Plk1 Spatial Synchronization in Prostate Epithelial Cells During Mitosis

Abstract

Cell division is a process whereby genetic material is duplicated, separated, and packaged to yield two daughter cells. This process relies on spatial and temporal synchronization of protein kinase activity at the mitotic spindle, a macromolecular machine that segregates chromosomes towards the daughter cells. A major generator of this machine and organizer of mitotic signaling is the centrosome. Interphase cells have a single centrosome that nucleates microtubules for cellular material to transport on. When cells decide to divide into two, they duplicate their genetic material and their centrosomes to make two mitotic spindle poles, which function to nucleate microtubules to capture duplicated genetic material and distribute it equally to each daughter cell. In primary prostate cancer cells, we find that a large proportion of cells (~30%) contain supernumerary centrosomes (>3 centrosomes/cell). We also identified in these samples that contained supernumerary centrosomes elevated amounts of the mitotic kinase Plk1, which is known to regulate centrosome function, number, and mitotic progression. Thus, we propose a testable model whose defects in centrosome number and function can lead to genomic instability, causing a normal prostate epithelial cell genome to behave like a cancer genome. To test this, we will first identify the mechanism of centrosome amplification and subsequently determine its impact on genome stability using primary prostate cancer cells grown in a three-dimensional (3-D) culture. The advantage of 3-D culture systems is that, unlike commonly used monolayer cultures, 3-D cultures recapitulate many features of prostate acini in vivo providing a context in which to study the functional consequences of supernumerary centrosomes and cancer genes such as Plk1. Optimization of imaging strategies for 3-D cultures may eventually allow for high-throughput screening of experimental therapeutics applied to ex vivo patient samples, with subsequent tailoring of treatments specific to that individual. These studies may also identify cancer-associated genes and provide early diagnostic tools to predict cancer development. In conclusion, our studies will address the overall hypothesis that deregulation of centrosome-based signaling events leads to genomic instability and subsequent metastasis in prostate cancer.

Document Details

Document Type

DoD Grant Award

Publication Date

Oct 29, 2018

Source ID

W81XWH1710241

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