Einfluss der Lysyloxidase-katalysierten Matrix-Quervernetzung auf Tumorwachstum, -metabolismus und -malignität / Effects of LOX(L)-catalyzed extracellular matrix crosslinking on tumor growth, metabolism and malignity

Rossow, Leonie

January 2019

Die EZM bildet ein Netzwerk quervernetzter Proteine, welches alle Zellen im Tumor umgibt. Sie übt direkte Effekte auf die Medikamenteneinbringung und -verteilung aus und somit auch auf die therapeutische Effizienz von Chemotherapeutika. Die LOX(L)-Proteinfamilie katalysiert die oxidative Desaminierung von Lysinresten in Elastin und Kollagenfasern und ermöglicht dadurch eine intra- und intermolekulare Quervernetzung. Diese wird für die Reifung und Stabilisierung der Kollagene in der EZM benötigt. Eine erhöhte LOX(L)-Expression steigert durch eine verstärkte EZM-Quervernetzung die Gewebesteifheit im Tumor und bildet so eine physikalische Diffusionsbarriere. Durch diese Barriere wird die Versorgung mit Sauerstoff und Nährstoffen reduziert. Die resultierende Hypoxie im Tumor kann eine fehlgeleitete Angiogenese triggern und zu einer Aktivierung maligner Signalkaskaden führen. In dieser Arbeit wurden durch eine LOX(L)-Inhibierung mittels βAPN einerseits und eine ektopische LOX-/LOXL2-Überexpression andererseits Auswirkungen solcher Eingriffe auf verschiedene Indikatoren wie Zellproliferation und apoptose, Versorgung mit Sauerstoff und Nährstoffen, Angiogenese, Hypoxie, Makrophageninfiltration und die Expression verschiedener Wachstumsfaktoren analysiert. Die Versuche wurden an fünf verschiedenen Tumoren (4T1-, E0771- und EMT6-Brustkarzinome, LLC-Lungenkarzinome und MT6-Fibrosarkome) durchgeführt. Die Ergebnisse dieser Arbeit demonstrieren eine direkte Verbindung zwischen der EZM und einer Therapieresistenz. Nach βAPN-Behandlung konnte eine verbesserte Versorgung mit Sauerstoff und Nährstoffen beobachtet werden, welches in einer Verringerung maligner Signalkaskaden und folglich auch in einer verbesserten Vaskularisierung resultierte. Als Konsequenz wurde die therapeutische Effizienz von Chemotherapeutika verbessert. Im Gegensatz dazu führte eine LOX-/LOXL2-Überexpression zu einer erhöhten Therapieresistenz. Die vorliegende Studie zeigt, dass die Modifizierung der EZM durch eine Hemmung von LOX(L) das Potenzial birgt, das Ansprechen von Chemotherapeutika in der Behandlung von Krebserkrankungen zu verbessern. / The extracellular matrix (ECM) forms a network of cross-linked proteins, which surrounds all cells in the tumor. The ECM has direct effects on the accumulation and distribution of drugs and therefore also on the therapeutic efficacy of chemotherapeutics. The LOX protein family catalyzes the oxidative deamination of lysin-residues in elastins and collagen fibers and as a consequence allows an intra- and intermolecular crosslinking. This is necessary for the maturation and stabilization of the collagens in the ECM. An elevated LOX(L)-expression increases the stiffness through a higher cross-linked ECM and thus builds a physical diffusion barrier. Because of this barrier the oxygen and nutritional supply is limited. The resulting hypoxia in the tumor could promote errant angiogenesis and lead to an activation of malign signal cascades. In this dissertation, effects on different influences were examined on the one hand through a LOX(L)-inhibition with βAPN and on the other hand through an ectopic LOX /LOXL2-overexpression. These influences were cell proliferation and -apoptosis, supply with oxygen and nutrients, angiogenesis, hypoxia, infiltration of macrophages and the expression of various growth factors. The experiments were performed on five different tumor models (4T1, E0771, EMT6 breast carcinomas, LLC lung carcinomas and MT6 fibrosarcomas). The results of this work demonstrate a direct link between the ECM and a therapeutic resistance of tumors. After βAPN-treatment a better supply with oxygen and nutrients could be determined, which ended up in a reduction of malign signal cascades and thus in a better vascularization. As a consequence the therapeutic efficacy of chemotherapeutics was improved. In contrast, LOX /LOXL2-overexpression lead to a higher therapeutic resistance. This dissertation shows that modification of the ECM through LOX(L)-inhibition has the potential to improve response of chemotherapeutics in the treatment of cancer.

Lysyl-Oxidase

Tumor

ddc:610

The LOX and LOXL2 amine oxidases in colon and esophageal cancer

Fong, Sheri F. T.

