Roles of transglutaminase 2 in development of drug resistance and metastasis by cancer cells

Odii, Benedict Onyekachi

January 2014

No description available.

616.99

Sphingolipid metabolic enzymes modulate anticancer drug resistance

Min, Junxia.

January 2006

Thesis (Ph. D.)--University of Missouri-Columbia, 2006. / The entire dissertation/thesis text is included in the research.pdf file; the official abstract appears in the short.pdf file (which also appears in the research.pdf); a non-technical general description, or public abstract, appears in the public.pdf file. Title from title screen of research.pdf file viewed on (March 5, 2007) Vita. Includes bibliographical references.

Functional analyses of multidrug resistance protein 3 (MRP3) and characterization of a retinoic acid resistant human leukemia cell line (HL60-ATRA) /

Zeng, Hao,

January 2000

Thesis (Ph. D.)--Lehigh University, 2000. / Includes bibliographical references and vita.

Optimizing drug delivery in pancreatic ductal adenocarcinoma

Jacobetz, Michael

January 2011

No description available.

616.99

Development of a 3D Tissue Engineered Bone Tumor Model

Burdett, Emily

16 September 2013

3D ex vivo tumor models are required which better replicate the microenvironment encountered by tumor cells in vivo. In this study, we applied bone tissue engineering culture techniques to develop an ex vivo 3D bone tumor model. Ewing sarcoma cells were cultured on poly(ε-caprolactone) (PCL) microfiber scaffolds, and cellular growth kinetics, morphology, and infiltration were assessed. Cell/scaffold constructs were then exposed to anticancer drugs for up to 16 days and drug response was compared to 2D controls. Ewing sarcoma cells were capable of attachment and proliferation on PCL scaffolds and dense scaffold infiltration up to 200 micrometers. Constructs could be maintained in culture for up to 32 days, and high density 3D cell growth conferred an increased resistance to anticancer drugs over 2D controls. This 3D tumor model shows potential for use in future studies of bone tumor biology, especially as it pertains to the development of new anticancer drugs.

Tissue Engineering

3D Cancer Models

Ewing Sarcoma

Cancer Drug Discovery

Development And Investigation Of Etoposide Resistance In Mcf-7 Breast Cancer Cell Line

Kaplan, Esra

01 December 2010

Failure of chemotherapy in cancer patients because of development of drug resistance is a major problem. Alterations of DNA repair mechanisms and drug targets are among the important resistance mechanisms which are developed against topoisomerase II inhibitors etoposide and doxorubicin. Modifications in the expression levels of mismatch repair (MMR) genes due to resistance to topoisomerase II inhibitors are involved in breast cancer. In this study, etoposide resistant sublines were developed from MCF7 breast cancer cell line (MCF7/S) and the expression levels of TOP2A and two important MMR genes MSH2 and MLH1 were examined by real time qPCR. Previously developed doxorubicin resistant cells were also studied for comparison. Etoposide resistant sublines MCF7/1000E, MCF7/1250E and MCF7/2000E were approximately 2, 3 and 4 fold resistant relative to parental MCF7/S cells, respectively. MLH1, MSH2 and TOP2A expressions decreased in both etoposide and doxorubicin resistant sublines relative to MCF7/S cells. Expression levels of TOP2A in resistant sublines differ between 10-95 percent of the expression levels in the parental cells. In the sublines MCF7/200E, MCF7/500E, MCF7/750E and MCF7/1000E a decrease in TOP2A gene expression was determined. In sublines MCF7/1250E and MCF7/2000E fluctuations in the expression levels were observed. Among the doxorubicin resistant sublines (MCF7/600D and MCF7/1000D), in MCF7/1000D which is more resistant to doxorubicin, TOP2A expression level was higher. Expression levels of MSH2 decreased regularly as the resistance increased. However, in MCF7/1250E significant increase relative to MCF7/1000E was observed. In MCF7/2000E, expression levels of MSH2 again significantly decreased to 41 percent of the levels in parental cell line. Expression levels of MLH1 decreased significantly (18-58 percent) in etoposide resistant sublines relative to MCF7/S cells. In doxorubicin resistant sublines, a decrease in MLH1 gene expression was observed in MCF7/1000D. It can be concluded from the results that decrease in the expression levels of TOP2A, MSH2 and MLH1 genes may contribute to resistance together. Above a certain resistance level, sublines may develop new strategies for acquiring higher resistance. Whenever a strategy becomes limited, new strategies emerge. New approaches developed to overcome resistance in cancer chemotherapy should consider the molecular basis of resistance in different stages of the disease.

