LAUSR

Introduction: Diabetes mellitus (DM) is the seventh leading cause of death in the US and diabetic kidney disease (DKD)is the cause of nearly 50% of individuals receiving dialysis. Kidney proximal tubule (PT) cells are sensitive to injury under diabetic conditions of high glucose. Maladaptive repair can cause fibrosis and loss of PT function contributing to end-stage renal disease. PT cell proliferation re-establishes the monolayer responsible for PT functionality. Preliminary lab findings showed increased abundance and nuclear localization of Hepatoma-derived growth factor (HDGF), known to regulate proliferation, in cells grown at low (<40%) confluency in high glucose supplemented growth media. This change associated with altered nuclear co-localization with β-catenin (ß-Cat), involved in renal fibrosis, suggesting crosstalk between both factors may be involved in PT cell responses in DKD. Hypothesis: Cell confluency and glucose concentrations regulate the spatial and absolute abundance/degradation of HDGF altering cell signaling pathways in PT cells. Methods: Cultured human kidney PT cells (HK-11 cell line) were grown to low and high confluency under normal (5mM) and high (25mM) glucose conditions. RNA was collected via column purification for analysis of cell signaling. RNASeq and bioinformatic analysis. revealed transcript abundances and respective statistical significances between normal and high glucose conditions grown to low confluency. MetaCore and STRING were utilized to examine fold change differences of the transcriptome and affected pathways. To determine regulation of protein abundance, HK-11 cells were cultured in normal glucose media to 80-90% confluency and treated with no agent (control), DMSO, MG132 (proteasome inhibitor), and chloroquine (lysosome inhibitor), and abundance of HDGF and β-Cat activation analyzed by immunoblot. Results: HDGF transcripts from conditions of normal and high glucose grown to low confluency were found in relatively equal abundance (q ≤ 1). Pathway analyses revealed genes associated with multiple pathways including nuclear signaling, ER stress, proliferation and ubiquitination exhibited differential transcript abundance at statistically significant values. Immunoblot analysis suggested that HDGF is degraded via the lysosome. Conclusions: HDGF regulation by diabetes-like high glucose does not occur at the level of transcription and but through lysosomal degradation. ß-Cat nuclear localization is increased under conditions of high glucose and low cellular confluency. To confirm HDGF degradation and ß-Cat activation, more replicates are needed for statistical analysis. Future studies will determine the role of β-cat activation on HDGF abundance and nuclear localization. NIH T35-DK072923, P20-GM103436, NIH P20 GM113226, P50 AA024337, P30 ES030283 This is the full abstract presented at the American Physiology Summit 2023 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.