Literature DB >> 35581939

Tubular-specific CDK12 knockout causes a defect in urine concentration due to premature cleavage of the slc12a1 gene.

Bin Wang1, Yao Wang2, Yi Wen3, Yi-Lin Zhang1, Wei-Jie Ni1, Tao-Tao Tang1, Jing-Yuan Cao1, Qing Yin1, Wei Jiang1, Di Yin1, Zuo-Lin Li1, Lin-Li Lv1, Bi-Cheng Liu4.   

Abstract

Cyclin-dependent kinase 12 (CDK12) plays a critical role in regulating gene transcription. CDK12 inhibition is a potential anticancer therapeutic strategy. However, several clinical trials have shown that CDK inhibitors might cause renal dysfunction and electrolyte disorders. CDK12 is abundant in renal tubular epithelial cells (RTECs), but the exact role of CDK12 in renal physiology remains unclear. Genetic knockout of CDK12 in mouse RTECs causes polydipsia, polyuria, and hydronephrosis. This phenotype is caused by defects in water reabsorption that are the result of reduced Na-K-2Cl cotransporter 2 (NKCC2) levels in the kidney. In addition, CKD12 knockout causes an increase in Slc12a1 (which encodes NKCC2) intronic polyadenylation events, which results in Slc12a1 truncated transcript production and NKCC2 downregulation. These findings provide novel insight into CDK12 being necessary for maintaining renal homeostasis by regulating NKCC2 transcription, which explains the critical water and electrolyte disturbance that occurs during the application of CDK12 inhibitors for cancer treatment. Therefore, there are safety concerns about the clinical use of these new anticancer drugs.
Copyright © 2022 The Authors. Published by Elsevier Inc. All rights reserved.

Entities:  

Keywords:  CDK12 inhibitor; Na-K-2Cl cotransporter 2; RNA polymerase II; cyclin-dependent kinase 12; urine concentration

Mesh:

Substances:

Year:  2022        PMID: 35581939      PMCID: PMC9552909          DOI: 10.1016/j.ymthe.2022.05.012

Source DB:  PubMed          Journal:  Mol Ther        ISSN: 1525-0016            Impact factor:   12.910


  48 in total

1.  AKAP220 manages apical actin networks that coordinate aquaporin-2 location and renal water reabsorption.

Authors:  Jennifer L Whiting; Leah Ogier; Katherine A Forbush; Paula Bucko; Janani Gopalan; Ole-Morten Seternes; Lorene K Langeberg; John D Scott
Journal:  Proc Natl Acad Sci U S A       Date:  2016-07-11       Impact factor: 11.205

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Authors:  Bi-Cheng Liu; Tao-Tao Tang; Lin-Li Lv; Hui-Yao Lan
Journal:  Kidney Int       Date:  2018-01-17       Impact factor: 10.612

3.  ILDR1 is important for paracellular water transport and urine concentration mechanism.

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Journal:  Proc Natl Acad Sci U S A       Date:  2017-05-01       Impact factor: 11.205

4.  Structure-Based Design of Selective Noncovalent CDK12 Inhibitors.

Authors:  Jeffrey W Johannes; Christopher R Denz; Nancy Su; Allan Wu; Anna C Impastato; Scott Mlynarski; Jeffrey G Varnes; D Bryan Prince; Justin Cidado; Ning Gao; Malcolm Haddrick; Natalie H Jones; Shaobin Li; Xiuwei Li; Yang Liu; Toan B Nguyen; Nichole O'Connell; Emma Rivers; Daniel W Robbins; Ronald Tomlinson; Tieguang Yao; Xiahui Zhu; Andrew D Ferguson; Michelle L Lamb; John I Manchester; Sylvie Guichard
Journal:  ChemMedChem       Date:  2018-01-26       Impact factor: 3.466

5.  The Cyclin K/Cdk12 complex maintains genomic stability via regulation of expression of DNA damage response genes.

Authors:  Dalibor Blazek; Jiri Kohoutek; Koen Bartholomeeusen; Eric Johansen; Petra Hulinkova; Zeping Luo; Peter Cimermancic; Jernej Ule; B Matija Peterlin
Journal:  Genes Dev       Date:  2011-10-15       Impact factor: 11.361

6.  Diabetes insipidus in mice with a mutation in aquaporin-2.

Authors:  David J Lloyd; Frank Wesley Hall; Lisa M Tarantino; Nicholas Gekakis
Journal:  PLoS Genet       Date:  2005-08-19       Impact factor: 5.917

7.  Absolute quantification of somatic DNA alterations in human cancer.

Authors:  Scott L Carter; Kristian Cibulskis; Elena Helman; Aaron McKenna; Hui Shen; Travis Zack; Peter W Laird; Robert C Onofrio; Wendy Winckler; Barbara A Weir; Rameen Beroukhim; David Pellman; Douglas A Levine; Eric S Lander; Matthew Meyerson; Gad Getz
Journal:  Nat Biotechnol       Date:  2012-05       Impact factor: 54.908

8.  CDK12 controls G1/S progression by regulating RNAPII processivity at core DNA replication genes.

Authors:  Anil Paul Chirackal Manavalan; Kveta Pilarova; Michael Kluge; Koen Bartholomeeusen; Michal Rajecky; Jan Oppelt; Prashant Khirsariya; Kamil Paruch; Lumir Krejci; Caroline C Friedel; Dalibor Blazek
Journal:  EMBO Rep       Date:  2019-07-25       Impact factor: 8.807

9.  Employing Macrophage-Derived Microvesicle for Kidney-Targeted Delivery of Dexamethasone: An Efficient Therapeutic Strategy against Renal Inflammation and Fibrosis.

Authors:  Tao-Tao Tang; Lin-Li Lv; Bin Wang; Jing-Yuan Cao; Ye Feng; Zuo-Lin Li; Min Wu; Feng-Mei Wang; Yi Wen; Le-Ting Zhou; Hai-Feng Ni; Ping-Sheng Chen; Ning Gu; Steven D Crowley; Bi-Cheng Liu
Journal:  Theranostics       Date:  2019-07-09       Impact factor: 11.556

10.  Genome-wide profiling of genetic synthetic lethality identifies CDK12 as a novel determinant of PARP1/2 inhibitor sensitivity.

Authors:  Ilirjana Bajrami; Jessica R Frankum; Asha Konde; Rowan E Miller; Farah L Rehman; Rachel Brough; James Campbell; David Sims; Rumana Rafiq; Sean Hooper; Lina Chen; Iwanka Kozarewa; Ioannis Assiotis; Kerry Fenwick; Rachael Natrajan; Christopher J Lord; Alan Ashworth
Journal:  Cancer Res       Date:  2013-11-15       Impact factor: 12.701
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