QH Genetics 426-470

Acquired resistance to HSP90 inhibition in triple-negative breast cancer

Mumin, Dk Nuramalina Hafizah Pg Hj

January 2016

Heat shock protein 90 (HSP90), a conserved molecular chaperone, has become a potential molecular target for cancer therapeutics. HSP90 inhibition (HSP90i) causes inhibition of several oncogenic pathways simultaneously and leads to anti-cancer activities in multiple cancers including in triple-negative breast cancer (TNBC). TNBC is a subtype of breast cancer with poor prognosis and lack of approved targeted therapies. Although HSP90i has shown promising initial clinical data, resistance to HSP90i can still arise in TNBC patients and its resistance mechanisms are not yet understood. In this study, using an in vitro system, we report for the first time the isolation of TNBC cells with acquired resistance to HSP90i. Proteome and whole transcriptome profiling, and a bioactive small molecule screen were performed to identify the molecular basis of resistance to HSP90i and potential therapeutic approaches to overcome acquired resistance to HSP90i in TNBC cells. Two independent HSP90i-resistant clones were acquired through prolonged exposure of a TNBC cell line (Hs578T) to HSP90i. The clones showed significant resistance to HSP90i, notably to resorcinol-based HSP90i. The HSP90i-resistant clones also shared genomic sequence variants, suggesting a pre-existing population of resistant cells within the parental cells. We demonstrate that upregulated expression of UGT1A9, possibly due to an increased intrinsic oxidative stress, is associated with acquired resistance to resorcinol-based HSP90i in TNBC cells, and sensitivity to HSP90i can be restored with a competitive inhibitor of UGT1A9. The HSP90i-resistant clones also exhibited slower growth and upregulated IL6- mediated JAK2-STAT3 survival signalling pathway, which might contribute to the crossresistance to chemotherapeutics and other targeted therapies seen in the clones. Finally, we demonstrate that inhibition of JAK2-STAT3 signalling pathway is able to increase the cytotoxic effects of HSP90i to TNBC cells. We conclude that by using in vitro assays, we are able to identify potential mechanisms of acquired resistance to HSP90i in TNBC cells. We propose that expression of UGT1A9 or STAT3 might be a potential biomarker of sensitivity to HSP90i in TNBC cells. A combined inhibition of HSP90 and JAK2 might be a potential therapeutic approach for the development of effective targeted therapies in TNBC patients.

The effect of MKP-1 inhibition on the cytotoxicity of chemotherapeutic drugs in breast cancer

