Dmrt2 and Hmx2 direct intercalated cell diversity in the mammalian kidney through antagonistic and supporting regulatory processes

Intercalated cells (ICs) in the mammalian kidney regulate circulatory pH through IC subtype restricted actions of bicarbonate transcporters: pH is elevated by Slc4a1 restricted to type A-ICs (A-ICs) and depressed by Slc26a4 in type B-IC (B-ICs). nonA-nonB-ICs (nA/nB-ICs) also produce Slc26a4 though their function is unclear. Though both nephron and ureteric progenitor lineages generate A-ICs, the former also generates nA/nB-ICs and the latter B-ICs. Lineage and subtype restricted transporter gene expression in the mouse and human kidney is preceded by expression of the transcriptional regulators Dmrt2/DMRT2 in A-ICs, and either, or both Hmx2/HMX2 and Hmx3/HMX3 in B- and nA/nB ICs. CRISPR/CAS9-directed removal of Dmrt2 and the linked Hmx2/Hmx3 genes resulted in IC-subtype switching. A-ICs adopted an Hmx2+/Slc26a4+ B-IC cell fate on Dmrt2 removal while B-ICs initiated a Dmrt2+/Slc4a1+ A-IC program on Hmx2/Hmx3 removal. Triple knockout of Dmrt2, Hmx2, and Hmx3 resulted in hybrid ICs expressing both Slc4a1 and Slc26a4. Thus, restricted expression of these regulators is essential for specifying IC subtypes. These data support a model in which mutually repressive interactions between Dmrt2 and Hmx2/3 establish distinct IC-identities and activity of these factors supports gene regulatory programs specific to each IC sub-type. Overall design: To understand the role of Dmrt2, Hmx2, and Hmx3 in regulation of development of intercalated cell subtypes, we generated Dmrt2 knockout (KO) and Hmx3; Hmx2 knockout mice to look at gene expression. Whole embryonic day 18.5 knockout and control kidneys were sequenced from 1) Dmrt2 KO (n=3), 2) Hmx3; Hmx2 KO (n=6), and 3) Dmrt2; Hmx3; Hmx2 KO (n=3) samples as well as control littermates (n= matched for each KO condition).