Regulation and function of the Rho GTPase mediated signaling pathways in metastasis and lenticular differentiation

Mitchell, Dianne Courtenay

17 September 2007

Modulation of the actin-based cytoskeleton and transcription factor regulation are merely two essential functions in a wide array of cellular activities that the Rho family of small GTPases is responsible for mediating. Aberrations in, or loss of, Rho GTPase signaling has been found to lead to multiple pathologies, including both metastatic progression and lenticular differentiation leading to cataractogenesis. This study has examined the transcriptional regulation of the metastasis suppressor, KiSS-1. Although the mechanism by which KiSS-1 modulates an anti-metastatic effect is not entirely known, it is known that KiSS-1 mediates stress fiber formation, increased adhesion and reduced migratory and invasive properties through modulation of the Rho family of small GTPases. The loss of KiSS-1 that commonly occurs during metastatic progression, leads to a loss of proper Rho GTPase regulation. This study has examined how KiSS-1 is regulated in two tissue types, breast and skin, and how the loss of AP-2(alpha) and DRIP-130, respectively, leads to the progression of breast cancer and melanoma. In addition, this study has also looked at the importance of Rac1 expression and function in the lens epithelium. Activation of Rac1 and its downstream effector, SRF, have been shown to be key regulators in lens cell differentiation, possibly leading to lens opacification via its transcriptional control of the structural crystallins within the lens. The results of this dissertation research have made significant strides in understanding the nature of the anti-metastatic effects registered by the novel KiSS-1 peptide and its cognate GPCR. Additionally, it has shed light on the Rho family regulation of lens epithelial cell differentiation, indicating the elaborate involvement of Rac1 in mediating lens fiber development. In all, this research has determined previously unknown roles of small molecule GTPases in both the progression of metastasis, as well as in normal and abnormal lens cell differentiation.

Rho GTPase

metastasis

differentiation

The putative role of matrix metalloproteinase 13 and oncostatin M in the establishment of bone metastases

Mancini, Stephanie Sarah Jane

11 1900

Breast cancer has a high propensity to metastasize to bone. While the genetic and epigenetic changes associated with metastatic breast cancer progression are being identified, the changes that drive metastatic progression are poorly understood. Proteases, and in particular matrix metalloproteinases (MMPs), have been shown to play a pivotal role in certain aspects of tumor metastasis by modifying the affected microenvironment. Bone matrix-depositing mouse MC3T3 osteoblasts were co-cultured with metastatic human MDA-MB-23 1 (MDA23 1) cells or the bone-homing MDA-MB 231-1 833/TR (1 833/TR) variant in an effort to identify novel, osteoclast-independent, changes to the tumor/bone microenvironment. Co-culture-induced changes in the complete “protease and inhibitor” expression profile in the osteoblasts and the tumor cells were then determined using targeted murine and human specific microarray chips (CLIP-CHIP TM ). This analysis revealed an increase in the RNA expression of collagenase-3 (MMP 13) in the co-cultured osteoblasts that was confirmed by qPCR. Further, Western blotting indicated increased MIvIP13 protein secretion into the bone matrixltumor microenvironment by the co-cultured MC3T3 cells. The elevation in osteoblast-produced MMP13 was observed when the co- cultured tumor cells were in direct contact or separated by filters. Additionally, the elevation was also induced by conditioned medium derived from separate MDA23 1 or 1 833/TR cultures, which indicates that a soluble factor produced by the tumor cells is capable of inducing MMP 13. One soluble factor that appears to be produced by 1 833iTR cultures is oncostatin M. Oncostatin M is an interleukin-6 family cytokine that is known to upregulate MMP13 synthesis and secretion during chondrogenesis. Genome-wide Affymetrix® analysis revealed, and qPCR analysis confirmed, that oncostatin M receptor-specific subunit RNA was also significantly upregulated in co-cultured osteoblasts. Therefore, breast tumor cells may be capable of initiating protein degradative changes in the bone microenvironment that are independent of the much studied osteolytic degradation initiated by osteoclast activation.

