Mechanisms of cardiac chamber-specific gene expression of natriuretic peptides

Majalahti, T. (Theresa)

07 October 2008

Abstract Clarification of the mechanisms of cardiac-specific gene expression provides not only basic knowledge about how the gene expression is regulated in the heart, but also about the changes in the gene expression during the development of cardiovascular diseases. The purpose of this study was to analyze the mechanisms of cardiac chamber-specific gene expression and cardiac gene activation induced by mechanical load. In the present study, the experiments were carried out by using two cardiac genes, salmon cardiac peptide (sCP) and rat B-type natriuretic peptide (BNP) genes as models. sCP was discovered previously in our laboratory and turned out to be extremely cardiac-specific, representing A-type natriuretic peptide characters in an exaggerated way. In neonatal rat cardiomyocytes, the sCP promoter activity was shown to be strictly restricted to atrial cells and the promoter to be inert to cardiac hypertrophy-inducing factors. In order to find out the mechanisms of earlier proved BNP gene activation by mechanical load, BNP promoter activity was studied in vivo in adult rat hearts. The tandem GATA transcription factor binding site at position -80/-91 was shown to be essential for the BNP gene induction by angiotensin II. To clarify the possiblity to transfer the characters of the BNP gene into the sCP gene, short BNP fragments were inserted to the sCP gene promoter. The otherwise atrial-restricted sCP promoter was shown to be switched on in rat ventricular cardiomyocytes by adding a short BNP proximal promoter element to the sCP promoter, preferably near to the transcription start site. This activity was partly dependent on the -80/-91 GATA sites in the BNP promoter. Thus, A-type natriuretic peptide regulation can be switched to B-type regulation by a short proximal BNP promoter element. In conclusion, these studies reveal certain basic differences in cardiac atrial and ventricular gene expression.

cardiac-specific gene expression

cultured cardiomyocytes

luciferase reporter gene constructs

mechanical load

promoter activity

Onkogenní promotor c-myc jako cíl pro nový typ heterocyklických dikationtů stabilizujících G-kvadruplex. / The promoter of c-myc oncogene as a target for a novel type of heterocyclic cations stabilizing G-quadruplex.

Pohlová, Lenka

January 2015

Targeting oncogene promoters: a novel heterocyclic cations as G-quadruplex stabilizing ligands Lenka Pohlová Abstract: The diploma thesis studies an effect of newly synthesized group of compounds - helquats - on the expression of c-myc as a major player in malignant transformation and tumorigenesis via the stabilization of G-quadruplex in c-myc promotor. The G-quadruplex c-myc stabilization ability was tested for 101 helquats using dual luciferase reporter assay. The G-quadruplex c-myc stabilization ability was found for 13 helquats by this method. 8 successful helquats was selected by a comparison of the results from dual luciferase reporter assay and FRET melting assay. Effect on cell viability of tumor (HeLa S3) and non-tumor (HUVEC) cell lines was evaluated for these 8 helquats. Three of them exhibited cytotoxic effect on tumor cells but no effect was observed on viability of non-tumor cells. Moreover, an effect of these 3 helquats on c-myc expression on both mRNA and protein level, where significant effect on c-myc mRNA expression was not found for most of incubation periods. The 30% decrease in mRNA level was observed only for 24 hours incubation period for two helquats (LS702 and MJ656). The decrease in the expression on protein level was observed for all tested helquats, and helquat LS702 had the...

Functional Analysis of the TRIB1 Locus in Coronary Artery Disease

Douvris, Adrianna

21 July 2011

The TRIB1 locus (8q24.13) is a novel locus associated with plasma TGs and CAD risk. Trib1 is a regulator of MAPK activity, and has been shown to regulate hepatic lipogenesis and VLDL production in mice. However, the functional relationship between common SNPs at the TRIB1 locus and plasma lipid traits is unknown; TRIB1 has not been identified as an eQTL. This cluster of SNPs falls within an intergenic region 25kb to 50kb downstream of the TRIB1 coding region. By phylogenetic footprinting analysis and DNA genotyping, we identified an evolutionarily conserved region (CNS1) within the risk locus that harbours two common SNPs in tight LD with GWAS risk SNPs and significantly associated with CAD. We investigated the regulatory function of CNS1 by luciferase reporter assays in HepG2 cells and demonstrate that this region has promoter activity. In addition, the rs2001844 risk allele significantly reduces luciferase activity, suggesting that altered expression of the EST-based gene may be associated with plasma TGs. We identified an EST within the risk locus directly downstream of CNS1. We performed 5'/3' RACE using HepG2 RNA, identified multiple variants of this EST-based gene, and confirmed its transcription start site within CNS1. We hypothesize that this EST is a long noncoding RNA due to low abundance, poor conservation, and absence of significant ORF. Over-expression of a short variant implicates its function in the regulation of target gene transcription, although the mechanism of action remains unknown. We conclude that the risk locus at 8q24.13 harbours a novel EST-based gene that may explain the relationship between GWAS SNPs at this locus and plasma lipid traits.

