Somatic mutations of CADM1 in aldosterone-producing adenomas and gap junction-dependent regulation of aldosterone production

Wu, Xiaozhen; Azizan, Elena; Goodchild, Emily; Garg, Swati; Hagiyama, Man; Cabrera, Claudia; Fernandes-Rosa, Fábio Luiz; Boulkroun, Sheerazed; Kuan, Jyn Ling; Tiang, Zenia; David, Alessia; Murakami, Masanori; Mein, Charles A.; Wozniak, Eva; Zhao, Wanfeng; Marker, Alison; Buß, Folma; Saleeb, Rebecca S.; Salsbury, Jackie; Tezuka, Yuta; Satoh, Fumitoshi; Oki, Kenji; Udager, Aaron M.; Cohen, Debbie L.; Wachtel, Heather; King, Peter; Drake, William M; Gurnell, Mark; Ceral, Jiří; Ryška, Aleš; Mustangin, Muaatamarulain; Wong, Yin Ping; Tan, Geok Chin; Solař, Miroslav; Reincke, Martín; Rainey, William E.; Foo, Roger; Takaoka, Yutaka; Murray, Sandra A.; Zennaro, Maria-Christina; Beuschlein, Felix; Ito, Akihiko; Mj, Brown

doi:10.1038/s41588-023-01403-0

Cited by 26 publications

(12 citation statements)

References 93 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…-Cardiovascular risk and Diabetes : both of these disease families have different risk factors, including environmental, genetic and genetic-environment interaction (GxE). For example, Type 1 vs Type 2 diabetes, or specific genetic risk factors [6], [15].…”

Section: Discussionmentioning

confidence: 99%

Automated Annotation of Disease Subtypes

Ofer,

Linial

2023

Preprint

View full text Add to dashboard Cite

Background Distinguishing diseases into distinct subtypes is crucial for study, effective treatment, and the discovery of potential cures. The Open Targets Platform integrates biomedical, genetic, and biochemical datasets with the goal of empowering disease ontologies and gene targets. However, many disease annotations remain incomplete, necessitating laborious expert medical input. This is particularly painful for rare and orphan diseases, where resources are limited. Results We present a machine learning approach to identifying diseases with potential subtypes, using the approximately 23,000 diseases documented in Open Targets. We derive and describe novel features for predicting diseases with subtypes, using direct evidence. Machine learning models were applied to analyze feature importance and evaluate predictive performance for discovering known subtypes. Our model achieves a high (89.1%) ROCAUC. We integrated pre-trained deep learning language models and showed their benefits. Furthermore, we identify 515 disease candidates predicted to possess previously unannotated subtypes. Conclusions Our models can partition diseases into distinct subtypes. This methodology enables a robust, scalable approach for improving knowledge-based annotations and a comprehensive assessment of disease ontology tiers. Our candidates are attractive targets for further study and personalized medicine, potentially aiding in the unveiling of new therapeutic indications for sought-after targets.

show abstract

Section: Discussionmentioning

confidence: 99%

Automated Annotation of Disease Subtypes

Ofer,

Linial

2023

Preprint

View full text Add to dashboard Cite

show abstract

“…Following the recovery in 2022, we believed that the ideal time had come to reconvene. Major progress had been made during the past years, and key publications have addressed new genetic events [2][3][4][5][6][7], diagnosis [8,9] pathophysiology of aldosterone excess [10][11][12][13][14][15], imaging [16], histopathologic classifications [17], and treatment [18] but unresolved and controversial issues remain. In October 2022, PIPA 7 took place in the usual location at Castle Nymphenburg in Munich.…”

Section: The Pipa 7 Conference In Munich 2022mentioning

confidence: 99%

Progress in Primary Aldosteronism 7: No better time to meet!

Reincke,

Rainey,

Williams

2023

Exp Clin Endocrinol Diabetes

View full text Add to dashboard Cite

“…In particular, exome sequencing has contributed to uncovering several genes (including KCNJ5, ATP1A1, ATP2B3, CACNA1D, CAC-NA1H, CTNNB1, GNAQ, GNA11, CLCN2, CADM1, and SLC30A1), the specific mutations of which are associated with autonomous aldosterone production. [9][10][11][12][13][14][15][16][17] Recently, single-cell RNA sequencing technology, which examines the cellular composition and features, and functions of tumor cells, has been increasingly applied to study the occurrence and development of diseases at the cellular level. 18 However, reports on the use of single-cell RNA sequencing or single-nucleus RNA sequencing (snRNA-seq) in studying the adrenal tissue, such as the identification of aldosterone-producing cell clusters at the single-cell level in the examination of normal human adrenal tissue, 19 a thorough investigation of immune cells in the analysis of APA tissue, 20 and the clustering analysis to identify the localization of diseasespecific genes in peritumoral adrenal cortex tissues, 21 are limited.…”

mentioning

confidence: 99%

“…In particular, exome sequencing has contributed to uncovering several genes (including KCNJ5 , ATP1A1 , ATP2B3 , CACNA1D , CACNA1H , CTNNB1 , GNAQ , GNA11 , CLCN2 , CADM1 , and SLC30A1 ), the specific mutations of which are associated with autonomous aldosterone production. 9–17…”

mentioning

confidence: 99%

Single-Nucleus Analysis Reveals Tumor Heterogeneity of Aldosterone-Producing Adenoma

Murakami,

Hara,

Ikeda

et al. 2024

Hypertension

Self Cite

View full text Add to dashboard Cite

BACKGROUND: Recent advances in omics techniques have allowed detailed genetic characterization of aldosterone-producing adenoma (APA). The pathogenesis of APA is characterized by tumorigenesis-associated aldosterone synthesis. The pathophysiological intricacies of APAs have not yet been elucidated at the level of individual cells. Therefore, a single-cell level analysis is speculated to be valuable in studying the differentiation process of APA. METHODS: We conducted single-nucleus RNA sequencing of APAs with KCNJ5 mutation and nonfunctional adenomas obtained from 3 and 2 patients, respectively. RESULTS: The single-nucleus RNA sequencing revealed the intratumoral heterogeneity of APA and identified cell populations consisting of a shared cluster of nonfunctional adenoma and APA. In addition, we extracted 2 cell fates in APA and obtained a cell population specialized in aldosterone synthesis. Genes related to ribosomes and neurodegenerative diseases were upregulated in 1 of these fates, whereas those related to the regulation of glycolysis were upregulated in the other fate. Furthermore, the total RNA reads in the nucleus were higher in hormonally activated clusters, indicating a marked activation of transcription per cell. CONCLUSIONS: The single-nucleus RNA sequencing revealed intratumoral heterogeneity of APA with KCNJ5 mutation. The observation of 2 cell fates in KCNJ5 -mutated APAs provides the postulation that a heterogeneous process of cellular differentiation was implicated in the pathophysiological mechanisms underlying APA tumors.

show abstract

Somatic mutations of CADM1 in aldosterone-producing adenomas and gap junction-dependent regulation of aldosterone production

Cited by 26 publications

References 93 publications

Automated Annotation of Disease Subtypes

Automated Annotation of Disease Subtypes

Progress in Primary Aldosteronism 7: No better time to meet!

Single-Nucleus Analysis Reveals Tumor Heterogeneity of Aldosterone-Producing Adenoma

Contact Info

Product

Resources

About