Breast cancer

Bone metastasis

Regulation and function of the Rho GTPase mediated signaling pathways in metastasis and lenticular differentiation

Mitchell, Dianne Courtenay

17 September 2007

Modulation of the actin-based cytoskeleton and transcription factor regulation are merely two essential functions in a wide array of cellular activities that the Rho family of small GTPases is responsible for mediating. Aberrations in, or loss of, Rho GTPase signaling has been found to lead to multiple pathologies, including both metastatic progression and lenticular differentiation leading to cataractogenesis. This study has examined the transcriptional regulation of the metastasis suppressor, KiSS-1. Although the mechanism by which KiSS-1 modulates an anti-metastatic effect is not entirely known, it is known that KiSS-1 mediates stress fiber formation, increased adhesion and reduced migratory and invasive properties through modulation of the Rho family of small GTPases. The loss of KiSS-1 that commonly occurs during metastatic progression, leads to a loss of proper Rho GTPase regulation. This study has examined how KiSS-1 is regulated in two tissue types, breast and skin, and how the loss of AP-2(alpha) and DRIP-130, respectively, leads to the progression of breast cancer and melanoma. In addition, this study has also looked at the importance of Rac1 expression and function in the lens epithelium. Activation of Rac1 and its downstream effector, SRF, have been shown to be key regulators in lens cell differentiation, possibly leading to lens opacification via its transcriptional control of the structural crystallins within the lens. The results of this dissertation research have made significant strides in understanding the nature of the anti-metastatic effects registered by the novel KiSS-1 peptide and its cognate GPCR. Additionally, it has shed light on the Rho family regulation of lens epithelial cell differentiation, indicating the elaborate involvement of Rac1 in mediating lens fiber development. In all, this research has determined previously unknown roles of small molecule GTPases in both the progression of metastasis, as well as in normal and abnormal lens cell differentiation.

Rho GTPase

metastasis

differentiation

Matrix metalloproteinase 2 in the Dunning prostate cancer moderl : a novel upregulation in metastasis /

Tennant, Thelma Ruth.

January 2003

Thesis (Ph. D.)--University of Chicago, Committee on Cancer Biology, December 2003. / Includes bibliographical references. Also available on the Internet.

Prostate Metalloproteinases. Metastasis.

Identification and characterization of a candidate prostate cancer metastasis-suppressor gene on human chromosome 12 /

Jaeger, Erich B.

January 2003

Thesis (Ph. D.)--University of Chicago, Committee on Genetics, August 2003. / Includes bibliographical references. Also available on the Internet.

Role of c-Jun N-terminal kinase (JNK) in mediating mammary cancer cell migration and metastasis

Mitra, Shreya

16 October 2012

The c-Jun N-terminal kinases (JNKs) are MAPK family members and are activated by stress, growth factors and cytokines. They are encoded by three separate genes (jnk 1, 2, and 3), spliced alternately creating 10 isoforms. JNK signaling promotes both cell death and cell survival in a stimuli and tissue specic manner and is also implicated in tumorigenesis. Using the Polyoma Virus Middle T Antigen (PyVMT) transgenic mouse model where jnk2 was either expressed or deleted, we found that the PyVMTjnk2-/- tumors expressed higher Epidermal Growth Factor Receptor Substrate 8 (EPS8) mRNA and protein. EPS8 regulates EGFR signaling from Ras to Rac and EGFR tracking via Rab5 and RN-Tre. EPS8 is a prime candidate for connecting the EGFR signaling to actin cytoskeleton remodeling, thus mediating cell migration, a critical step in metastasis. In migration assays, PyVMTjnk2+/+ cells migrated ve fold more than the PyVMTjnk2-/- cells. Re-expression of JNK2[alpha] in the PyVMTjnk2-/- cells rescued this phenotype. Expression of shRNA EPS8 in the PyVMTjnk2-/- cell increased migration in vitro. EPS8 localization at dorsal rues and internalization of EGF-EGFR complexes coincided with JNK2 expression. Expression of shEPS8 in the PyVMTjnk2-/- cells increased EGF internalization suggesting that in absence of JNK2, EPS8 participates in Rab5-RN-Tre complex that inhibits EGFR internalization. Finally, we report that in absence of JNK2, EPS8 protein stability is greatly increased, suggesting that JNK2 is essential for endosomal sorting and degradation of EGFR associated cargo, of which EPS8 is a critical part. In contrast, silencing JNK1 (p46) in 4T1.2 mammary tumor cells, consistently enhanced cell invasion and tumor growth. Tumors derived from orthotopic injection of the 4T1.2shJNK1 expressing cells into the mammary fat pad reached target volume signicantly earlier than non-silencing vector expressing tumors. When injected intravenously, signicantly higher lung metastasis was observed in the 4T1.2shJNK1 group. The more aggressive behavior of 4T1.2shJNK1 tumors was associated with an increase in CCR5 and pAkt as detected by microarray analysis. Taken together, our data suggest that JNK1 suppresses the expression of proteins associated with tumor growth and invasive phenotype, contributing to tumor progression. / text

Protein kinases

Metastasis--Etiology

The prognostic significance of lymphatic and blood vessel invasion, angiogenesis and occult nodal metastasis in breast carcinoma

Lee, Kai-chung, Arthur., 李啓聰.

