Integration of cell-cell interactions and cell division by novel Dkk1 functions

Award Number
BB/V015362/1
Status / Stage
Active
Dates
9 August 2021 -
8 August 2024
Duration (calculated)
02 years 11 months
Funder(s)
BBSRC (UKRI)
Funding Amount
£630,054.00
Funder/Grant study page
BBSRC UKRI
Contracted Centre
King's College London
Principal Investigator
Professor Corinne Houart
PI Contact
corinne.houart@kcl.ac.uk
PI ORCID
0000-0002-2062-3964
WHO Catergories
Understanding Underlying Disease
Disease Type
Dementia (Unspecified)

CPEC Review Info
Reference ID727
ResearcherReside Team
Published07/07/2023

Data

Award NumberBB/V015362/1
Status / StageActive
Start Date20210809
End Date20240808
Duration (calculated) 02 years 11 months
Funder/Grant study pageBBSRC UKRI
Contracted CentreKing's College London
Funding Amount£630,054.00

Abstract

We have very recently found that the signalling protein Dkk1 acts on cell-cell interaction via a molecular interaction independent from its known action. We propose a research plan which will elucidate the molecular interactions by which Dkk1 directly impacts cell behaviour and cell division in vivo. The data from this research will be pertinent for several cancers, neurodegenerative- and cardiovascular disease, where upregulation of Dkk1 and loss of cell-cell contacts lie at the core of disease progression. Identifying interaction partners for Dkk1 in vivo is key to understanding the mechanistic details of how Dkk1 downregulates adhesion between cells. By identifying Fz-independent membrane receptors in complex with Dkk1, we will gain understanding of Dkk1-induced signalling events which locally modify cell-cell adhesion. We also propose to define these Dkk1-induced modifications at the molecular level by determining the contribution of specific myosin isoforms at these adhesive sites. Our discovery of an intracellular centrosome associated pool of Dkk1 raises questions regarding the nature and function of these complexes and how they relate to membrane localised Dkk1. Imaging by electron microscopy will give us detailed data on the cellular structure(s) that Dkk1 associates with, and how these and other cellular components change in response to a sustained increase in Dkk1 levels. This analysis will give valuable insight into the function of intracellular Dkk1 and the cellular structures that are involved in generating the loss of adhesion phenotype related to disease. Our finding that Dkk1 associates with the mitotic spindle puts it in a central position for control of mitotic progression. Our proposed experiments will determine the role of Dkk1 in this context and further our understanding of the consequences for timing and orientation of cell division when Dkk1 levels are elevated, which is of particular relevance to malignant disease.