Pathogenetic mechanisms of muscle-specific ribosomes in dilated cardiomyopathy

Michael R. Murphy; Mythily Ganapathi; Esther R. Rotlevi; Teresa M. Lee; Joshua M. Fisher; Megha V. Patel; Parul Jayakar; Amanda Buchanan; Alyssa L. Rippert; Rebecca C. Ahrens-Nicklas; Divya Nair; Shalini S. Nayak; Aakanksha Anand; Anju Shukla; Rajesh K. Soni; Yue Yin; Feiyue Yang; Enrique J. Garcia; Muredach P. Reilly; Wendy K. Chung; Xuebing Wu

doi:10.1038/s44161-025-00761-8

Pathogenetic mechanisms of muscle-specific ribosomes in dilated cardiomyopathy

Michael R. Murphy^*
, Mythily Ganapathi
, Esther R. Rotlevi
, Teresa M. Lee
, Joshua M. Fisher
, Megha V. Patel
, Parul Jayakar
, Amanda Buchanan
, Alyssa L. Rippert
, Rebecca C. Ahrens-Nicklas
, Divya Nair
, Shalini S. Nayak
, Aakanksha Anand
, Anju Shukla
, Rajesh K. Soni
, Yue Yin
, Feiyue Yang
, Enrique J. Garcia
, Muredach P. Reilly
, Wendy K. Chung

Xuebing Wu^*

^*Corresponding author for this work

Department of Medical Genetics, Kasturba Medical College, Manipal

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

Abstract

The heart uses a muscle-specific ribosome in cardiomyocytes, where the ribosomal protein RPL3 is replaced by its paralog RPL3L. Rare biallelic RPL3L mutations cause fatal neonatal dilated cardiomyopathy, yet the mechanisms that link genotype to heart failure are unclear. Despite the recessive inheritance pattern in humans, Rpl3l knockout mice show no overt cardiac phenotype, probably because of compensatory RPL3 upregulation through unknown mechanisms. Here we report four additional cases and propose a unifying pathogenetic model by integrating human genetics, patient tissues and isogenic cell models. Affected individuals typically carry one of two recurrent hotspot missense variants paired with a private allele. Whereas non-hotspot variants phenocopy knockout and allow RPL3 compensation, hotspot variants induce nucleolar protein aggregation, disrupt rRNA processing and block compensation by preserving the role of RPL3L in repressing RPL3 via unproductive splicing. These findings establish combined loss-of-function and gain-of-function mechanisms for RPL3L-associated cardiomyopathy and inform genetic screening, diagnosis and therapeutic development.

Original language	English
Pages (from-to)	51-66
Number of pages	16
Journal	Nature Cardiovascular Research
Volume	5
Issue number	1
DOIs	https://doi.org/10.1038/s44161-025-00761-8
Publication status	Published - 01-2026

All Science Journal Classification (ASJC) codes

Medicine (miscellaneous)
Biochemistry, Genetics and Molecular Biology (miscellaneous)
Cardiology and Cardiovascular Medicine
Cell Biology

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Murphy, M. R., Ganapathi, M., Rotlevi, E. R., Lee, T. M., Fisher, J. M., Patel, M. V., Jayakar, P., Buchanan, A., Rippert, A. L., Ahrens-Nicklas, R. C., Nair, D., Nayak, S. S., Anand, A., Shukla, A., Soni, R. K., Yin, Y., Yang, F., Garcia, E. J., Reilly, M. P., ... Wu, X. (2026). Pathogenetic mechanisms of muscle-specific ribosomes in dilated cardiomyopathy. Nature Cardiovascular Research, 5(1), 51-66. https://doi.org/10.1038/s44161-025-00761-8

@article{ba50d33c8cc646919c1ff6a4879d4402,

title = "Pathogenetic mechanisms of muscle-specific ribosomes in dilated cardiomyopathy",

abstract = "The heart uses a muscle-specific ribosome in cardiomyocytes, where the ribosomal protein RPL3 is replaced by its paralog RPL3L. Rare biallelic RPL3L mutations cause fatal neonatal dilated cardiomyopathy, yet the mechanisms that link genotype to heart failure are unclear. Despite the recessive inheritance pattern in humans, Rpl3l knockout mice show no overt cardiac phenotype, probably because of compensatory RPL3 upregulation through unknown mechanisms. Here we report four additional cases and propose a unifying pathogenetic model by integrating human genetics, patient tissues and isogenic cell models. Affected individuals typically carry one of two recurrent hotspot missense variants paired with a private allele. Whereas non-hotspot variants phenocopy knockout and allow RPL3 compensation, hotspot variants induce nucleolar protein aggregation, disrupt rRNA processing and block compensation by preserving the role of RPL3L in repressing RPL3 via unproductive splicing. These findings establish combined loss-of-function and gain-of-function mechanisms for RPL3L-associated cardiomyopathy and inform genetic screening, diagnosis and therapeutic development.",

