Sox9‐independent Control of Intestinal Paneth Cell Differentiation and Function

Abstract

The genetic and signaling mechanisms controlling the generation and function of differentiated cell types are of continued interest. The intestinal Paneth cell (PC) is a post‐mitotic and dedicated secretory cell type with reported functions in supporting intestinal stem cell (ISC) maintenance in the crypt stem cell niche, and in secreting antimicrobial peptides to protect the crypt from potentially pathogenic luminal microbiota. Previous studies have reported a near‐complete loss of PCs (as defined by morphological and marker‐based criteria) in epithelium where the transcription factor Sox9 is genetically ablated, leading to the proposition that Sox9 is required for PC differentiation. Currently, however, the mechanisms through which Sox9 controls PC differentiation are not known. We have found evidence in Sox9 knockout (KO) small intestine (SI) that cells at the crypt base frequently express PC‐markers such as Lysozyme (Lyz) and Cryptdin, exhibit apical granules, and are post‐mitotic, all of which are features indicative of PC differentiation. The numbers of Lyz+ cells are highest in the distal Sox9 KO SI but are significantly reduced relative to control, and are essentially absent in the proximal SI, suggesting that regionally patterned signals may drive PC differentiation independent of Sox9. Apical granularity and expression levels of Lyz/Cryptdin are also altered, suggesting that while Sox9 KO ISCs can initiate PC differentiation, they are unable to reach full maturity. Antibody and qPCR based detection of PC gene products (including secreted antimicrobials, growth factors, and transcriptional regulators proposed to drive PC differentiation downstream of Sox9) are maintained in Sox9 KO cultured intestinal organoids and are elevated in organoids treated with pharmacological agents that drive the PC differentiation program. These results indicate that Sox9‐deficient ‘Paneth‐like’ cells are continually generated in culture and can be pushed toward PC differentiation with factors known to stimulate the PC differentiation program. We conclude that Sox9 is not required for the activation of at least sub‐sets of gene products associated with PC differentiation and function. Ongoing experiments are designed to investigate Sox9‐ dependent and independent pathways toward PC fate, and to characterize the functionality of Sox9−/− ‘Paneth‐like’ cells compared to controls.Support or Funding InformationRO1 DK091427‐05F32 DK115016‐01This abstract is from the Experimental Biology 2018 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.