1.
A novel SATB1 protein isoform with different biophysical properties.
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Zelenka, T
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Papamatheakis, DA
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Tzerpos, P
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Panagopoulos, G
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Tsolis, KC
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Papadakis, VM
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Mariatos Metaxas, D
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Papadogkonas, G
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Mores, E
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Kapsetaki, M
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Papamatheakis, J
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Stanek, D
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Spilianakis, C
Abstract:
Intra-thymic T cell development is coordinated by the regulatory actions of SATB1 genome organizer. In this report, we show that SATB1 is involved in the regulation of transcription and splicing, both of which displayed deregulation in Satb1 knockout murine thymocytes. More importantly, we characterized a novel SATB1 protein isoform and described its distinct biophysical behavior, implicating potential functional differences compared to the commonly studied isoform. SATB1 utilized its prion-like domains to transition through liquid-like states to aggregated structures. This behavior was dependent on protein concentration as well as phosphorylation and interaction with nuclear RNA. Notably, the long SATB1 isoform was more prone to aggregate following phase separation. Thus, the tight regulation of SATB1 isoforms expression levels alongside with protein post-translational modifications, are imperative for SATB1's mode of action in T cell development. Our data indicate that deregulation of these processes may also be linked to disorders such as cancer.
2.
SATB1 undergoes isoform-specific phase transitions in T cells.
Abstract:
Intracellular space is demarcated into functional membraneless organelles and nuclear bodies via the process of phase separation. Phase transitions are involved in many functions linked to such bodies as well as in gene expression regulation and other cellular processes. In this work we describe how the genome organizer SATB1 utilizes its prion-like domains to undergo phase transitions. We have identified two SATB1 isoforms with distinct biophysical behavior and showed how phosphorylation and interaction with nuclear RNA, impact their phase transitions. Moreover, we show that SATB1 is associated with transcription and splicing, both of which evinced deregulation in Satb1 knockout mice. Thus, the tight regulation of different SATB1 isoforms levels and their post-translational modifications are imperative for SATB1’s physiological roles in T cell development while their deregulation may be linked to disorders such as cancer.