Le Roux, Heloise

12 1900

Thesis (MSc)--Stellenbosch University, 2012. / ENGLISH ABSTRACT: Introduction: Cancer is an emerging health problem in South Africa, with breast cancer being one of the leading cancers affecting women globally. Therefore, there is a need to find novel targets to improve the therapeutic options for these patients. A recently proposed target is the mitogen-activated protein kinase phosphatase-1 (MKP-1). Studies have suggested that mitogen-activated protein kinase phosphatases are involved in the development of cancer and play an important role in the response of cancer cells to chemotherapy. Additionally, numerous studies have indicated that there is increased expression of MKP-1 in breast cancers where its over-expression is proposed to be a significant mediator in chemo-resistance. We propose that inhibition of MKP-1 will increase the cytotoxic effect of doxorubicin in breast cancer cells, thus making the cells more responsive to treatment leading to increased cell death through autophagy and apoptosis. Methods: In MDA-MB231 cells, MKP-1 was inhibited using sanguinarine or MKP-1 siRNA and this was compared to a known inducer of MKP-1, dexamethasone. MDA-MB231 cells were treated with doxorubicin alone or in combination with MKP-1 inhibitors or an inducer. Following treatment, cell death was determined by trypan blue and a caspase glo assay as well as with western blotting. Autophagy was determined by western blotting and flow cytometry. LC3 and p62 were used as markers of autophagy and caspase 3 and PARP as apoptosis markers. Likewise, the level of MKP-1 expression under conditions of MKP-1 induction, inhibition or silencing was evaluated by means of western blotting. C57BL6 tumour bearing mice was used to analyse apoptosis and autophagy in vivo under conditions of MKP-1 inhibition, using sanguinarine, together with doxorubicin treatment. Western blotting was used to determine levels of caspase 3, LC3, p62 and MKP-1 expression. Results and discussion: A concentration and time curve indicated that 5 μM doxorubicin reduced cell viability in the MDA-MB231 cells significantly after 24 hours of treatment. MKP-1 expression was significantly reduced with sanguinarine and MKP-1 siRNA. Furthermore, our results indicate a significant increase in apoptosis in MDA-MB231 cells when treated with doxorubicin, under conditions of MKP-1 inhibition or MKP-1 silencing. Also, an increase in autophagic activity was observed following treatment with doxorubicin in combination with sanguinarine. Whole excised tumours of C57BL6 mice also showed an increase in apoptosis and autophagy following treatment with sanguinarine in combination with doxorubicin. This indicates that the inhibition of MKP-1 with sanguinarine sensitized the MDA-MB231 cells and E0771 cell tumours to doxorubicin-induced-apoptosis through a mechanism involving autophagy. Conclusion: This is an encouraging finding that could hopefully be used in future studies to overcome doxorubicin-resistance in breast cancer cells overexpressing MKP-1. Targeting MKP-1 can have potential therapeutic benefits for breast cancer patients by making chemotherapy more effective. Sanguinarine thus has potential to be developed as a clinically relevant inhibitor of MKP-1 which could provide a novel avenue for therapeutic intervention in combination with chemotherapy in breast cancer patients. / AFRIKAANSE OPSOMMING: Inleiding: Kanker is 'n vinnig groeiende gesondheidsprobleem in Suid-Afrika, met borskanker as een van die vernaamste kankers wat vroue wêreldwyd raak. Daar is dus 'n behoefte aan nuwe terapeutiese opsies vir hierdie pasiënte en mitogeen-geaktiveerde proteïenkinase fosfatase-1 (MKP-1) is onlangs voorgestel as ‘n moontlike teiken. Verskeie studies toon dat mitogeen-geaktiveerde proteïenkinase fosfatases betrokke is by die ontwikkeling van kanker en ook belangrike rolspelers is in die reaksie van kanker op chemoterapie. Daarbenewens toon talle studies dat daar verhoogde MKP-1 uitdrukking in borskanker is, asook dat dit ‘n belangrike bemiddelaar is vir die weerstand wat borskanker teen chemoterapie bied. Ons het dus voorgestel dat die inhibisie van MKP-1 die sitotoksiese effek van doxorubicin op borskanker selle sal verhoog; sodoende sal die kanker selle beter reageer op behandeling en dit sal dus lei tot verhoogde seldood deur autofagie en apoptose. Metodes: MKP-1 is geïnhibeer met behulp van sanguinarine of MKP-1 siRNA in MDA-MB231 selle en dit is vergelyk met 'n bekende MKP-1 induseerder, dexamethasone. MDA-MB231 selle is met doxorubicin alleen behandel of in kombinasie met MKP-1 inhibeerders of ‘n induseerder. Seldood is bepaal deur middel van ‘n trypan blou en kaspase toetsingsmetode, asook met die westelike kladtegniek. Autofagie is bepaal deur westelike kladtegniek en vloeisitometrie. LC3 en p62 is gebruik as merkers van autofagie en kaspase 3 en PARP is as apoptose merkers gebruik. MKP-1 uitdrukking is geëvalueer deur middel van westelike kladtegniek. C57BL6 muise met kankeragtige gewasse is gebruik om apoptose en autofagie in vivo te ondersoek. MKP-1 is geïnhibeer met sanguinarine en die muise is behandel met ‘n kombinasie van sanguinarine en doxorubicin. Kaspase 3, LC3, p62 en MKP-1 uitdrukking is bepaal deur middel van die westelike kladtegniek. Resultate en bespreking: ‘n Konsentrasie en tyd kurwe het aangedui dat 5 μM doxorubicin die MDA-MB231 selle se lewensvatbaarheid aansienlik verminder het na 24 uur. MKP-1 uitdrukking is ook aansienlik verminder met sanguinarine en MKP-1 siRNA. Verder dui die resultate op 'n beduidende toename in apoptose in MDA-MB231 selle na behandeling met doxorubicin onder toestande van MKP-1 inhibisie. 'n Toename in autofagiese aktiwiteit is waargeneem na behandeling met doxorubicin en sanguinarine. Die kankeragtige gewasse van die C57BL6 muise toon ook 'n toename in apoptose en autofagie na behandeling met sanguinarine en doxorubicin. Hierdie resultate dui daarop dat die inhibisie van MKP-1 met sanguinarine die MDA-MB231 selle en E0771 sel gewasse gesensitiseer het tot doxorubicin-geïnduseerde apoptose deur middel van ‘n meganisme wat autofagie insluit. Gevolgtrekking: Hierdie bevinding kan hopelik in toekomstige studies gebruik word om doxorubicin weerstand te oorkom in borskanker selle waar MKP-1 verhoog is. Deur MKP-1 te teiken, kan dit lei tot potensiële terapeutiese voordele vir borskanker pasiënte en sodoende kan dit chemoterapie meer effektief maak. Sanguinarine het dus die potensiaal om ontwikkel te word as ‘n klinies relevante inhibeerder van MKP-1 wat sodoende kan dien as terapeutiese intervensie in kombinasie met chemoterapie vir borskanker pasiënte.

