Leukocyte trafficking: a special focus on VAP-1 and CLEVER-1

It is crucial that lymphocytes patrol the body against foreign intruders and that leukocytes invade inflamed tissues to ameliorate the infection or injury. The adhesion molecules in leukocytes and endothelial cells play an essential role in the immune response by directing the traffic of leukocytes. However, the same molecules that guide leukocyte traffic under physiological conditions are also involved in pathological situations, when an overly excessive or harmful inflammatory response leads to tissue destruction and organ dysfunction or tumor growth. Vascular adhesion protein-1 (VAP-1) and Common lymphatic endothelial and vascular endothelial receptor-1 (CLEVER-1) are endothelial molecules that participate in the adhesion of leukocytes to the endothelia. This study was designed to elucidate, using different inflammation models, the role of VAP-1 and CLEVER-1 in leukocyte migration to the inflamed tissue, and to evaluate the use of antibodies against these molecules as an anti-adhesive therapy. Also, the role of CLEVER-1 during tumorigenesis was studied. Blocking the function of VAP-1 with antibodies significantly decreased the accumulation of leukocytes in the inflamed tissue. Targeting CLEVER-1 prevented cell migration via lymphatic vessels, as well as leukocyte traffic during inflammation. Following the anti-CLEVER-1 antibody treatment the number of immune regulating leukocytes in tumors was reduced, which led to a decrease in tumor growth. However, the normal immune response towards immunization or bacterial infection was not compromised. Thus, VAP-1 and CLEVER-1 are both potential targets for antiinflammatory therapies for preventing the harmful accumulation of leukocytes in inflamed areas. Targeting CLEVER-1 may also inhibit tumor growth by reducing immunosuppressive leukocytes in tumors

The Structure and Function of αI Domains in Collagen Receptor and Leukocyte Integrins

Integrins are heterodimeric, signaling transmembrane adhesion receptors that connect the intracellular actin microfilaments to the extracellular matrix composed of collagens and other matrix molecules. Bidirectional signaling is mediated via drastic conformational changes in integrins. These changes also occur in the integrin αI domains, which are responsible for ligand binding by collagen receptor and leukocyte specific integrins. Like intact integrins, soluble αI domains exist in the closed, low affinity form and in the open, high affinity form, and so it is possible to use isolated αI domains to study the factors and mechanisms involved in integrin activation/deactivation. Integrins are found in all mammalian tissues and cells, where they play crucial roles in growth, migration, defense mechanisms and apoptosis. Integrins are involved in many human diseases, such as inflammatory, cardiovascular and metastatic diseases, and so plenty of effort has been invested into developing integrin specific drugs. Humans have 24 different integrins, four of which are collagen receptor (α1β1, α2β1, α10β1, α11β1) and five leukocyte specific integrins (αLβ2, αMβ2, αXβ2, αDβ2, αEβ7). These two integrin groups are quite unselective having both primary and secondary ligands. This work presents the first systematic studies performed on these integrin groups to find out how integrin activation affects ligand binding and selectivity. These kinds of studies are important not only for understanding the partially overlapping functions of integrins, but also for drug development. In general, our results indicated that selectivity in ligand recognition is greatly reduced upon integrin activation. Interestingly, in some cases the ligand binding properties of integrins have been shown to be cell type specific. The reason for this is not known, but our observations suggest that cell types with a higher integrin activation state have lower ligand selectivity, and vice versa. Furthermore, we solved the three-dimensional structure for the activated form of the collagen receptor α1I domain. This structure revealed a novel intermediate conformation not previously seen with any other integrin αI domain. This is the first 3D structure for an activated collagen receptor αI domain without ligand. Based on the differences between the open and closed conformation of the αI domain we set structural criteria for a search for effective collagen receptor drugs. By docking a large number of molecules into the closed conformation of the α2I domain we discovered two polyketides, which best fulfilled the set structural criteria, and by cell adhesion studies we showed them to be specific inhibitors of the collagen receptor integrins.

Sphingosine-1-phosphate-evoked invasion of follicular thyroid cancer cells : evidence for the involvement of HIF-Iα, MMP2 and MMP9