Coronary Artery Disease

Plasma triglycerides

Lipoproteins

Genomics

Genome-wide association studies

Single nucleotide polymorphisms

TRIB1 locus (8q24.13)

Noncoding RNA

Hepatic lipogenesis

Gene transcription

5'/3' RACE

Luciferase reporter assays

Promoter

Intergenic

Functional Analysis of the TRIB1 Locus in Coronary Artery Disease

Douvris, Adrianna

21 July 2011

The TRIB1 locus (8q24.13) is a novel locus associated with plasma TGs and CAD risk. Trib1 is a regulator of MAPK activity, and has been shown to regulate hepatic lipogenesis and VLDL production in mice. However, the functional relationship between common SNPs at the TRIB1 locus and plasma lipid traits is unknown; TRIB1 has not been identified as an eQTL. This cluster of SNPs falls within an intergenic region 25kb to 50kb downstream of the TRIB1 coding region. By phylogenetic footprinting analysis and DNA genotyping, we identified an evolutionarily conserved region (CNS1) within the risk locus that harbours two common SNPs in tight LD with GWAS risk SNPs and significantly associated with CAD. We investigated the regulatory function of CNS1 by luciferase reporter assays in HepG2 cells and demonstrate that this region has promoter activity. In addition, the rs2001844 risk allele significantly reduces luciferase activity, suggesting that altered expression of the EST-based gene may be associated with plasma TGs. We identified an EST within the risk locus directly downstream of CNS1. We performed 5'/3' RACE using HepG2 RNA, identified multiple variants of this EST-based gene, and confirmed its transcription start site within CNS1. We hypothesize that this EST is a long noncoding RNA due to low abundance, poor conservation, and absence of significant ORF. Over-expression of a short variant implicates its function in the regulation of target gene transcription, although the mechanism of action remains unknown. We conclude that the risk locus at 8q24.13 harbours a novel EST-based gene that may explain the relationship between GWAS SNPs at this locus and plasma lipid traits.

Coronary Artery Disease

Plasma triglycerides

Lipoproteins

Genomics

Genome-wide association studies

Single nucleotide polymorphisms

TRIB1 locus (8q24.13)

Noncoding RNA

Hepatic lipogenesis

Gene transcription

5'/3' RACE

Luciferase reporter assays

Promoter

Intergenic

Functional Analysis of the TRIB1 Locus in Coronary Artery Disease

Douvris, Adrianna

21 July 2011

The TRIB1 locus (8q24.13) is a novel locus associated with plasma TGs and CAD risk. Trib1 is a regulator of MAPK activity, and has been shown to regulate hepatic lipogenesis and VLDL production in mice. However, the functional relationship between common SNPs at the TRIB1 locus and plasma lipid traits is unknown; TRIB1 has not been identified as an eQTL. This cluster of SNPs falls within an intergenic region 25kb to 50kb downstream of the TRIB1 coding region. By phylogenetic footprinting analysis and DNA genotyping, we identified an evolutionarily conserved region (CNS1) within the risk locus that harbours two common SNPs in tight LD with GWAS risk SNPs and significantly associated with CAD. We investigated the regulatory function of CNS1 by luciferase reporter assays in HepG2 cells and demonstrate that this region has promoter activity. In addition, the rs2001844 risk allele significantly reduces luciferase activity, suggesting that altered expression of the EST-based gene may be associated with plasma TGs. We identified an EST within the risk locus directly downstream of CNS1. We performed 5'/3' RACE using HepG2 RNA, identified multiple variants of this EST-based gene, and confirmed its transcription start site within CNS1. We hypothesize that this EST is a long noncoding RNA due to low abundance, poor conservation, and absence of significant ORF. Over-expression of a short variant implicates its function in the regulation of target gene transcription, although the mechanism of action remains unknown. We conclude that the risk locus at 8q24.13 harbours a novel EST-based gene that may explain the relationship between GWAS SNPs at this locus and plasma lipid traits.

