Pascal Sommer

Bio: Pascal Sommer is an academic researcher from Claude Bernard University Lyon 1. The author has contributed to research in topics: Lysyl oxidase & Elastin. The author has an hindex of 8, co-authored 24 publications receiving 428 citations. Previous affiliations of Pascal Sommer include Centre national de la recherche scientifique.

Genotype-Correlated Expression of Lysyl Oxidase-Like 1 in Ocular Tissues of Patients with Pseudoexfoliation Syndrome/Glaucoma and Normal Patients

Abstract: Pseudoexfoliation (PEX) syndrome is a generalized disease of the extracellular matrix and the most common identifiable cause of open-angle glaucoma. Two single nucleotide polymorphisms in the lysyl oxidase-like 1 (LOXL1) gene (rs1048661 and rs3825942) have been recently identified as strong genetic risk factors for both PEX syndrome and PEX glaucoma. Here we investigated the expression and localization of LOXL1, LOXL2, and lysyl oxidase (LOX) in tissues of PEX syndrome/glaucoma patients and controls in correlation with their individual single nucleotide polymorphism genotypes and stages of disease. LOXL1 ocular expression was reduced by approximately 20% per risk allele of rs1048661, whereas risk alleles of rs3825942, which were highly overrepresented in PEX cases, did not affect LOXL1 expression levels. Irrespective of the individual genotype, LOXL1 expression was significantly increased in early PEX stages but was decreased in advanced stages both with and without glaucoma compared with controls, whereas LOX and LOXL2 showed no differences between groups. LOXL1 was also found to be a major component of fibrillar PEX aggregates in both intra- and extraocular locations and to co-localize with various elastic fiber components. These findings provide evidence for LOXL1 involvement in the initial stages of abnormal fibrogenesis in PEX tissues. Alterations of LOXL1 activation, processing, and/or substrate specificity may contribute to the abnormal aggregation of elastic fiber components into characteristic PEX fibrils.

Use of lysyl oxidase inhibitors for cell culture and tissue engineering

Abstract: The invention concerns the use of lysyl oxidase inhibitors for implementing in vitro cell culture processes capable of being used in tissue or cell engineering, or in experimental pharmacology.

Stimulation de la synthese et de l'activite d'une isoforme de la lysyl oxydase-like loxl pour stimuler la formation de fibres elastiques

Abstract: L'invention concerne la stimulation de la synthese et de l'activite d'une isoforme de la lysyl oxydase, et plus particulierement de l'isoforme LOXL (lysyl oxidase-like).L'invention concerne notamment une methode d'identification d'un principe actif stimulant la formation de fibres elastiques.L'invention a principalement pour but de fournir une telle methode d'identification afin de realiser des compositions permettant de stimuler la formation de fibres elastiques.

Lysyl oxidase: Properties, specificity, and biological roles inside and outside of the cell

Abstract: Lysyl oxidase (LO) plays a critical role in the formation and repair of the extracellular matrix (ECM) by oxidizing lysine residues in elastin and collagen, thereby initiating the formation of covalent crosslinkages which stabilize these fibrous proteins. Its catalytic activity depends upon both its copper cofactor and a unique carbonyl cofactor and has been shown to extend to a variety of basic globular proteins, including histone H1. Although the three-dimensional structure of LO has yet to be determined, the present treatise offers hypotheses based upon its primary sequence, which may underlie the prominent electrostatic component of its unusual substrate specificity as well as the catalysis-suppressing function of the propeptide domain of prolysyl oxidase. Recent studies have demonstrated that LO appears to function within the cell in a manner, which strongly modifies cellular activity. Newly discovered LO-like proteins also likely play unique roles in biology. © 2002 Wiley-Liss, Inc.

Elastic fiber homeostasis requires lysyl oxidase-like 1 protein.

Abstract: Elastic fibers are components of the extracellular matrix and confer resilience1. Once laid down, they are thought to remain stable2, except in the uterine tract where cycles of active remodeling occur3. Loss of elastic fibers underlies connective tissue aging and important diseases including emphysema4,5,6,7. Failure to maintain elastic fibers is explained by a theory of antielastase-elastase imbalance8, but little is known about the role of renewal. Here we show that mice lacking the protein lysyl oxidase–like 1 (LOXL1) do not deposit normal elastic fibers in the uterine tract post partum and develop pelvic organ prolapse, enlarged airspaces of the lung, loose skin and vascular abnormalities with concomitant tropoelastin accumulation. Distinct from the prototypic lysyl oxidase (LOX), LOXL1 localizes specifically to sites of elastogenesis and interacts with fibulin-5. Thus elastin polymer deposition is a crucial aspect of elastic fiber maintenance and is dependent on LOXL1, which serves both as a cross-linking enzyme and an element of the scaffold to ensure spatially defined deposition of elastin.

Inactivation of the Lysyl Oxidase Gene Lox Leads to Aortic Aneurysms, Cardiovascular Dysfunction, and Perinatal Death in Mice

Abstract: Background— The lysyl oxidases are extracellular copper enzymes that initiate the crosslinking of collagens and elastin, 5 human isoenzymes having been characterized so far. The crosslinks formed provide the tensile strength and elastic properties for various extracellular matrices, including vascular walls. We studied the role of the first described isoenzyme Lox by inactivating its gene in mice. Methods and Results— Murine Lox gene was disrupted by routine methods. Lox−/− mice died at the end of gestation or as neonates, necropsy of the live-born pups revealing large aortic aneurysms. In light microscopy, hazy and unruffled elastic lamellae in the Lox−/− aortas were observed, and electron microscopy of the aortic walls of the Lox−/− fetuses showed highly fragmented elastic fibers and discontinuity in the smooth muscle cell layers in Lox−/− fetuses. The wall of the aorta in the Lox−/− fetuses was significantly thicker, and the diameter of the aortic lumen was significantly smaller than that in the Lox+/+...

The rationale for targeting the LOX family in cancer.

Abstract: The therapeutic targeting of extracellular proteins is becoming hugely attractive in light of evidence implicating the tumour microenvironment as pivotal in all aspects of tumour initiation and progression. Members of the lysyl oxidase (LOX) family of proteins are secreted by tumours and are the subject of much effort to understand their roles in cancer. In this Review we discuss the roles of members of this family in the remodelling of the tumour microenvironment and their paradoxical roles in tumorigenesis and metastasis. We also discuss how targeting this family of proteins might lead to a new avenue of cancer therapeutics.

New insights into elastic fiber assembly

Abstract: Elastic fibers provide recoil to tissues that undergo repeated stretch, such as the large arteries and lung. These large extracellular matrix (ECM) structures contain numerous components, and our understanding of elastic fiber assembly is changing as we learn more about the various molecules associated with the assembly process. The main components of elastic fibers are elastin and microfibrils. Elastin makes up the bulk of the mature fiber and is encoded by a single gene. Microfibrils consist mainly of fibrillin, but also contain or associate with proteins such as microfibril associated glycoproteins (MAGPs), fibulins, and EMILIN-1. Microfibrils were thought to facilitate alignment of elastin monomers prior to cross-linking by lysyl oxidase (LOX). We now know that their role, as well as the overall assembly process, is more complex. Elastic fiber formation involves elaborate spatial and temporal regulation of all of the involved proteins and is difficult to recapitulate in adult tissues. This report summarizes the known interactions between elastin and the microfibrillar proteins and their role in elastic fiber assembly based on in vitro studies and evidence from knockout mice. We also propose a model of elastic fiber assembly based on the current data that incorporates interactions between elastin, LOXs, fibulins and the microfibril, as well as the pivotal role played by cells in structuring the final functional fiber.