[Truncated abstract] Breast cancer is the cause of significant suffering and death in our community. It is now estimated that the risk of developing breast cancer for an Australian woman before the age of 85 is 1 in 8, with this risk rising for unknown reasons. While mortality rates from breast cancer are falling due to increased awareness and early detection, few new treatments have been developed from an advanced understanding of the molecular basis of the disease. From decades of scientific research it is clear that estrogen (E2) has a large role to play in breast cancer. However, the basic mechanism behind E2 action in breast cancer remains unclear. E2 plays a fundamental role in breast cancer cell proliferation and is highly expressed in breast cancers, thus, it is important to understand both E2 and its receptor, the estrogen receptor (ER). The ER is a member of the nuclear receptor (NR) superfamily. The NR superfamily consists of a large group of proteins which regulate a large number of homeostatic proteins together with regulator proteins termed coregulators and corepressors. SRA (steroid receptor RNA activator) is the only known RNA coactivator and augments transactivation by NRs. SRA has been demonstrated to play an important role in mediating E2 action (Lanz et al., 1999; Lanz et al., 2003) and its expression is aberrant in many human breast tumors, suggesting a potential role in breast tumorigenesis (Murphy et al., 2000). Despite evidence that an alternative splice variant of SRA exists as a protein (Chooniedass-Kothari et al., 2004), it has been conclusively shown that SRA can function as an RNA transcript to coactivate NR transcription (Lanz et al., 1999; Lanz et al., 2002; Lanz et al., 2003). The precise mechanism by which SRA augments ER activity remains unknown. However, it is currently hypothesized that SRA acts as an RNA scaffold for other coregulators at the transcription initiation site. Several SRA stem loops have been identified as important for SRA function, including structure (STR) 1, 5 and 7 (Lanz et al., 2002; Zhao et al., 2007). Previously, I sought to identify SRA-binding proteins using a specific stem-loop structure of SRA (STR7) that was identified as both important for its coactivator function (Lanz et al., 2002) and also as a target for proteins from breast cancer cell extracts (Hatchell, 2002). From a yeast E. Hatchell Abstract iii III hybrid screen using STR7 as bait, I identified a novel protein which was named SLIRP (Patent Number: WO/2007/009194): SRA stem-Loop Interacting RNA-binding Protein (Hatchell, 2002; Hatchell et al., 2006). '...' This thesis demonstrates that SLIRP modulates NR transactivation, provides mechanistic insight into interactions between SRA, SRC-1, HSP-60 and NCoR and suggests that SLIRP may regulate mitochondrial function. These studies contribute significantly to the growing field of NR biology, and contribute more specifically to the elucidation of estrogen action in breast cancer. Furthermore, it lays a strong and exciting foundation for further studies to evaluate SLIRP as a biomarker and potential therapeutic target in hormone dependent cancers.
Identifer | oai:union.ndltd.org:ADTP/222313 |
Date | January 2008 |
Creators | Hatchell, Esme Claire |
Publisher | University of Western Australia. School of Medicine and Pharmacology |
Source Sets | Australiasian Digital Theses Program |
Language | English |
Detected Language | English |
Rights | Copyright Esme Claire Hatchell, http://www.itpo.uwa.edu.au/UWA-Computer-And-Software-Use-Regulations.html |
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