Coronary Artery Disease

Plasma triglycerides

Lipoproteins

Genomics

Genome-wide association studies

Single nucleotide polymorphisms

TRIB1 locus (8q24.13)

Noncoding RNA

Hepatic lipogenesis

Gene transcription

5'/3' RACE

Luciferase reporter assays

Promoter

Intergenic

Functional analyses of polymorphisms in the promoters of the KLK3 and KLK4 genes in prostate cancer

Lai, John

January 2006

This PhD aimed to elucidate the mechanisms by which polymorphisms may alter androgen-induced transactivation of androgen receptor (AR) target genes which may be important in prostate cancer aetiology. The second aspect of this PhD focused on identifying and characterising functional polymorphisms that may have utility as predictive risk indicators for prostate cancer and which may aid in earlier therapeutic intervention and better disease management. Analyses were carried out on the kallikrein-related peptidase 3 (KLK3), also known as the prostate specific antigen (PSA), gene and the kallikrein-related peptidase 4 (KLK4) gene. The PSA and KLK4 genes are part of the serine protease family that have trypsin or chymotrypsin like activity and are thought to play a role in the development of hormone-dependent cancers in tissues such as those in the prostate, breast, endometrium and ovaries. In the prostate, PSA is regulated by androgens and three androgen response elements (AREs) have been described in the promoter and upstream enhancer region. The PSA ARE I harbours a polymorphism at -158 bp from the transcription initiation site (TIS) that results in a G to A transition (G-158A). This PhD investigated the functional significance of the PSA G-158A polymorphism which has been reported to be associated with prostate cancer risk. Electromobility shift assays (EMSAs) investigating the interaction of ARE I variants with the AR DNA binding domain (AR-DBD) demonstrated that the A allele had a two-fold increased binding affinity for the AR-DBD when compared with the G allele. This was confirmed with endogenous AR in limited proteolysis-EMSA experiments. The limited proteolysis-EMSA experiments also demonstrated differential sensitivities of PSA ARE I alleles to trypsin digestion, which suggests that the G-158A polymorphism has an allosteric effect on the AR that alters AR/ARE I complex stability. Furthermore, Chromatin Immunoprecipitation (ChIP) assays suggest that the A allele more readily recruited the AR in vivo when compared with the G allele and is consistent with the in vitro binding data. Luciferase reporter assays carried out in both LNCaP and 22Rv1 prostate cancer cells, and using the natural (dihydrotestosterone; DHT) ligand demonstrated that the A allele was more responsive to androgens in LNCaP cells. Hence, this study has elucidated the potential mechanisms by which the G-158A polymorphism may differentially regulate PSA expression (of which up-regulation of PSA is thought to be important in prostate cancer development and progression). KLK4 has similar tissue-restricted expression as PSA and is up-regulated by steroid hormones in many endocrine cells including those in the prostate. A putative ARE (KLK4-pARE) located at -1,005 to -1019 relative to the more predominantly used transcription initiation site, TIS3, was initially found in supershift assays using AR antibodies to interact with endogenous AR. However, subsequent EMSA analysis using purified AR-DBD suggest that KLK4-pARE may be interacting with the AR indirectly. To investigate this hypothesis, a tandem construct of KLK4-pARE was cloned into the pGL3-Promoter vector for hormone-induced reporter assays. However, reporter assays did not demonstrate any responsiveness of KLK4-pARE to androgens, estradiol or progestins. Consequently, Real-Time PCR was carried out to reassess the hormonal regulation of KLK4 at the mRNA level. Consistent with the literature, data from this study suggests that KLK4 may be up-regulated by androgens, progestins and estradiol in a cyclical manner. Hormone-induced luciferase reporter assays were then carried out on seven promoter constructs that span 2.8 kb of the KLK4 promoter from TIS3. However, none of the seven promoter constructs demonstrated any significant responsiveness to androgens, estradiol or progestins. This study suggests that hormone response elements (HREs) that may drive the hormonal regulation of KLK4 in prostate cancer may be located further upstream from the promoter region investigated in this PhD, or alternatively, may lie 3' of TIS3. The characterisation of KLK4 promoter polymorphisms and their flanking sequences were also carried out in parallel to the functional work with the intent to assess the functional significance of any polymorphisms that may be located within HREs. In total 19 polymorphisms were identified from the public databases and from direct sequencing within 2.8 kb of the KLK4 promoter from TIS3. However, the functional and clinical significance of these 19 polymorphisms were not further pursued given the negative findings from the functional work. The PSA AR enhancer region was also assessed for potential polymorphisms that may be associated with prostate cancer risk. A total of 12 polymorphisms were identified in the PSA enhancer of which two (A-4643G and T-5412C) have been reported to alter functionality of the enhancer region and thus, prioritised for further analysis. Association analysis for prostate cancer risk was then carried out on these PSA enhancer polymorphisms as none of the KLK4 promoter polymorphisms were found in functional HREs. No significant association for either the A-4643G or T-5412C polymorphism with prostate cancer risk was found at the P = 0.05 level. However, under an age-adjusted dominant model a 1.22- (95% CI = 1.16-1.26) and 1.23-fold (95% CI = 1.17-1.29) increased risk for prostate cancer was found for the A-4643G or T-5412C polymorphisms, respectively. Both polymorphisms were also assessed for association with tumour grade and stage and PSA levels. Genotypes were significantly different for the A-4643G and T-5412C polymorphisms with tumour stage and PSA levels, respectively. However, these results are likely to be biased by the case population which consist primarily of men who presented with incidental (pT1) and organ-confined (pT2) tumours. To summarise, the A-4643G and T-5412C polymorphisms are unlikely to be associated with prostate cancer risk, PSA levels or stage/grade of disease. However, further analyses in a larger cohort is warranted given that these polymorphisms alter androgen responsiveness of the PSA enhancer and that elevated PSA levels are indicative of men with prostate cancer. To summarise, this PhD has elucidated the functional significance of the PSA G-158A polymorphism in prostate cancer and which may be important in prostate cancer patho-physiology. This PhD has also furthered the understanding of the hormonal regulation of KLK4 in prostate cancer cells. Finally, this PhD has carried out a pilot study on two functional PSA enhancer polymorphisms (A-4643G and T-5412C) with prostate cancer risk.