January 1995

published_or_final_version / Medicine / Master / Doctor of Medicine

Metastasis.

Breast - Cancer.

Neovascularization.

The putative role of matrix metalloproteinase 13 and oncostatin M in the establishment of bone metastases

Mancini, Stephanie Sarah Jane

11 1900

Breast cancer has a high propensity to metastasize to bone. While the genetic and epigenetic changes associated with metastatic breast cancer progression are being identified, the changes that drive metastatic progression are poorly understood. Proteases, and in particular matrix metalloproteinases (MMPs), have been shown to play a pivotal role in certain aspects of tumor metastasis by modifying the affected microenvironment. Bone matrix-depositing mouse MC3T3 osteoblasts were co-cultured with metastatic human MDA-MB-23 1 (MDA23 1) cells or the bone-homing MDA-MB 231-1 833/TR (1 833/TR) variant in an effort to identify novel, osteoclast-independent, changes to the tumor/bone microenvironment. Co-culture-induced changes in the complete “protease and inhibitor” expression profile in the osteoblasts and the tumor cells were then determined using targeted murine and human specific microarray chips (CLIP-CHIP TM ). This analysis revealed an increase in the RNA expression of collagenase-3 (MMP 13) in the co-cultured osteoblasts that was confirmed by qPCR. Further, Western blotting indicated increased MIvIP13 protein secretion into the bone matrixltumor microenvironment by the co-cultured MC3T3 cells. The elevation in osteoblast-produced MMP13 was observed when the co- cultured tumor cells were in direct contact or separated by filters. Additionally, the elevation was also induced by conditioned medium derived from separate MDA23 1 or 1 833/TR cultures, which indicates that a soluble factor produced by the tumor cells is capable of inducing MMP 13. One soluble factor that appears to be produced by 1 833iTR cultures is oncostatin M. Oncostatin M is an interleukin-6 family cytokine that is known to upregulate MMP13 synthesis and secretion during chondrogenesis. Genome-wide Affymetrix® analysis revealed, and qPCR analysis confirmed, that oncostatin M receptor-specific subunit RNA was also significantly upregulated in co-cultured osteoblasts. Therefore, breast tumor cells may be capable of initiating protein degradative changes in the bone microenvironment that are independent of the much studied osteolytic degradation initiated by osteoclast activation.

Breast cancer

Bone metastasis

Tumor-specific Expression of Versican G3 Domain Promotes Breast Cancer Cell Invasion and Bone Metastasis

Du, Weidong

11 December 2012

Increased local tumor tissue expression of versican in breast cancer patients is predictive of relapse and has a negative impact on survival rates. It is recognized that bone is a common anatomic site of breast cancer metastasis. The C-terminal G3 domain of versican influences local and systemic tumor invasiveness in pre-clinical murine models. However, the mechanism(s) by which G3 influences breast tumor growth and metastasis is not well characterized. We exogenously expressed a G3 construct in mouse breast cancer cell line 66c14, and found that G3 expression enhanced breast cancer cell proliferation and migration, and spontaneous metastasis to bone in an orthotopic model by upregulating the EGFR-mediated signaling pathway. Possessing anti-apoptotic and drug resistant properties, overexpression of versican was accompanied by selective sensitization to several chemotherapeutic agents. The dual roles of G3 in modulating breast cancer cell resistance to chemotherapeutic agents may, in part, explain breast cancer cell resistance to chemotherapy and EGFR therapy. The apoptotic effects of chemotherapeutics depend upon the activation and balance of down stream signals in the EGFR pathway. New knowledge gained by our experiments includes the understanding that GSK-3β (S9P) appears to function as a key check-point in this balance. In addition, versican G3 enhanced breast cancer cell self-renewal in vitro and in vivo. Versican was expressed at high levels in breast cancer mammosphere cells, which contained a high percentage of SP cells. Reduction of versican’s functionality through anti-versican shRNA or knocking out the EGF-like motifs using G3ΔEGF reduced the effect of versican on enhancing mammosphere and colony formation. Versican promoted breast cancer cell self-renew appears to play a role in enhanced chemotherapeutic drug resistance (including Docetaxel, Doxorubicin, and Epirubicin), which relates partly to its upregulated expression of EGFR signaling. Versican enhances breast cancer bone metastasis not only by enhancing tumor cell mobility, invasion, and survival in bone tissues, but also through mechanisms inhibiting osteoblast cell growth and differentiation, affording favorable microenvironments for tumor metastasis.

Versican

Invasion

Metastasis

0307

Transcriptional regulation of the p9Ka gene in metastatic and non-metastatic rat mammary epithelial cells

Chen, Dongsheng

January 1997

No description available.

572.8

Tumour metastasis