Breast -- Cancer -- Chemotherapy

Cancer -- Drug resistance

Theses -- Physiology

Dissertations -- Physiology

Development and assessment of in vitro tumour models for anti-cancer drug testing

Liu, Xinhui

January 2011

The study of the development of anti-cancer drugs and preclinical efficacy tests has until today encountered a major problem identified as lack of reliable in vitro tumour models which are able to reflect in vivo tumour conditions. These models provide a clear basis for understanding tumour development processes, assisting in the selection of agents from various chemicals and testing the efficacy of drugs. There are two important characteristics for an in vitro tumour model, i.e. tumour-like structure of cell aggregates, and the in vivo-like culture microenvironment. To meet these two requirements, an in vitro perfusion based three-dimensional tumour model was developed for the three dimensional culture of cancer cells and related anti-cancer drugs tests. In order to assess this model, DLD1 and NCI/ADR cells were cultured in four different models and compared their proliferation rate, cell viability, micro tumour formation and drug responses. In addition, the comparison of static and perfusion culture were done on monolayer and in 3D also. The cells in perfusion culture showed higher proliferation rates and significantly, higher cell viabilities after a 6-day culture compared to statically cultured cells, especially for the cells in the 3D culture. Microtumours (MTs) were formed from this model, which showed significant tumour-like morphological characteristics, a denser and highly stable structure, a higher cell viability, and varied drug responses compared with spheroids. The inhibition effect of paclitaxel and cisplatin, two common type anti-cancer drugs, were tested and a comparative study was carried out using conventional two-dimensional (2D) static culture, spheroids, and the developed 3D MTs model, as well as real human tumour tissues. The results showed that the cells in 2D culture were most greatly inhibited while human tumours showed the lowest drug responses. The efficacy of anti-cancer drugs, tested in conventional 2D static culture, was greatly amplified. Besides, the response of MTs to agents was much closer to that of human tumours, when the values of spheroids are relatively closer to the cells in 2D culture. It is further supported that MTs have more tumour-like characteristics than spheroids. When compared, the inhibition to proliferation of cells in static and perfusion culture showed significantly different drug responses except for the cells on the monolayer. The shown difference between static and perfusion culture can be due to the different culture environment, and further related to the different action mechanisms of anti-cancer agents. The perfusion culture provides a more homogenous and more physiological microenvironment for the in vitro tumour growth, and in vitro perfused 3D cancer model, developed in this thesis, proved valuable for the study of in vitro cancer and related anti-cancer drug tests.