prostate cancer

single nucleotide polymorphism (SNP)

kallikreins (KLKs)

kallikrein 4 (KLK4)

prostate specific antigen (PSA)

androgens

hormones

androgen receptor (AR)

androgen response element (ARE)

electromobility shift assay (EMSA)

luciferase reporter assay

Functional Analysis of the TRIB1 Locus in Coronary Artery Disease

Douvris, Adrianna

January 2011

The TRIB1 locus (8q24.13) is a novel locus associated with plasma TGs and CAD risk. Trib1 is a regulator of MAPK activity, and has been shown to regulate hepatic lipogenesis and VLDL production in mice. However, the functional relationship between common SNPs at the TRIB1 locus and plasma lipid traits is unknown; TRIB1 has not been identified as an eQTL. This cluster of SNPs falls within an intergenic region 25kb to 50kb downstream of the TRIB1 coding region. By phylogenetic footprinting analysis and DNA genotyping, we identified an evolutionarily conserved region (CNS1) within the risk locus that harbours two common SNPs in tight LD with GWAS risk SNPs and significantly associated with CAD. We investigated the regulatory function of CNS1 by luciferase reporter assays in HepG2 cells and demonstrate that this region has promoter activity. In addition, the rs2001844 risk allele significantly reduces luciferase activity, suggesting that altered expression of the EST-based gene may be associated with plasma TGs. We identified an EST within the risk locus directly downstream of CNS1. We performed 5'/3' RACE using HepG2 RNA, identified multiple variants of this EST-based gene, and confirmed its transcription start site within CNS1. We hypothesize that this EST is a long noncoding RNA due to low abundance, poor conservation, and absence of significant ORF. Over-expression of a short variant implicates its function in the regulation of target gene transcription, although the mechanism of action remains unknown. We conclude that the risk locus at 8q24.13 harbours a novel EST-based gene that may explain the relationship between GWAS SNPs at this locus and plasma lipid traits.