January 2003

Thesis (Ph. D.)--University of Hawaii at Manoa, 2003. / Includes bibliographical references (leaves 184-233).

Lysyl oxidase. Colon (Anatomy) Esophagus

Discovery of protein-protein interactions of the lysyl oxidase enzyme : implications for cardiovascular disease, cancer and fibrosis

Fogelgren, Benjamin C

January 2005

Thesis (Ph. D.)--University of Hawaii at Manoa, 2005. / Includes bibliographical references (leaves 162-188). / Also available by subscription via World Wide Web / xvi, 188 leaves, bound ill. (some col.) 29 cm

Lysyl oxidase

Protein-protein interactions

Fibronectins

Discovery of protein-protein interactions of the lysyl oxidase enzyme implications for cardiovascular disease, cancer and fibrosis /

Fogelgren, Benjamin C.

January 2005

Thesis (Ph. D.)--University of Hawaii at Manoa, 2005. / Includes bibliographical references (leaves 162-188).

Lysyl oxidase like-2 mediates tumor to stromal cell communication in oral cancer

Mahjour, Faranak

24 October 2018

INTRODUCTION: The lysyl oxidase family consists of 5 members and oxidizes specific lysine residues in biosynthetic collagen and elastin maturation. Lysyl oxidase like-2 (LOXL2) is elevated in oral cancer and promotes metastasis and correlates with poor prognosis. The objective of this study was to determine the mechanism by which LOXL2 promotes the progression and invasiveness of oral squamous cell carcinoma. METHODS: In vitro: The effects of LOXL2 inhibitor (PXS-S1C) on human gingival fibroblasts treated with tumor cell conditioned medium (CM) were investigated. Cell proliferation assays, signaling arrays, gene knock down and western blots were used to evaluate the effect of PXS-S1C on CM-treated fibroblasts. The effects of PXS-S1C on cancer cell expression of LOXL2 and proliferation were determined. To find potential LOXL2 substrates, carbonyl-containing proteins of gingival fibroblasts treated with CM +/- PXS-S1C were affinity-labeled and then purified by affinity chromatography and identified by western blot. In vivo: The effects of PXS-S1C on cancer cell growth and metastasis in vivo were investigated using orthotopic oral tongue cancer mouse models in both immunodeficient and immunocompetent mice. PXS-S1C at 10 mg/kg and 30 mg/kg was injected immediately following tumor cell injections. Tumor growth was monitored by both caliper measurement and in vivo imaging (IVIS). The mice were sacrificed and their organs were subjected to immunohistochemical staining with proliferation markers. RESULTS: PXS-S1C significantly inhibited gingival fibroblast proliferation stimulated by tumor cell CM and attenuated phosphorylation of PDGFRβ at the Y771 and Y857, but not Y751 residues in response to CM treatment. PXS-S1C inhibited ERK1/2-signaling in fibroblasts but not AKT pathway in response to CM treatment. PDGFR activation by oral tumor cells was mimicked by PDGF-AB but not PDGF-BB. PXS-S1C decreased the expression of LOXL2 in HSC3 oral cancer cells in vitro, suggesting the existence of a positive autoregulatory loop. Assessing for direct LOXL2 substrates in fibroblasts with functional consequences identified PDGFR. In vivo studies: Caliper measurements, IVIS, and immunohistochemistry demonstrated that inhibition of LOXL2 by injections of PXS-S1C significantly decreased both progression and metastasis of oral cancers in vivo in both mouse models. Mice without PXS-S1C treatment developed larger tongue volumes (p<0.05), and in immunocompetent mice larger lymph nodes (9 out 12) were observed compared to the PXS-S1C-treated mice (4 out of 12). IVIS imaging of immunodeficient mice revealed inhibition of metastasis by PXS-S1C treatment. The expression of proliferation marker (Ki-67 or PCNA) and LOXL2 was lower in tongue tumors treated with PXS-S1C in both in vivo models (p<0.05). CONCLUSIONS: LOXL2 secreted by cancer cells stimulates fibroblast proliferation by oxidizing PDGFR and thereby enhancing PDGF-mediated signaling. Inhibition of LOXL2 can be used as a therapeutic strategy to suppress the growth and metastasis of oral cancers by modulating tumor microenvironment. / 2019-10-24T00:00:00Z

Molecular biology

Lysyl oxidase

Oral cancer

Adenovirus endocytosis and adenoviral gene transfer in cardiovascular and dermatologic disease models

Rauma-Pinola, T. (Tanja)

