Discovery of novel regulators of aldehyde dehydrogenase isoenzymes

Ivanova, Yvelina Tsvetanova

30 May 2011

Indiana University-Purdue University Indianapolis (IUPUI) / Recent work has shown that specific ALDH isoenzymes can contribute to the underlying pathology of different diseases. Many ALDH isozymes are important in oxidizing reactive aldehydes resulting from lipid peroxidation, and, thus, help maintain cellular homeostasis. Increased expression and activity of ALDH isozymes are found in many human cancers and are often associated with poor prognosis. Therefore, the development of inhibitors of the different ALDH enzymes is of interest as means to treat some of these disease states. Here I describe the results of assays designed to characterize the site of interaction and the mode of inhibition for the unique compounds that function as inhibitors of aldehyde dehydrogenase 2 and determine their respective IC50 values with intent to develop structure-activity relationships for future development.

ALDH2

Characterization

High-throughput docking approach

Aldehyde dehydrogenase -- Inhibitors

Isoenzymes

Homeostasis

Cancer cells -- Growth -- Regulation

Pathology, Cellular -- Research

An inhibitor of the mitotic kinase, MPS1, is selective towards pancreatic cancer cells

Bansal, Ruchi

January 2014

Indiana University-Purdue University Indianapolis (IUPUI). / The abysmal five year pancreatic cancer survival rate of less than 6% highlights the need for new treatments for this deadly malignancy. Cytotoxic drugs normally target rapidly dividing cancer cells but unfortunately often target stem cells resulting in toxicity. This warrants the development of compounds that selectively target tumor cells. An inhibitor of the mitotic kinase, MPS1, which has been shown to be more selective towards cancer cells than non-tumorigenic cells, shows promise but its effects on stem cells has not been investigated. MPS1 is an essential component of the Spindle Assembly Checkpoint and is proposed to be up-regulated in cancer cells to maintain chromosomal segregation errors within survivable limits. Inhibition of MPS1 kinase causes cancer cell death accompanied by massive aneuploidy. Our studies demonstrate that human adipose stem cells (ASCs) and can tolerate higher levels of a small molecule MPS1 inhibitor than pancreatic cancer cells. In contrast to PANC-1 cancer cells, ASCs and telomerase-immortalized pancreatic ductal epithelial cells did not exhibit elevated chromosome mis-segregation after treatment with the MPS1 inhibitor for 72hrs. In contrast, PANC-1 pancreatic cancer cells exhibited a large increase in chromosomal mis-segregation under similar conditions. Furthermore, growth of ASCs was minimally affected post treatment whereas PANC-1 cells were severely growth impaired suggesting a favorable therapeutic index. Our studies, demonstrate that MPS1 inhibition is selective towards pancreatic cancer cells and that stem cells are less affected in vitro. These data suggest MPS1 inhibition should be further investigated as a new treatment approach in pancreatic cancer.

CIN70

MPS1 kinase inhibitor

pancreatic cancer

Antineoplastic agents

Cancer cells

Cancer -- Treatment

Focal adhesion kinase

Cancer cells -- Growth -- Regulation

Pancreas -- Diseases

Cancer cells -- Growth

Stem cells

Antioncogenes

Enzyme inhibitors

The oncogenic properties of Amot80 in mammary epithelia

Ranahan, William P.

