Die Suchmaschine für Unternehmensdaten in Europa
UK-Förderung (542.604 £): Mechanistische Grundlagen für CENP-32 vermittelte Regulation der Zellteilung Ukri01.01.2023 Forschung und Innovation im Vereinigten Königreich, Großbritannien
Auf einen Blick
Text
Mechanistische Grundlagen für CENP-32 vermittelte Regulation der Zellteilung
| Zusammenfassung | In the human body, trillions of cells undergo division every day. During each division, the genetic information which is in the form of chromosomes need to be equally and identically distributed to the newly formed daughter cells. Distribution of chromosomes is achieved by an elaborate machinery called the mitotic spindle. In humans, the mitotic spindle is formed by a filamentous network called microtubules which are organised by an organelle called centrosome. During cell division cells possess two centrosomes that move away from each other and orchestrate microtubule network to establish the mitotic spindle. The centrosomes form the opposite ends of the mitotic spindle where microtubule networks converge and are called spindle poles. Physical attachment of centrosomes to the spindle poles is crucial for distributing chromosomes and centrosomes accurately to the daughter cells. Defective distribution of chromosomes and/or centrosomes are associated with several human health disorders such as cancer, microcephaly and primordial dwarfism. Hence understanding how centrosomes are attached to the spindle poles is important to better understand the related medical conditions and to find a possible cure. The proposed work focuses on an essential human protein called CENP-32, which when removed from cells results in the detachment of centrosomes from spindle poles affecting the integrity of the mitotic spindle. CENP-32 mutations have also been found in patients with neurodevelopmental disorders such as microcephaly, seizures and developmental delays. The mitotic spindle lacking centrosomes at the poles is not capable of distributing the chromosomes accurately and as a consequence will result in daughter cells with inappropriate chromosome and/or centrosome numbers, a condition often associated with cancer and developmental disorders. Proteins exert their function by interacting with and/or modifying biomolecules including proteins and nucleic acids (RNA and DNA). Proteins acquire their function through their three-dimensional structure which provides them their ability to interact with/modify other biomolecules. To understand how CENP-32, a likely RNA binding protein, ensures the physical attachment of centrosomes to spindle poles, we propose: (1) to study the structure of CENP-32 and identify the RNA modifications it makes, (2) to identify the proteins/RNA that CENP-32 interacts with, (3) to delineate how RNA modifying activity of CENP-32 facilitate centrosome-spindle pole attachment, and (4) assess how CENP-32 patient mutations affect CENP-32 activity and function. The outcome of this research will advance our understanding of how centrosomes help build an intact mitotic spindle essential for generating daughter cells with correct genetic information. CENP-32 is a protein essential for cell survival, hence the outcome of the proposed research will also pave way for exploring the possibility of blocking CENP-32 function in cancer cells and rectifying CENP-32 defect in patients with associated neurodevelopmental disorders. |
| Kategorie | Research Grant |
| Referenz | MR/X001245/1 |
| Status | Active |
| Laufzeit von | 01.01.2023 |
| Laufzeit bis | 31.12.2025 |
| Fördersumme | 542.604,00 £ |
| Quelle | https://gtr.ukri.org/projects?ref=MR%2FX001245%2F1 |
Beteiligte Organisationen
| University of Edinburgh |
Die Bekanntmachung bezieht sich auf einen vergangenen Zeitpunkt, und spiegelt nicht notwendigerweise den heutigen Stand wider. Der aktuelle Stand wird auf folgender Seite wiedergegeben: University OF Edinburgh CHARITY, Edinburgh, Großbritannien.
