Toll-like receptor 9 in breast cancer

The innate immune system recognizes microbial features leading to the activation of the adaptive immune system. The role of Toll-like receptor 9 (TLR9) is to recognize microbial DNA. In addition to immune cells, TLR9 is widely expressed in breast cancer in addition to other cancers. Breast cancer is the most common cancer in women, affecting approximately one in eight in industrialized countries. In the clinical setting, breast cancer is divided into three clinical subtypes with type-specific treatments. These subtypes are estrogen receptor (ER)-positive, HER2-positive and triple-negative (TNBC) breast cancer. TNBC is the most aggressive subtype that can be further divided into several subtypes. TNBC tumors lack ER, progesterone receptor and HER2 receptor. Therefore, the current clinically used targeted therapies are not suitable for TNBC treatment as TNBC is a collection of diseases rather than one entity. Some TNBC patients are cured with standard chemotherapy, while others rapidly die due to the disease. There are no clinically used iomarkers which would help in predicting which patients respond to chemotherapy. During this thesis project, we discovered a novel good-prognosis TNBC subtype. These tumors have high TLR9 expression levels. Our findings suggest that TLR9 screening in TNBC patient populations might help to identify the patients that are at the highest risk regarding a relapse. To gain better understanding on the role of TLR9 in TNBC, we developed an animal model which mimicks this disease. We discovered that suppression of TLR9 expression in TNBC cells increases their invasive properties in hypoxia. In line with the clinical findings, TNBC cells with low TLR9 expression also formed more aggressive tumors in vivo. TLR9 expression did not, however, affect TNBC tumor responses to doxorubicin. Our results suggest that tumor TLR9 expression may affect chemotherapyrelated immune responses, however, this requires further investigation. Our other findings revealed that DNA released by chemotherapy-killed cells induces TLR9-mediated invasion in living cancer cells. Normally, extracellular self-DNA is degraded by enzymes, but during massive cell death, for example during chemotherapy, the degradation machinery may be exhausted and self-DNA is taken up into living cells activating TLR9. We also discovered that the malaria drug chloroquine, an inhibitor of autophagy and TLR9 signalling does not inhibit TNBC growth in vivo, independently of the TLR9 status. Finally, we found that ERα as well as the sex hormones estrogen and testosterone regulate TLR9 expression and activity in breast cancer cells in vitro. As a conclusion, we suggest that TLR9 is a potential biomarker in TNBC. ------- Sisäsyntyisen immuniteetin tehtävä on tunnistaa mikrobien molekyylirakenteita, mikä saa aikaan adaptiivisen immuunijärjestelmän aktivoitumisen. Tollin kaltainen reseptori 9 (TLR9) on dna:ta tunnistava sisäsyntyisen immuniteetin reseptori, jota ilmennetään myös useissa syövissä, kuten rintasyövässä. Rintasyöpä on naisten yleisin syöpä, johon joka kahdeksas nainen sairastuu elämänsä aikana. Kliinisesti rintasyöpä jaotellaan kolmeen alatyyppiin, joista kolmoisnegatiivinen rintasyöpä on aggressiivisin. Tämän tyypin syövät eivät ilmennä hormonireseptoreja (estrogeeni- ja progesteronireseptori) tai HER2-reseptoria. Tästä johtuen kolmoisnegatiivisten potilaiden hoitoon ei voida käyttää rintasyövän nykyisten hoitosuositusten mukaisia täsmähoitoja. Kolmoisnegatiivinen rintasyöpä ei kuitenkaan ole yksi sairaus, koska molekyylitasolla sen on osoitettu koostuvan lukuisista, biologialtaan erilaisista syöpämuodoista. Tällä hetkellä kliinisessä käytössä ei ole biomarkkeria, jonka avulla kolmoisnegatiivisen rintasyövän alatyypit voisi erottaa toisistaan. Löysimme uuden kolmoisnegatiivisen syövän alatyypin, joka ilmentää vain vähän TLR9-proteiinia. Tällä alatyypillä on erittäin huono ennuste ja tulostemme perusteella TRL9-tason selvittäminen voisi seuloa huonoennusteiset syövät kolmoisnegatiivisten syöpien joukosta. Kehitimme eläinmallin, jolla voidaan tutkia matalan ja korkean TLR9-tason vaikutuksia kolmoisnegatiivisten kasvainten hoitovasteeseen. Toinen löytömme oli, että kemoterapialla tapettujen syöpäsolujen dna saa aikaan elävien syöpäsolujen TLR9-välitteistä invaasiota. Normaalisti entsyymit hajoittavat yksilön oman solunulkoisen dna:n. Erikoistilanteissa, kuten syöpähoitojen yhteydessä, jolloin solukuolema on massiivista, elimistön oma koneisto ei ehdi tuhoamaan solunulkoista dna:ta ja sitä voi kertyä eläviin soluihin, joissa se aktivoi TLR9:n. Kolmanneksi havaitsimme, että malarialääke klorokiini, joka estää TLR9:n toimintaa ja jolla on syövänvastaisia vaikutuksia soluviljelyolosuhteissa, ei estänyt TLR9-positiivisten tai TLR9-negatiivisten kasvainten kasvua käyttämässämme eläinmallissa. Neljänneksi soluviljelykokeittemme tulokset osoittivat, että sukupuolihormonit estrogeeni ja testosteroni sekä estrogeenireseptori osallistuvat TLR9:n ilmentymisen ja aktiivisuuden säätelyyn. Tuloksemme osoittavat, että TLR9 potentiaalinen biomarkkeri kolmoisnegatiivisessa rintasyövässä.

The Role of PME-1 in Cancer: Therapeutic Implication

Protein phosphatase 2A (PP2A) plays a major role in maintaining cellular signaling homeostasis in human cells by reversibly affecting the phosphorylation of a variety of proteins. Protein phosphatase methylesterase-1 (PME-1) negatively regulates PP2A activity by reversible demethylation and active site binding. Thus far, it is known that overexpression of PME-1 in human gliomas contributes to ERK pathway signaling, cell proliferation, and malignant progression. Whether PME-1-mediated PP2A inhibition promotes therapy resistance in gliomas is unknown. Specific PP2A targets regulated by PME-1 in cancers also remain elusive. Additionally, whether oncogenic function of PME-1 can be generalized to various human cancers needs to be investigated. This study demonstrated that PME-1 expression promotes kinase inhibitor resistance in glioblastoma (GBM). PME-1 silencing sensitized GBM cells to a group of clinically used indolocarbazole multikinase inhibitors (MKIs). To facilitate the quantitative evaluation of MKIs by cancer-cell specific colony formation assay, Image-J software-plugin ‘ColonyArea’ was developed. PME-1-silencing was found to reactivate specific PP2A complexes and affect PP2A-target histone deacetylase HDAC4 activity. The HDAC4 inhibition induced synthetic lethality with MKIs similar to PME-1 depletion. However, synthetic lethality by both approaches required co-expression of a pro-apoptotic protein BAD. In gliomas, PME-1 and HDAC4 expression was associated with malignant progression. Using tumor PME-1, HDAC4 and BAD expression based stratification signatures this study defined patient subgroups that are likely to respond to MKI alone or in combination with HDAC4 inhibitor therapies. In contrast to the oncogenic role of PME-1 in certain cancer types, this study established that colorectal cancer (CRC) patients with high tumor PME-1 expression display favorable prognosis. Interestingly, PME-1 regulated survival signaling did not operate in CRC cells. Summarily, this study potentiates the candidacy of PME-1 as a therapy target in gliomas, but argues against generalization of these findings to other cancers, especially CRC.