12 March 2014

Indiana University-Purdue University Indianapolis (IUPUI) / While breast cancer is the second most commonly diagnosed cancer worldwide, its causes and natural history are not well defined. The female mammary organ is unique in that it does not reach full maturity until the lactation cycle following pregnancy. This cycle entails extensive growth and reorganization of the primitive epithelial ductal network. Following lactation, these same epithelial cells undergo an equally extensive program of apoptosis and involution. The mammary gland's sensitivity to pro-growth and pro-apoptotic signals may partly explain its proclivity to develop cancers. For epithelial cells to become transformed they must lose intracellular organization known as polarity as differentiated epithelial tissues are refractory to aberrant growth. One essential component of epithelial to mesenchymal transition is the intrinsic capacity of cells to repurpose polarity constituents to promote growth. Recently, a novel mechanism of organ size control has been shown to repurpose the apical junctional associated protein Yap into the nucleus where it functions as a transcriptional coactivator promoting growth and dedifferentiation. The focus of my work has been on a family of adaptor proteins termed Amots that have been shown to scaffold Yap and inhibit growth signaling. Specifically, I have shown that the 80KDa form of Amot, termed Amot80, acts as a dominant negative to the other Amot proteins to promote cell growth while reducing cell differentiation. Amot80 was found to promote the prolonged activation of MAPK signaling. Further, Amot80 expression was also found to enhance the transcriptional activity of Yap. This effect likely underlies the ability of Amot80 to drive disorganized overgrowth of MCF10A cells grown in Matrigel̈™. Overall, these data suggest a mechanism whereby the balance of Amot proteins controls the equilibrium between growth and differentiation within mammary epithelial tissues.

Epithelium -- Differentiation

Epithelium -- Growth

Epithelial cells

Breast -- Cancer

Cancer cells -- Growth -- Regulation

Polarity (Biology) -- Research

Mammals -- Development

Cellular signal transduction

Cancer cells -- Research

Transcription factors

Tumor suppressor proteins

Oncogenes -- Research

Cancer -- Endocrine aspects

Pathology, Molecular

The inhibition of mammary epithelial cell growth by the long isoform of Angiomotin

Adler, Jacob J.

07 July 2014

Indiana University-Purdue University Indianapolis (IUPUI) / Mammary ductal epithelial cell growth is controlled by microenvironmental signals in serum under both normal physiological settings and during breast cancer progression. Importantly, the effects of several of these microenvironmental signals are mediated by the activities of the tumor suppressor protein kinases of the Hippo pathway. Canonically, Hippo protein kinases inhibit cellular growth through the phosphorylation and inactivation of the oncogenic transcriptional co-activator Yes-Associated Protein (YAP). This study defines an alternative mechanism whereby Hippo protein kinases induce growth arrest via the phosphorylation of the long isoform of Angiomotin (Amot130). Specifically, serum starvation is found to activate the Hippo protein kinase, Large Tumor Suppressor (LATS), which phosphorylates the adapter protein Amot130 at serine-175. Importantly, wild-type Amot130 potently inhibits mammary epithelial cell growth, unlike the Amot130 serine-175 to alanine mutant, which cannot be phosphorylated at this residue. The growth-arrested phenotype of Amot130 is likely a result of its mechanistic response to LATS signaling. Specifically, LATS activity promotes the association of Amot130 with the ubiquitin ligase Atrophin-1 Interacting Protein 4 (AIP4). As a consequence, the Amot130-AIP4 complex amplifies LATS tumor suppressive signaling by stabilizing LATS protein steady state levels via preventing AIP4-targeted degradation of LATS. Additionally, AIP4 binding to Amot130 leads to the ubiquitination and stabilization of Amot130. In turn, the Amot130-AIP4 complex signals the ubiquitination and degradation of YAP. This inhibition of YAP activity by Amot130 requires both AIP4 and the ability of Amot130 to be phosphorylated by LATS. Together, these findings significantly modify the current view that the phosphorylation of YAP by Hippo protein kinases is sufficient for YAP inhibition and cellular growth arrest. Based upon these results, the inhibition of cellular growth in the absence of serum more accurately involves the stabilization of Amot130 and LATS, which together inhibit YAP activity and mammary epithelial cell growth.

Breast -- Cancer -- Pathophysiology

Protein-tyrosine kinase -- Research

Ligases -- Research

Epithelial cells -- Growth -- Inhibitors

Ubiquitin -- Research

Proteins -- Research

Cancer -- Molecular aspects -- Research

Cellular signal transduction -- Research

Cancer cells -- Growth -- Regulation

Pathology, Molecular

Transcription factors -- Research

Cell migration -- Inhibitors -- Research

Proto-oncogenes -- Research