What question did this study set out to answer?

This study aims to understand the role of specific genes in transepithelial oxalate and bicarbonate transport in Drosophila Malpighian tubules.

May 14, 2026

Humanizing the Drosophila Malpighian Tubule (Renal Epithelium) to Study Transepithelial Oxalate and Bicarbonate Secretion

Key Points

This study aims to understand the role of specific genes in transepithelial oxalate and bicarbonate transport in Drosophila Malpighian tubules.
Drosophila Malpighian tubules are used as a model to measure renal calcium oxalate crystallization and membrane transport.
Gene-specific knockdown and knockout techniques, including CRISPR-Mediated Integration Cassette (CRIMIC) alleles, are applied to assess cellular functions.
Comparative analysis of knockdown effects on calcium oxalate crystallization and intracellular pH regulation is performed.
Knockdowns of Prestin, Neat, or NDAE1 in principal cells resulted in decreased calcium oxalate crystal formation.
NDAE1 knockdown in stellate cells increased calcium oxalate crystals, indicating modulation by transporters.
The study shows that bicarbonate and chloride secretion are vital for fluid secretion in the tubules.

Abstract

We previously showed that the Drosophila Malpighian tubule (MT) can model the formation of calcium oxalate (CaOx) kidney stones. Two epithelial cell types, stellate cells (SC) and principal cells (PC) comprise MTs, with each transporting different solutes from the hemolymph to MT lumen. Prestin, Neat and Ndae1 contribute to transepithelial ox2-, HCO 3 - transport and fluid secretion. Neat (2HCO 3 - /ox2- exchange) and NDAE1 (Na + ,2HCO 3 - /Cl - exchange) functionally combine to takeup hemolymph ox2-, can also facilitate HCO 3 - uptake. Prestin then secretes ox2- via Cl - / ox2-exchange to create luminal MT CaOx crystals, but it can also exchange Cl - /HCO 3 - . This study examines transepithelial ion secretion by Prestin (Slc26a6, apical), Neat (Slc26a1-like, basal) and Ndae1 (Slc4a8-like, basal). We use a functionally similar, simple genetic model (Drosophila Malpighian tubules, MT) to measure renal CaOx crystallization (NaOx feeding), membrane transport (pHi, fluorescent pH sensors) and fluid secretion (Ramsey assay) to: (1) compare cell-specific gene knockdown (KD) vs gene knockout, (2) quantify CaOx crystallization and intracellular pH (pHi) regulation by CO 2 /HCO 3 - , and (3) humanize these transporters by replacing them with human homologs. We hypothesize that humanizing individual transporters will restore MT physiology. Candidate transporter genes are tested for transepithelial ox2-and HCO 3 - secretion with gene-specific knockdown or knockout, using CRIMIC (CRISPR-Mediated Integration Cassette) alleles, in MTs due to comparable function to mammalian nephrons. Neat and NDAE1 work together to take-up hemolymph ox2- or HCO 3 - then Prestin secretes ox2- or HCO 3 - into the MT lumen. Prestin, Neat or NDAE1 knockdowns in principal cells decrease CaOx crystals. NDAE1 but not Neat knockdown in SC increases CaOx crystals like AQP (Drip, Prip)-knockdowns while either KD enhance HCO 3 - transport. Ndae1-SC-KD reduces fluid secretion like AQP-KD. Each CRIMIC allele must be physiologically compared to PC/SC-KDs because Ndae1-KO but not Neat-KO mirrors PC rather than SC function. Ndae1-SC-KD shows that HCO 3 - and Cl - secretion cause fluid secretion. Human homolog replacements are on-going. This abstract was presented at the American Physiology Summit 2026 and is only available in HTML format. There is no downloadable file or PDF version. The Physiology editorial board was not involved in the peer review process.

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