur KO) mice are glucose intolerant as a result of smaller islets with lower insulin content and abnormal dense-core secretory granule morphology. mRNA expression analysis and differential proteomics on β Fur KO islets revealed activation of activating transcription factor 4 (ATF4), which was mediated by mammalian target of rapamycin C1 (mTORC1). β Fur KO cells show impaired cleavage or shedding of vacuolar-type ATPase (V-ATPase) subunits Ac45 and prorenin receptor, respectively, and impaired lysosomal acidification. Blocking V-ATPase pharmacologically in β-cells increased mTORC1 activity, suggesting involvement of the V-ATPase proton pump in the phenotype. Taken together, these results suggest a model of mTORC1-ATF4 hyperactivation and impaired lysosomal acidification in β-cells lacking Furin , causing β-cell dysfunction., (© 2020 by the American Diabetes Association.)

Published

2021

2. β-cell-specific gene repression: a mechanism to protect against inappropriate or maladjusted insulin secretion?

Author

Schuit F, Van Lommel L, Granvik M, Goyvaerts L, de Faudeur G, Schraenen A, and Lemaire K

Subjects

Anaerobiosis, Animals, Blood Glucose metabolism, Gene Silencing, Glucose metabolism, Glycolysis, Hexokinase genetics, Hexokinase metabolism, Humans, Insulin Secretion, Insulin-Secreting Cells enzymology, Mice, Organ Specificity, Gene Expression Regulation physiology, Insulin metabolism, Insulin-Secreting Cells metabolism

Published

2012

3. Probe-independent and direct quantification of insulin mRNA and growth hormone mRNA in enriched cell preparations.

Author

Van Lommel L, Janssens K, Quintens R, Tsukamoto K, Vander Mierde D, Lemaire K, Denef C, Jonas JC, Martens G, Pipeleers D, and Schuit FC

Subjects

Actins genetics, Animals, Biotechnology methods, Energy Intake, Islets of Langerhans physiology, Kinetics, Proinsulin genetics, RNA, Complementary genetics, Rats, Reverse Transcriptase Polymerase Chain Reaction, Insulin genetics, RNA, Messenger genetics

Abstract

Task division in multicellular organisms ensures that differentiated cell types produce cell-specific proteins that fulfill tasks for the whole organism. In some cases, the encoded mRNA species is so abundant that it represents a sizeable fraction of total mRNA in the cell. In this study, we have used a probe- and primer-free technique to quantify such abundant mRNA species in order to assess regulatory effects of in vitro and in vivo conditions. As a first example, we were able to quantify the regulation of proinsulin mRNA abundance in beta-cells by food intake or by the glucose concentration in tissue culture. The second example of application of this technique is the effect of corticosteroids on growth hormone mRNA in enriched somatrotrophs. It is anticipated that other examples exist in which measurement of very abundant mRNAs in dedicated cells will help to understand biological processes, monitor disease states, or assist biotechnological manufacturing procedures.

Published

2006

4. A glucose sensor role for glucokinase in anterior pituitary cells.

Author

Zelent D, Golson ML, Koeberlein B, Quintens R, van Lommel L, Buettger C, Weik-Collins H, Taub R, Grimsby J, Schuit F, Kaestner KH, and Matschinsky FM

Subjects

Adrenocorticotropic Hormone genetics, Animals, Biosensing Techniques, Female, Gene Expression Regulation, Enzymologic, Growth Hormone genetics, In Situ Hybridization, Kinetics, Liver enzymology, Male, Mice, Mice, Inbred C57BL, Oligonucleotide Array Sequence Analysis, Pro-Opiomelanocortin genetics, RNA, Messenger genetics, Rats, Glucokinase genetics, Pituitary Gland, Anterior enzymology

Abstract

Enzymatic activity of glucokinase was demonstrated, quantitated, and characterized kinetically in rat and mouse pituitary extracts using a highly specific and sensitive spectrometric assay. A previously proposed hypothesis that the glucokinase gene might be expressed in the pituitary corticotrophic cells was therefore reexamined using mRNA in situ hybridization and immunohistochemical techniques. No evidence was found that corticotrophs are glucokinase positive, and the identity of glucokinase-expressing cells remains to be determined. The findings do, however, suggest a novel hypothesis that a critical subgroup of anterior pituitary cells might function as glucose sensor cells and that direct fuel regulation of such cells may modify the classical indirect neuroendocrine pathways that are known to control hormone secretion from anterior pituitary cells.

Published

2006