author = "Murphy, \{Michael R.\} and Mythily Ganapathi and Rotlevi, \{Esther R.\} and Lee, \{Teresa M.\} and Fisher, \{Joshua M.\} and Patel, \{Megha V.\} and Parul Jayakar and Amanda Buchanan and Rippert, \{Alyssa L.\} and Ahrens-Nicklas, \{Rebecca C.\} and Divya Nair and Nayak, \{Shalini S.\} and Aakanksha Anand and Anju Shukla and Soni, \{Rajesh K.\} and Yue Yin and Feiyue Yang and Garcia, \{Enrique J.\} and Reilly, \{Muredach P.\} and Chung, \{Wendy K.\} and Xuebing Wu",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2026.",

year = "2026",

month = jan,

doi = "10.1038/s44161-025-00761-8",

language = "English",

volume = "5",

pages = "51--66",

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Murphy, MR, Ganapathi, M, Rotlevi, ER, Lee, TM, Fisher, JM, Patel, MV, Jayakar, P, Buchanan, A, Rippert, AL, Ahrens-Nicklas, RC, Nair, D, Nayak, SS, Anand, A, Shukla, A, Soni, RK, Yin, Y, Yang, F, Garcia, EJ, Reilly, MP, Chung, WK & Wu, X 2026, 'Pathogenetic mechanisms of muscle-specific ribosomes in dilated cardiomyopathy', Nature Cardiovascular Research, vol. 5, no. 1, pp. 51-66. https://doi.org/10.1038/s44161-025-00761-8

TY - JOUR

T1 - Pathogenetic mechanisms of muscle-specific ribosomes in dilated cardiomyopathy

AU - Murphy, Michael R.

AU - Ganapathi, Mythily

AU - Rotlevi, Esther R.

AU - Lee, Teresa M.

AU - Fisher, Joshua M.

AU - Patel, Megha V.

AU - Jayakar, Parul

AU - Buchanan, Amanda

AU - Rippert, Alyssa L.

AU - Ahrens-Nicklas, Rebecca C.

AU - Nair, Divya

AU - Nayak, Shalini S.

AU - Anand, Aakanksha

AU - Shukla, Anju

AU - Soni, Rajesh K.

AU - Yin, Yue

AU - Yang, Feiyue

AU - Garcia, Enrique J.

AU - Reilly, Muredach P.

AU - Chung, Wendy K.

AU - Wu, Xuebing

PY - 2026/1

Y1 - 2026/1

N2 - The heart uses a muscle-specific ribosome in cardiomyocytes, where the ribosomal protein RPL3 is replaced by its paralog RPL3L. Rare biallelic RPL3L mutations cause fatal neonatal dilated cardiomyopathy, yet the mechanisms that link genotype to heart failure are unclear. Despite the recessive inheritance pattern in humans, Rpl3l knockout mice show no overt cardiac phenotype, probably because of compensatory RPL3 upregulation through unknown mechanisms. Here we report four additional cases and propose a unifying pathogenetic model by integrating human genetics, patient tissues and isogenic cell models. Affected individuals typically carry one of two recurrent hotspot missense variants paired with a private allele. Whereas non-hotspot variants phenocopy knockout and allow RPL3 compensation, hotspot variants induce nucleolar protein aggregation, disrupt rRNA processing and block compensation by preserving the role of RPL3L in repressing RPL3 via unproductive splicing. These findings establish combined loss-of-function and gain-of-function mechanisms for RPL3L-associated cardiomyopathy and inform genetic screening, diagnosis and therapeutic development.

AB - The heart uses a muscle-specific ribosome in cardiomyocytes, where the ribosomal protein RPL3 is replaced by its paralog RPL3L. Rare biallelic RPL3L mutations cause fatal neonatal dilated cardiomyopathy, yet the mechanisms that link genotype to heart failure are unclear. Despite the recessive inheritance pattern in humans, Rpl3l knockout mice show no overt cardiac phenotype, probably because of compensatory RPL3 upregulation through unknown mechanisms. Here we report four additional cases and propose a unifying pathogenetic model by integrating human genetics, patient tissues and isogenic cell models. Affected individuals typically carry one of two recurrent hotspot missense variants paired with a private allele. Whereas non-hotspot variants phenocopy knockout and allow RPL3 compensation, hotspot variants induce nucleolar protein aggregation, disrupt rRNA processing and block compensation by preserving the role of RPL3L in repressing RPL3 via unproductive splicing. These findings establish combined loss-of-function and gain-of-function mechanisms for RPL3L-associated cardiomyopathy and inform genetic screening, diagnosis and therapeutic development.

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U2 - 10.1038/s44161-025-00761-8

DO - 10.1038/s44161-025-00761-8

M3 - Article

AN - SCOPUS:105026881020

SN - 2731-0590

VL - 5

SP - 51

EP - 66

JO - Nature Cardiovascular Research

JF - Nature Cardiovascular Research

IS - 1

ER -

Pathogenetic mechanisms of muscle-specific ribosomes in dilated cardiomyopathy

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