Coronary Artery Disease

Plasma triglycerides

Lipoproteins

Genomics

Genome-wide association studies

Single nucleotide polymorphisms

TRIB1 locus (8q24.13)

Noncoding RNA

Hepatic lipogenesis

Gene transcription

5'/3' RACE

Luciferase reporter assays

Promoter

Intergenic

Rôle du ribosome dans la sénescence

Del Toro Del Toro, Neylen

12 1900

La sénescence est considérée comme un mécanisme de suppression tumorale puisque les cellules potentiellement dangereuses, activent leurs protéines de sauvegarde pour arrêter leur prolifération. Les protéines de sauvegarde telles que RB et p53 sont activées suite à différents stress comme des dommages à l’ADN, le raccourcissement des télomères ou l’induction oncogénique. Les cellules sénescentes restent métaboliquement actives, subissent des modifications dans leur expression génique, et sécrètent des cytokines et des chimiokines qui ont des effets paracrines pro-oncogéniques, mais peuvent également contribuer à la stabilité de l’arrêt du cycle cellulaire dans la sénescence de façon autocrine. Une des particularités du phénotype sénescent est la dégradation sélective des protéines dépendante de l’ubiquitination et du protéasome. Parmi les cibles de dégradation se trouvent des protéines impliquées dans la biogenèse du ribosome, ainsi que celles d’autres voies cellulaires requises pour la croissance de cellules cancéreuses. Ceci est lié à un stress nucléolaire qui affecte la biogenèse du ribosome, menant à l’accumulation, dans le nucléoplasme ou le nucléole, de protéines ribosomiques. Ce comportement suggère que les ribosomes des cellules sénescentes seraient structurellement différents. Par conséquent, ceci pourrait entrainer des effets sur leurs capacités à réguler l’initiation, l’élongation et/ou la terminaison de la traduction des ARN messagers (ARNm). Par ailleurs, la déplétion de certaines protéines impliquées dans la ribogenèse, ainsi que la surexpression de protéines ribosomiques telles que RPS14/uS11 amènent à la sénescence. Malgré le stress nucléolaire et les défauts de ribogenèse associés à la sénescence, les cellules sénescentes présentent des niveaux de translecture du codon d’arrêt très diminué, suggérant l’existence de défauts de production de protéines allongées en C-terminal. Nous émettons l’hypothèse que les défauts de la ribogenèse affecteraient la fonction des protéines ribosomiques et des ribosomes. Cette perturbation aurait un impact sur le rôle de suppresseur tumoral de la sénescence. Le premier objectif de cette thèse consiste à démontrer le rôle de RPL22/eL22 en tant que régulateur du cycle cellulaire et inducteur de la sénescence. Le deuxième but est de démontrer que, malgré la perturbation nucléolaire, les ribosomes des fibroblastes sénescents reconnaissent les codons d’arrêt de façon plus efficace que les ribosomes des cellules transformées, ou des cellules normales en prolifération. Nous avons démontré que le phénotype de sénescence peut être induit quand l’expression de RPL22/eL22 est augmentée. RPL22/eL22 s’accumule principalement dans le nucléole, de manière différente de RPS14/uS11, dont l’accumulation est nucléoplasmique. En effectuant des essais kinases in vitro, nous avons montré que RPL22/eL22, tout comme RPS14/uS11, peuvent interagir et inhiber le complexe CDK4-Cycline D1 afin d’activer la voie de RB et établir l’arrêt du cycle cellulaire et la sénescence. Afin de démontrer la fidélité de la terminaison de la traduction dans les cellules sénescentes, nous avons utilisé un système de rapporteurs de luciférases, pour détecter les erreurs de translecture ainsi que pour avoir un contrôle interne du système. L’inactivation de la voie du suppresseur tumoral RB par surexpression de CDK4 ou de l’oncoprotéine virale E7, nous a permis d’observer l’augmentation de la translecture dans les cellules sénescentes. Tandis que l’activation de la voie de suppression tumorale RB, à l’aide du suppresseur de tumeur PML, de la surexpression de RPL22/eL22 et de RPS14/uS11, ainsi que de l’utilisation de Palbociclib (PD-0332991), un inhibiteur des kinases CDK4/6, a montré une réduction des erreurs de translecture. Ces résultats indiquent une nouvelle fonction des protéines du ribosome en tant que suppresseurs de tumeur, permettant d’inhiber les erreurs de translecture du codon d’arrêt de façon dépendante de la voie de RB. Ces travaux suggèrent que de petites molécules ou peptides pourraient simuler les fonctions inhibitrices de ces protéines ribosomiques afin de traiter certains cancers où la voie de RB est activable. / Senescence is considered a mechanism for tumor suppression since potentially dangerous cells activate their protective proteins to stop their proliferation. Safeguard proteins such as RB and p53 are activated as a result of stress such as DNA damage, telomere shortening or oncogenic induction. Senescent cells are metabolically active, they undergo changes in their gene expression and secrete cytokines and chemokines with pro-oncogenic paracrine effects, but which can also contribute to the stability of the senescent cell cycle arrest in an autocrine way. One of the peculiarities of the senescent phenotype is the selective ubiquitination and proteasome dependent-degradation of proteins involved in ribosome biogenesis and other cellular pathways required for cancer cell growth, leading to the accumulation, in the nucleoplasm or nucleolus, of ribosomal proteins. This behavior suggests that the ribosomes of senescent cells are structurally different. Therefore, this could have effects on their ability to regulate the initiation, elongation and/or translation termination of messenger RNAs (mRNAs). Moreover, the depletion of some proteins involved in ribogenesis, as well as the overexpression of ribosomal proteins such as RPS14/uS11 lead to senescence. Despite nucleolar stress and ribogenesis defects associated to senescence, global translation does not seem to be affected in senescence. Strikingly, senescent cells have reduced translational readthrough suggesting that they have defects in the production of C-terminal extended proteins. We hypothesize that defects in ribogenesis would affect the function of ribosomal proteins and ribosomes influencing the tumor suppressor role of senescence. The first aim of this thesis is to demonstrate the role of RPL22/eL22 as a regulator of the cell cycle and senescence inducer. The second aim of this thesis is to demonstrate that, despite the nucleolar disruption, the ribosomes of senescent fibroblasts recognize stop codons more efficiently than ribosomes from transformed cells, but also than ribosomes from proliferating normal cells. We found that the senescent phenotype can be induced by enhancing the expression of RPL22/eL22. RPL22/eL22 accumulates mainly in the nucleolus, unlike RPS14/uS11, whose accumulation is nucleoplasmic. By performing an in vitro kinase assay, we showed that RPL22/eL22, just like RPS14/uS11, can interact and inhibit the CDK4-Cyclin D1 complex in order to activate the RB pathway and establish cellular arrest and senescence. To assess translation termination accuracy in senescent cells, we used a system of luciferase reporters to measure the fidelity of translation termination. Inactivation of the RB tumor suppressor pathway using CDK4 or the viral oncoprotein E7 also increased readthrough in senescent cells while overexpression of PML, a tumor suppressor that activates the RB pathway, overexpression of RPL22/eL22 and RPS14/uS11, as well as the use of Palbociclib (PD-0332991), a CDK4/6 inhibitor, reduce readthrough errors. These results indicate a novel function of ribosomal proteins as tumor suppressors, making it possible to inhibit translational readthrough errors, in a RB-dependent pathway. This work suggests that small molecules or peptides could mimic the inhibitory functions of these ribosomal proteins in order to treat cancers where the RB pathway is activatable.

