PKD1 and PKD2 mRNA cis-inhibition drives polycystic kidney disease progression Article Swipe

PDF

Related Concepts

PKD1 Autosomal dominant polycystic kidney disease Polycystic kidney disease Untranslated region Biology Cyst Genetics Allele Mutant Kidney Cancer research Internal medicine Endocrinology Messenger RNA Medicine Gene Pathology

Ronak Lakhia , Harini Ramalingam , Chun-Mien Chang , Patricia Cobo-Stark , Laurence Biggers , Andrea Flaten , Jesus Alvarez , Tania Valencia , Darren P. Wallace , Edmund Lee , Vishal Patel ·

YOU? · · 2022 · Open Access · · DOI: https://doi.org/10.1101/2022.02.23.479396 · OA: W4213440835

Autosomal dominant polycystic kidney disease (ADPKD), among the most common human genetic conditions and a frequent etiology of kidney failure, is primarily caused by heterozygous PKD1 mutations. Kidney cyst formation ensues when the PKD1 dosage falls below a critical threshold. However, no framework exists to harness the remaining allele or reverse PKD1 decline. Here, we show that mRNAs produced by the noninactivated PKD1 allele are cis-repressed via their 3’-UTR miR-17 binding element. Eliminating this motif ( Pkd1 Δ17 ) improves mRNA stability, raises Polycystin-1 levels, and alleviates cyst growth in cellular, ex vivo , and mouse PKD models. Remarkably, Pkd2 is also autoinhibited via its 3’-UTR miR-17 motif, and Pkd2 Δ17 -induced Polycystin-2 derepression partly compensates and retards cyst growth in Pkd1 -mutant models. Moreover, acutely blocking Pkd1/2 cis-inhibition, including after cyst onset, attenuates murine PKD. Finally, PKD1 Δ17 or PKD2 Δ17 alleles revert cyst-pathogenic sequala in patient-derived primary ADPKD cultures. Thus, evading 3’-UTR cis-interference and enhancing PKD1/2 mRNA translation is a potentially mutation-agnostic ADPKD-arresting approach.