RAD23B acquires a copper metalloadaptor function in amphibian-to-reptile evolution to increase metabolism and regulate genomic integrity

Tong Xiao; Dan He; Danqian Liu; Shang Jia; Qingyi Chen; Daniel Silverman; Neilabjo Maitra; Alan Y. Huang; Aidan Pezacki; Trisha T. Nguyen; Guodong Rao; Rachel Tillage; Kelly Deng; David Weinshenker; R. David Britt; Mark J.S. Kelly; Yang Dan; Christopher J. Chang

doi:10.1016/j.molcel.2025.08.024

RAD23B acquires a copper metalloadaptor function in amphibian-to-reptile evolution to increase metabolism and regulate genomic integrity

Tong Xiao
, Dan He
, Danqian Liu
, Shang Jia
, Qingyi Chen
, Daniel Silverman
, Neilabjo Maitra
, Alan Y. Huang
, Aidan Pezacki
, Trisha T. Nguyen
, Guodong Rao
, Rachel Tillage
, Kelly Deng
, David Weinshenker
, R. David Britt
, Mark J.S. Kelly
, Yang Dan
, Christopher J. Chang

Chemistry

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

Abstract

Increasing brain complexity is a major step in the evolution of species. Here, we show that, in the transition from amphibians to reptiles, the DNA repair protein RAD23B acquires a metalloadaptor function that allows it to serve as a central hub for both metabolism and protection of genomic integrity. More specifically, RAD23B gains an allosteric H274/H323 copper-binding site to enable the transfer of copper from the universal copper transporter 1 (CTR1) uptake protein to all known copper metallochaperone pathways, while simultaneously making its canonical functions in DNA repair copper dependent. This layer of nutrient regulation allows organisms to withstand elevated levels of potentially toxic copper while augmenting metabolism in cells with high energetic needs across both physiology and disease, including neurons in the locus coeruleus, a key brain structure that regulates sleep, and cancer cells.

Original language	English (US)
Pages (from-to)	3443-3459.e11
Journal	Molecular Cell
Volume	85
Issue number	18
DOIs	https://doi.org/10.1016/j.molcel.2025.08.024
State	Published - Sep 18 2025

All Science Journal Classification (ASJC) codes

Molecular Biology
Cell Biology

Keywords

Amniota evolution
CTR1/SLC31A1
Rad23b
metalloadaptor
metalloallostery
mitochondrial metabolism
sleep and wake behavior
transition metal signaling

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10.1016/j.molcel.2025.08.024

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Xiao, T., He, D., Liu, D., Jia, S., Chen, Q., Silverman, D., Maitra, N., Huang, A. Y., Pezacki, A., Nguyen, T. T., Rao, G., Tillage, R., Deng, K., Weinshenker, D., Britt, R. D., Kelly, M. J. S., Dan, Y., & Chang, C. J. (2025). RAD23B acquires a copper metalloadaptor function in amphibian-to-reptile evolution to increase metabolism and regulate genomic integrity. Molecular Cell, 85(18), 3443-3459.e11. https://doi.org/10.1016/j.molcel.2025.08.024

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title = "RAD23B acquires a copper metalloadaptor function in amphibian-to-reptile evolution to increase metabolism and regulate genomic integrity",

abstract = "Increasing brain complexity is a major step in the evolution of species. Here, we show that, in the transition from amphibians to reptiles, the DNA repair protein RAD23B acquires a metalloadaptor function that allows it to serve as a central hub for both metabolism and protection of genomic integrity. More specifically, RAD23B gains an allosteric H274/H323 copper-binding site to enable the transfer of copper from the universal copper transporter 1 (CTR1) uptake protein to all known copper metallochaperone pathways, while simultaneously making its canonical functions in DNA repair copper dependent. This layer of nutrient regulation allows organisms to withstand elevated levels of potentially toxic copper while augmenting metabolism in cells with high energetic needs across both physiology and disease, including neurons in the locus coeruleus, a key brain structure that regulates sleep, and cancer cells.",

keywords = "Amniota evolution, CTR1/SLC31A1, Rad23b, metalloadaptor, metalloallostery, mitochondrial metabolism, sleep and wake behavior, transition metal signaling",

author = "Tong Xiao and Dan He and Danqian Liu and Shang Jia and Qingyi Chen and Daniel Silverman and Neilabjo Maitra and Huang, \{Alan Y.\} and Aidan Pezacki and Nguyen, \{Trisha T.\} and Guodong Rao and Rachel Tillage and Kelly Deng and David Weinshenker and Britt, \{R. David\} and Kelly, \{Mark J.S.\} and Yang Dan and Chang, \{Christopher J.\}",