616.994061

Evaluation of the antitumour activity of novel flavonoids on pre-clinical models of breast and ovarian cancer

Martínez Pérez, Carlos

January 2017

New drugs are needed for better cancer management. Clinical trials are currently underway to assess the use of flavonoids (natural polyphenols) as anticancer agents. Among them, myricetin has been shown to induce cell cycle arrest and apoptosis in pre-clinical cancer models. We hypothesised that myricetin-derived novel flavonoids designed to enhance this natural potential and improve on the drug-likeness limitations of myricetin might have increased potential for their application in the management of breast and ovarian cancer. The effect of a library of novel flavonoids was screened on 3 panels of breast and ovarian cancer cell lines, representing different molecular subtypes and phenotypes, to assess their potency. The second-generation bi-methoxylated analogue AO-1530-OMe (Oncamex) was identified as the most effective candidate in the library, with sub-micromolar concentrations exerting a strong antiproliferative effect across almost all models studied. Results suggested that changes in the hydroxylation profile, the addition of methoxylations and a decyl alkyl chain were some of the structure-activity relationships contributing to this improved efficacy. Plate assays showed 8 h treatment with Oncamex reduced cell viability and induced cytotoxicity and apoptosis, concomitant with caspase activation and PARP cleavage. Pre-incubation with an antioxidant partially blocked these effects, suggesting the possible involvement of ROS modulation in the mechanism of action of Oncamex. Fluorescence microscopy reported the quick and stable delivery of Oncamex to the mitochondria. Fluorescent probes showed that Oncamex can induce mitochondrial superoxide production at concentrations associated with its antiproliferative effects. Study of the electrochemical properties of Oncamex by cyclic voltammetry supported this. Differential gene expression analysis following a microarray experiment showed Oncamex induces changes in the expression of genes controlling cell cycle and apoptosis. Together with previous results, the findings from this analysis led to the postulation of a model for the mechanism of action of Oncamex: due to its enhanced reactivity and mitochondrial targeting, Oncamex can generate mitochondrial superoxide, leading to mitochondrial dysfunction, membrane permeabilisation and the activation of the JNK pathway and the transcription factor FOXO3, which together contribute to the induction of intrinsic apoptosis and the inhibition of proliferation. Further proliferation assays on cell culture models also reported enhanced effect of Oncamex when administered in combination with paclitaxel and TRAIL. These improved responses were observed in breast and ovarian cancer models, including cells lines characterised by their treatment-resistant phenotype. Cotreatment with Oncamex also improved the effect of tamoxifen on anti-oestrogen resistant LCC9 breast cancer cells. Results from preliminary in vivo studies in mice implanted with the MDA-MB-231 breast cancer xenograft were consistent with an antiproliferative effect of Oncamex (25mg/kg/day) in vivo, as treatment inhibited tumour growth and reduced the expression of the marker of proliferation Ki-67 without signs of systemic toxicity. Tissues from this experiment also allowed for preliminary in vivo validation of the proposed mechanism of action of Oncamex by immunohistochemistry. The in vivo cytostatic effect of Oncamex was confirmed in a second in vivo experiment, which also investigated the effect of Oncamex at higher doses or in combination with paclitaxel. In conclusion, the novel flavonoid Oncamex has shown a promising antiproliferative effect in pre-clinical models of breast and ovarian cancer, including models of treatment-resistant cancers. Preliminary in vivo studies have demonstrated a partial recapitulation of the effect of Oncamex. A mechanistic model has been proposed by which Oncamex induces intrinsic apoptosis through its redox reactivity and mitochondrial targeting. These results support the potential of this prototypic candidate, although possible work in the structure and formulation of this candidate and further study and validation of its mechanism of action is needed for its continued development as an anticancer agent.

616.99