Sphingolipids are widely expressed molecules, which traditionally were considered to have majorly structural properties. Nowadays, however, they are implicated in a wide range of different biological processes. The bioactive lipid sphingosine 1-phosphate (S1P) has emerged during the past decade as one of the most studied molecules due to its proliferative and pro-migratory abilities both during normal physiology and in the pathology of a subset of different diseases. Migration and invasion of cancer cells require changes in cell behavior and modulation of the tissue microenvironment. Tumor aggressiveness is markedly enhanced by hypoxia, in which hypoxia inducible transcription factors 1-2α (HIF-1-2α) are activated to promote metabolism, proliferation and migration. Invasion requires degradation of the extracellular matrix (ECM) achieved by several degrading and remodeling enzymes. Matrix metalloproteinases (MMPs) are broadly expressed and well accepted as proteolytic enzymes with essential roles both in normal physiology and in pathology. Previously, S1P was shown to strongly evoke migration of follicular ML-1 thyroid cancer cells. The objective of this study was to further investigate and understand the mechanisms behind this regulation. In the first project it was demonstrated that S1P enhances the expression and activity of HIF-1α. S1P enhanced the expression of HIF-1α by increasing its synthesis and stability. The S1P-increased HIF-1α was mediated via S1P3, Gi/0, PI3K, PKCβI, ERK1/2, mTOR and translation factors p70S6K and eIF4E. Finally, it was shown that HIF-1α mediated S1P-induced migration. The ECM is constituted of a complex and coordinated assembly of many types of proteins. In order to be able to invade, cells need to break down the ECM, therefore several key players in this event were investigated in the second project. S1P increased the secretion and activity of MMP2 and MMP9 via S1P-receptor 1 and 3 and that these MMPs participated in the S1P-facilitated invasion of ML-1 cells. In this interplay, calpains and Rac1 were involved, both of which are crucial players in migration and invasion. The prognosis for some types of thyroid cancer is relatively good. However, there are forms of thyroid cancers, for which there are no treatments or the current available treatments are inefficient. Thus, new medical interventions are urgently needed. In the third project the significance of the S1P-receptor modulating drug FTY720, which is currently used for the treatment of multiple sclerosis (MS), was studied. The effect of FTY720 was tested on several thyroid cancer cell lines, and it inhibited the proliferation and invasion of all cancer cell lines tested. In ML-1 cells, FTY720 attenuated invasion by blocking signaling intermediates important for migration and invasion of the cells. Moreover, FTY720 inhibited the proliferation of ML-1 cells by increasing the expression of p21 and p27, hence, inducing cell arrest in G1 phase of the cell cycle. Thus, it can be suggested that FTY720 could be used in the treatment of thyroid cancer.

Clever-1 ja sen ilmeneminen konditionaalisesti poistogeenisissä hiirimalleissa

Proteiinit ovat elimistön perusyksiköitä. Niiden oikeanlainen toiminta ja rakenne ovat välttämättömiä solujen tarkoituksenmukaiselle toiminnalle. CLEVER-1 (common lymphatic endothelial and vascular entohelial receptor-1) on tyypin 2 makrofageissa ja sinusoidaalisessa endoteelissä tavallisesti ilmentyvä proteiini, jonka yhteyttä elimistön normaaliin toimintaan ja moniin eri sairaustiloihin on pyritty selvittämään. Tämän syventävien opintojen kirjallisen työn tarkoituksena on koota kirjallisuuskatsaukseen tämänhetkinen tieto CLEVER-1 -molekyylistä sekä kokeellisessa osiossa tutkia kyseisen molekyylin ilmenemistä eri hiirimalleissa. Kirjallisuuskatsauksen artikkelit valittiin PubMed-tietokannasta. Kokeellisessa osiossa perehdyin CLEVER-1:n ilmenemiseen hiiren maksassa, munuaisessa ja keuhkoissa. Tarkoituksena oli tutkia molekyylin ilmenemistä villityypin hiirissä ja verrata ilmenemistä hiiriin, joissa CLEVER-1 on poistettu vain joko makrofageista tai endoteelisoluista (ns. konditionaalisesti poistogeeniset hiirimallit). Ilmenemistä tutkittiin kaksoisfluoresenssivärjäyksillä. Kirjallisuuskatsauksessa osoitan, miten CLEVER-1 on liitetty moniin eri sairaustiloihin, erityisesti syöpäsairauksiin sekä tulehduksellisiin sairauksiin. Lisäksi pyrin hieman kartoittamaan tulevaisuudennäkymiä CLEVER-1:een liittyvässä tutkimuksessa. Kokeellisessa osiossa sain tuloksia, jotka osoittavat, että konditionaalisesti poistogeeniset hiirimallit eivät toimi aivan odotetulla tavalla. CLEVER-1:tä ei ole kyetty poistamaan täysin halutuista kohdesoluista. Havaitsin kuitenkin joitakin eroja ilmenemisessä poistogeenisten ja villityypin hiirten välillä. Lisäksi CLEVER-1 ilmentyy bronkiolaaristen epiteelisolujen alla kaikkien hiirilinjojen keuhkoissa. Näiden solujen alkuperä on vielä toistaiseksi tuntematon.