10 September 2004

Abstract Adenoviral gene transfer is a valuable tool in molecular biology research. In order to be an efficient and safe vector, adenovirus structure and infection mechanism as well as molecular biology of the used transgene need to be well studied. The aim of this study was to evaluate the role of adenovirus as a gene transfer vector from several perspectives. Adenovirus uses receptor-mediated endocytosis in order to enter the target cell. The effect of Rab5 GTPase on adenovirus entry and gene transfer efficiency was examined first. Next, adenovirus was used as an investigatory tool in the cardiovascular research, focused on clarifying the role of adrenomedullin (AM) in heart and vascular remodeling. Finally, a model of adenoviral gene transfer into skin fibroblasts was used. The role of Rab5 GTPase in the adenovirus endocytosis was examined in HeLa cells using Cy3-labeled adenovirus, and gene transfer efficiency using β-galactosidase encoding adenovirus. Rab5 increased both adenovirus uptake and gene transfer, whereas dominant negative Rab5S34N decreased both endocytosis and gene transfer. The data indicate that Rab5 is needed in mediating the adenovirus uptake into the target cell. In the rat heart, adenovirus-mediated AM gene transfer transiently improved systolic function both in vivo and in vitro. AM caused activation of translocation of protein kinases C ε and δ, whereas phosphorylation of p38 mitogen activated protein kinase was decreased in the left ventricle. AM significantly attenuated the development of angiotensin II-induced cardiac hypertrophy. In rats with myocardial infarction, AM enhanced dilatation of left ventricle and thinning of anterior wall. The role of AM in neointima formation was evaluated in rat artery after endothelial injury. Intravascular AM gene transfer decreased neointimal growth and increased neointimal myofibroblasts apoptosis. These results show that AM regulates left ventricular systolic function and remodeling in the heart, and plays a role in pathological vascular remodeling. Adenovirus-mediated lysyl hydroxylase (LH) gene transfer into skin fibroblasts of type VI Ehlers-Danlos syndrome patient and rat skin increased functional LH production, elevated LH activity, and human LH mRNA production both in vitro and in vivo. LH gene replacement therapy may thus lead to possibilities to improve skin wound healing in Ehlers-Danlos syndrome patients.

Rab5

adrenomedullin

gene transfer

lysyl hydroxylase

adenovirus

Mutations in the gene of lysyl hydroxylase of patients with Ehlers-Danlos syndrome type VI

Pousi, B. (Birgitta)

24 June 1999

Abstract Lysyl hydroxylase (EC 1.14.11.4, procollagen-lysine 2-oxoglutarate 5-dioxygenase, PLOD) catalyses the formation of hydroxylysine in collagens and in the other collagen like proteins. Hydroxylysine participates in the formation of cross-links between collagen molecules and can bind to the carbohydrates, galactose and glucosylgalactose. Patients with the type VIA Ehlers-Danlos syndrome (EDS) have characteristically a deficiency in hydroxylysine of collagen in their skin that is caused by reduced activity of lysyl hydroxylase 1. In this work the mutations were studied in detail in four different Ehlers-Danlos VIA patients. The first patient characterized in this study had a duplication of seven exons in the lysyl hydroxylase gene 1. The mutation was caused by homologous recombination of two identical 44-nucleotide regions of Alu sequences in introns 9 and 16 in the gene. This study also suggests that uniparental isodisomy does not explain the homozygosity of the mutation. The second patient was found to have two mutations in the gene for lysyl hydroxylase 1 in a compound heterozygote state. The study resulted in the discovery of the first deletion mutation in the gene. The deletion was caused by an Alu-Alu recombination that removes about 3 kb from the gene including all the exon 17 sequences. The other mutation causes deletion of exon 16 from the mRNA. Deletion of the penultimate nucleotide of intron 15 destroys the consensus sequence of the intron/exon boundary and thus causes the deletion. The third patient was described to have a nonsense codon in exon 14 of one allele which causes a reduction in the amount of lysyl hydroxylase mRNA and leads to aberrant RNA splicing in the cell. The other allele was concluded to be operationally null. In the last work two novel null mutations were found in the gene for lysyl hydroxylase 1. The first was a one nucleotide deletion in the acceptor splice site of intron 4 and the other an insertion of a C nucleotide in exon 2. The abnormal alleles lead to markedly decreased lysyl hydroxylase mRNA levels. This work revealed many exon deleted splicing variants of lysyl hydroxylase mRNA which were first discovered in affected cells, but traces of similarly spliced mRNA species were also found in the cytoplasm of normal human skin fibroblasts. These data indicate that the splicing machinery of the cell is leaky. In this thesis, several types of stuctural mutations in the DNA were found to be responsible for lysyl hydroxylase deficiency in patients with type VIA variant of EDS. The different mechanisms causing these mutations were also studied in detail.

Alu-Alu recombination

Lysyl hydroxylase

genetic disorder

Domain by domain analysis of the RNA binding properties of LysRS

Robinson, Christian L.