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year = "2025",

month = sep,

day = "18",

doi = "10.1016/j.molcel.2025.08.024",

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Xiao, T, He, D, Liu, D, Jia, S, Chen, Q, Silverman, D, Maitra, N, Huang, AY, Pezacki, A, Nguyen, TT, Rao, G, Tillage, R, Deng, K, Weinshenker, D, Britt, RD, Kelly, MJS, Dan, Y & Chang, CJ 2025, 'RAD23B acquires a copper metalloadaptor function in amphibian-to-reptile evolution to increase metabolism and regulate genomic integrity', Molecular Cell, vol. 85, no. 18, pp. 3443-3459.e11. https://doi.org/10.1016/j.molcel.2025.08.024

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T1 - RAD23B acquires a copper metalloadaptor function in amphibian-to-reptile evolution to increase metabolism and regulate genomic integrity

AU - Xiao, Tong

AU - He, Dan

AU - Liu, Danqian

AU - Jia, Shang

AU - Chen, Qingyi

AU - Silverman, Daniel

AU - Maitra, Neilabjo

AU - Huang, Alan Y.

AU - Pezacki, Aidan

AU - Nguyen, Trisha T.

AU - Rao, Guodong

AU - Tillage, Rachel

AU - Deng, Kelly

AU - Weinshenker, David

AU - Britt, R. David

AU - Kelly, Mark J.S.

AU - Dan, Yang

AU - Chang, Christopher J.

PY - 2025/9/18

Y1 - 2025/9/18

N2 - Increasing brain complexity is a major step in the evolution of species. Here, we show that, in the transition from amphibians to reptiles, the DNA repair protein RAD23B acquires a metalloadaptor function that allows it to serve as a central hub for both metabolism and protection of genomic integrity. More specifically, RAD23B gains an allosteric H274/H323 copper-binding site to enable the transfer of copper from the universal copper transporter 1 (CTR1) uptake protein to all known copper metallochaperone pathways, while simultaneously making its canonical functions in DNA repair copper dependent. This layer of nutrient regulation allows organisms to withstand elevated levels of potentially toxic copper while augmenting metabolism in cells with high energetic needs across both physiology and disease, including neurons in the locus coeruleus, a key brain structure that regulates sleep, and cancer cells.

AB - Increasing brain complexity is a major step in the evolution of species. Here, we show that, in the transition from amphibians to reptiles, the DNA repair protein RAD23B acquires a metalloadaptor function that allows it to serve as a central hub for both metabolism and protection of genomic integrity. More specifically, RAD23B gains an allosteric H274/H323 copper-binding site to enable the transfer of copper from the universal copper transporter 1 (CTR1) uptake protein to all known copper metallochaperone pathways, while simultaneously making its canonical functions in DNA repair copper dependent. This layer of nutrient regulation allows organisms to withstand elevated levels of potentially toxic copper while augmenting metabolism in cells with high energetic needs across both physiology and disease, including neurons in the locus coeruleus, a key brain structure that regulates sleep, and cancer cells.

KW - Amniota evolution

KW - CTR1/SLC31A1

KW - Rad23b

KW - metalloadaptor

KW - metalloallostery

KW - mitochondrial metabolism

KW - sleep and wake behavior

KW - transition metal signaling

UR - https://www.scopus.com/pages/publications/105015777507

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DO - 10.1016/j.molcel.2025.08.024

M3 - Article

C2 - 40972527

AN - SCOPUS:105015777507

SN - 1097-2765

VL - 85

SP - 3443-3459.e11

JO - Molecular Cell

JF - Molecular Cell

IS - 18

ER -

RAD23B acquires a copper metalloadaptor function in amphibian-to-reptile evolution to increase metabolism and regulate genomic integrity

Abstract

All Science Journal Classification (ASJC) codes

Keywords

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