The emergence of Sox and POU transcription factors predates the origins of animal stem cells

Ya Gao; Daisylyn Senna Tan; Mathias Girbig; Haoqing Hu; Xiaomin Zhou; Qianwen Xie; Shi Wing Yeung; Kin Shing Lee; Sik Yin Ho; Vlad Cojocaru; Jian Yan; Georg K.A. Hochberg; Alex de Mendoza; Ralf Jauch

doi:10.1038/s41467-024-54152-x

The emergence of Sox and POU transcription factors predates the origins of animal stem cells

Ya Gao, Daisylyn Senna Tan, Mathias Girbig, Haoqing Hu, Xiaomin Zhou, Qianwen Xie, Shi Wing Yeung, Kin Shing Lee, Sik Yin Ho, Vlad Cojocaru, Jian Yan, Georg K.A. Hochberg, Alex de Mendoza^*, Ralf Jauch^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

Stem cells are a hallmark of animal multicellularity. Sox and POU transcription factors are associated with stemness and were believed to be animal innovations, reported absent in their unicellular relatives. Here we describe unicellular Sox and POU factors. Choanoflagellate and filasterean Sox proteins have DNA-binding specificity similar to mammalian Sox2. Choanoflagellate—but not filasterean—Sox can replace Sox2 to reprogram mouse somatic cells into induced pluripotent stem cells (iPSCs) through interacting with the mouse POU member Oct4. In contrast, choanoflagellate POU has a distinct DNA-binding profile and cannot generate iPSCs. Ancestrally reconstructed Sox proteins indicate that iPSC formation capacity is pervasive among resurrected sequences, thus loss of Sox2-like properties fostered Sox family subfunctionalization. Our findings imply that the evolution of animal stem cells might have involved the exaptation of a pre-existing set of transcription factors, where pre-animal Sox was biochemically similar to extant Sox, whilst POU factors required evolutionary innovations.

Original language	English
Article number	9868
Journal	Nature Communications
Volume	15
Issue number	1
DOIs	https://doi.org/10.1038/s41467-024-54152-x
Publication status	Published - 14 Nov 2024

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© The Author(s) 2024.

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title = "The emergence of Sox and POU transcription factors predates the origins of animal stem cells",

abstract = "Stem cells are a hallmark of animal multicellularity. Sox and POU transcription factors are associated with stemness and were believed to be animal innovations, reported absent in their unicellular relatives. Here we describe unicellular Sox and POU factors. Choanoflagellate and filasterean Sox proteins have DNA-binding specificity similar to mammalian Sox2. Choanoflagellate—but not filasterean—Sox can replace Sox2 to reprogram mouse somatic cells into induced pluripotent stem cells (iPSCs) through interacting with the mouse POU member Oct4. In contrast, choanoflagellate POU has a distinct DNA-binding profile and cannot generate iPSCs. Ancestrally reconstructed Sox proteins indicate that iPSC formation capacity is pervasive among resurrected sequences, thus loss of Sox2-like properties fostered Sox family subfunctionalization. Our findings imply that the evolution of animal stem cells might have involved the exaptation of a pre-existing set of transcription factors, where pre-animal Sox was biochemically similar to extant Sox, whilst POU factors required evolutionary innovations.",

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AU - Gao, Ya

AU - Tan, Daisylyn Senna

AU - Girbig, Mathias

AU - Hu, Haoqing

AU - Zhou, Xiaomin

AU - Xie, Qianwen

AU - Yeung, Shi Wing

AU - Lee, Kin Shing

AU - Ho, Sik Yin

AU - Cojocaru, Vlad

AU - Yan, Jian

AU - Hochberg, Georg K.A.

AU - de Mendoza, Alex

AU - Jauch, Ralf

PY - 2024/11/14

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AB - Stem cells are a hallmark of animal multicellularity. Sox and POU transcription factors are associated with stemness and were believed to be animal innovations, reported absent in their unicellular relatives. Here we describe unicellular Sox and POU factors. Choanoflagellate and filasterean Sox proteins have DNA-binding specificity similar to mammalian Sox2. Choanoflagellate—but not filasterean—Sox can replace Sox2 to reprogram mouse somatic cells into induced pluripotent stem cells (iPSCs) through interacting with the mouse POU member Oct4. In contrast, choanoflagellate POU has a distinct DNA-binding profile and cannot generate iPSCs. Ancestrally reconstructed Sox proteins indicate that iPSC formation capacity is pervasive among resurrected sequences, thus loss of Sox2-like properties fostered Sox family subfunctionalization. Our findings imply that the evolution of animal stem cells might have involved the exaptation of a pre-existing set of transcription factors, where pre-animal Sox was biochemically similar to extant Sox, whilst POU factors required evolutionary innovations.

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The emergence of Sox and POU transcription factors predates the origins of animal stem cells

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