Sénescence

Biogenèse du ribosome

RPL22/eL22

CDK4-Cycline D1

Translecture

Terminaison de la traduction

Suppresseur tumoral rétinoblastome (RB)

Rapporteur à deux luciférases

Senescence

Ribosome biogenesis

CDK4-Cyclin D1

Readthrough

Translation termination

Retinblastoma tumor suppressor (RB)

Dual-luciferase reporter

Měření aktivace signálních drah v myší makrofágové linii IC-21 a primárních dendritických buňkách po infekci virem klíšťové encefalitidy. / Measurement of signalling pathway activation in mouse macrophage line IC-21 and primery dendritic cells after infection with tick-borne encephalitis virus.

Kožantová, Jana

January 2017

Tick-borne encephalitis is a serious disease of the central nervous system. It is caused by tick-borne encephalitis virus, which is transmitted by ticks. The Czech Republic is one of the countries with the highest prevalence of this disease. Tick-borne encephalitis virus is able to replicate in several cell types. In this work we focused on macrophage line IC-21 and dendritic cells, because these cells are the first, which encounter the virus and support its spreading in the host at early stage of infection. So far there is not known any specific receptor for virus entry into cells or which signaling pathways activates. Therefore, we decided to investigate the activation of selected signaling pathways after infection with tick-borne encephalitis virus and influence of tick saliva on this activation. We employed methods of dual luciferase reporter assay, immunosandwich assay and western blot. The obtained results showed that in virus infected IC-21 cells are activated phosphatidyl-inositol pathway, NF-κB pathway, signaling molecule Erk1/2 and others. Testing of tick saliva effect revealed significantly decreased activity of NF-κB, AP-1 and CREB.