06 December 2010

No description available.

Biochemistry

LysRS

lysyl

tRNA

synthetase

RNA

Biochemical properties of class I LYSYL-tRNA synthetase

Levengood, Jeffrey D.

05 January 2007

No description available.

tRNA

aminoacyl-tRNA synthetase

lysyl-tRNA synthetase

Lisil oxidase e propriedades pró-tumorigênicas de pericitos / Lysyl oxidase and pro-tumorigenic properties of pericytes

Ribeiro, Aline Lopes

26 February 2016

O microambiente tumoral é composto por células, como fibroblastos, células do sistema imune, células endoteliais e pericitos, envoltas por uma matriz extracelular, além de possuir fatores solúveis que participam da comunicação celular. Nas últimas décadas, têm-se entendido cada vez melhor seu papel na iniciação e progressão dos tumores. É de fundamental importância, portanto, entender a biologia dos seus componentes e como podem agir em favor do desenvolvimento tumoral. Diversos trabalhos demonstram que há uma associação entre a presença dos pericitos nos vasos tumorais com a agressividade e prognóstico de alguns tipos de câncer. Uma vez ativadas, além do papel estrutural, essas células modulam as atividades das células endoteliais durante a formação de novos vasos, além de adquirirem propriedades como proliferação e migração. Neste contexto, os pericitos passam a secretar fatores importantes na comunicação célula-a-célula e liberam enzimas moduladoras na matriz extracelular. A lisil oxidase (LOX) é uma das principais enzimas que atuam sobre a matriz extracelular. Já está bem descrito que, quando superexpressa em células tumorais, a LOX pode alterar a migração e invasão dessas células, promovendo a geração de metástases. Entretanto, pouco se sabe a respeito da atuação dessa enzima sobre os demais componentes celulares do estroma tumoral, como os pericitos. Sendo assim, o presente trabalho teve como objetivo principal verificar se enzima LOX é relevante para a ativação de propriedades dos pericitos que possam contribuir para suas funções pró-tumorigênicas, como migração, proliferação e formação de vasos. Os resultados foram gerados avaliando essas atividades dos pericitos após pré-tratamento de 24 horas com &beta;-aminopropionitrile (&beta;APN), um inibidor irreversível da LOX. Foram utilizadas duas linhagens de pericitos derivados de tecido normal (adiposo e muscular) e duas linhagens de pericitos provenientes de tecido tumores do sistema nervoso central (neuroblastoma e ependimoma). Este composto foi capaz de diminuir a capacidade de migração das células de todas as linhagens testadas e, de maneira geral, tornou o processo de formação de estruturas tubulares in vitro menos eficiente. Entretanto, não foram observadas alterações na proliferação celular. Os dados indicam, portanto, que a enzima LOX pode ser importante para a ativação dos pericitos e, possivelmente, influenciem no seu comportamento no microambiente tumoral / The tumor microenvironment is composed of non-cancer cells, such as fibroblasts, immune cells, endothelial cells and pericytes, surrounded by an extracellular matrix, in addition to soluble factors involved in cellular crosstalk. In the last decades, it has been better understood its role in the initiation and progression of tumors. It is critical, therefore, to understand the biology of its components and how they can act in favor of tumor development. Several studies show an association between the presence of pericytes in tumor vessels with aggressiveness and prognosis of some cancers. Once activated, these cells modulate the activities of endothelial cells during the new vessels formation, and acquire properties as proliferation and migration. In this context, pericytes triggers the secretion of important factors in cell-to-cell communication and release modulating enzymes of extracellular matrix. The lysyl oxidase (LOX) is one of the main enzymes that act on the extracelular matrix. It is well described that when overexpressed in tumor cells, LOX can alter the migration and invasion of these cells, promoting the generation of metastases. However, little is known about the role of this enzyme over other cellular components of the tumor stroma, such as pericytes. Therefore, the aim of this study was to verify whether LOX enzyme is relevant to the activation of properties of the pericytes that could contribute to its pro-tumorigenic functions such as migration, proliferation and vessel formation. All the results were generated by evaluation of the activities of these pericytes after 24 hours pretreatment with &beta;-aminopropionitrile (&beta;APN), an irreversible inhibitor of LOX. This study used two cell lines of pericytes derived from normal tissue (fat and muscle) and two isolated from tissue of the central nervous system. The &beta;APN was able to reduce the migration of cells of all tested cell lines and, in general, alter the tubular formation in vitro. However, changes in cell proliferation weren&prime;t observed. The data showed, that the LOX family may be important for the activation of pericytes and possibly influence on their behavior in the tumor microenvironment

Lisil oxidase

Lysyl oxidase

Microambiente tumoral

Pericitos

Pericytes

Tumor microenvironment