The profound complexity of the intestinal mucosa demands a spatial approach to the study of gut transcriptomics. Although single-cell RNA sequencing has revolutionized our ability to survey the ...diverse cell types of the intestine, knowledge of cell type alone cannot fully describe the cells that make up the intestinal mucosa. During homeostasis and disease, dramatic gradients of oxygen, nutrients, extracellular matrix proteins, morphogens, and microbiota collectively dictate intestinal cell state, and only spatial techniques can articulate differences in cellular transcriptomes at this level. Spatial transcriptomic techniques assign transcriptomic data to precise regions in a tissue of interest. In recent years, these protocols have become increasingly accessible, and their application in the intestinal mucosa has exploded in popularity. In the gut, spatial transcriptomics typically involve the application of tissue sections to spatially barcoded RNA sequencing or laser capture microdissection followed by RNA sequencing. In combination with single-cell RNA sequencing, these spatial sequencing approaches allow for the construction of spatial transcriptional maps at pseudosingle-cell resolution. In this review, we describe the spatial transcriptomic technologies recently applied in the gut and the previously unattainable discoveries that they have produced.
Understanding how macroautophagy/autophagy contributes to tissue homeostasis is essential for understanding organismal health. The intestinal epithelium is an ideal model to define mechanisms that ...regulate tissue homeostasis because it houses well-defined populations of intestinal stem cells. Active intestinal stem cells (a-ISCs) are defined by their active cycling and self-renewal during homeostasis, which supports continual tissue turnover in vivo. In vitro, this is observed as long-term organoid formation capacity. A second population of stem cells, called "facultative intestinal stem cells" (f-ISCs), are defined by their ability to 1) survive tissue damage that depletes the injury-sensitive a-ISCs and 2) reenter the cell cycle to repopulate the a-ISC compartment and regenerate the epithelium. The prospective identification of f-ISCs has been challenging, as cells expressing markers of multiple differentiated lineages, particularly secretory lineages, appear to function as f-ISCs in diverse injury contexts. We evaluated cell age (defined as time elapsed after cell cycle exit) and autophagic state (marked by autophagic vesicle content) as molecular features that may be related to f-ISC capacity. We found that autophagic state, but not cell age, prospectively identifies f-ISCs within multiple lineages. As such, we describe autophagy as a lineage-agnostic marker of f-ISC capacity in the mammalian intestine.
Background
The intestinal epithelium is a highly proliferative tissue that undergoes complete turnover in 3 to 5 days. The presence of intestinal stem cells expressing the canonical Wnt target gene ...Lgr5, known as active intestinal stem cells (a‐ISCs), are responsible for generating daughter cells that differentiate into specialized epithelial cells to carryout various functions in the intestine. The proliferative nature of the intestinal epithelium renders it susceptible to DNA damage‐inducing injury, such as high‐dose irradiation and chemotherapy. Although a‐ISCs and early daughter cells are killed by these insults, a radio‐resistant population of facultative intestinal stem cells (f‐ISCs) can regenerate lost a‐ISCs to restore homeostasis following injury. The functional characteristics of f‐ISCs are becoming increasingly understood, however, whether any epithelial cell can act as an f‐ISC is less clear. One reason for this ambiguity is a heavy reliance on Cre‐driven reporter mouse models with low recombination efficiency. Our objective was to find a functional marker to identify f‐ISCs based on cellular state rather than gene expression. The autophagy pathway has been shown to protect against DNA damage and irradiation‐induced apoptosis in the intestinal epithelium. Furthermore, recent studies demonstrate a requirement for the autophagy pathway during cellular de‐differentiation in both gastric chief and pancreatic acinar cells following metaplasia‐inducing injury. Given that autophagy plays roles in both radio‐resistance and cellular plasticity, two integral features of f‐ISCs, we hypothesized that autophagic activity could serve to identify cells with f‐ISC capacity.
Methods and Results
Using the autophagic vesicle tracer dye CytoID combined with fluorescence‐activated cell sorting, we demonstrate that intestinal epithelial cells with high levels of CytoID exhibit increased organoid‐formation efficiency (OFE) compared to CytoID ‘low’ cells. Single cell sequencing reveals that the CytoID high population is largely composed of secretory cells including Paneth, Goblet, Tuft, and Enteroendocrine cells, whereas the CytoID low population consisted mainly of a‐ISCs and absorptive Enterocytes. Using reporter mice and antibodies against cell surface receptors, we observe that CytoID can identify cells with high OFE within Enteroendocrine, Paneth, and Goblet cell lineages. Finally, we demonstrate that autophagy is required for the enhanced organoid‐formation observed in CytoID high cells by plating these cells in the presence of the lysosomal inhibitor Bafilomycin A1.
Conclusions
Our new data support the notion that epithelial cells in a high autophagic state are biased to secretory lineages and that autophagy status functions as a lineage agnostic marker of f‐ISCs. Furthermore, our data suggests that autophagy is required for organoid formation in these lineages.
Colorectal cancer (CRC) is a leading cause of cancer-related death. There is an urgent need for new methods of early CRC detection and monitoring to improve patient outcomes. Extracellular vesicles ...(EVs) are secreted, lipid-bilayer bound, nanoparticles that carry biological cargo throughout the body and in turn exhibit cancer-related biomarker potential. RNA binding proteins (RBPs) are posttranscriptional regulators of gene expression that may provide a link between host cell gene expression and EV phenotypes. Insulin-like growth factor 2 RNA binding protein 1 (IGF2BP1/IMP1) is an RBP that is highly expressed in CRC with higher levels of expression correlating with poor prognosis. IMP1 binds and potently regulates tumor-associated transcripts that may impact CRC EV phenotypes. Our objective was to test whether IMP1 expression levels impact EV secretion and/or cargo. We used RNA sequencing, in vitro CRC cell lines, ex vivo colonoid models, and xenograft mice to test the hypothesis that IMP1 influences EV secretion and/or cargo in human CRC. Our data demonstrate that IMP1 modulates the RNA expression of transcripts associated with extracellular vesicle pathway regulation, but it has no effect on EV secretion levels in vitro or in vivo. Rather, IMP1 appears to affect EV regulation by directly entering EVs in a transformation-dependent manner. These findings suggest that IMP1 has the ability to shape EV cargo in human CRC, which could serve as a diagnostic/prognostic circulating tumor biomarker.
This work demonstrates that the RNA binding protein IGF2BP1/IMP1 alters the transcript profile of colorectal cancer cell (CRC) mRNAs from extracellular vesicle (EV) pathways. IMP1 does not alter EV production or secretion in vitro or in vivo, but rather enters CRC cells where it may further impact EV cargo. Our work shows that IMP1 has the ability to shape EV cargo in human CRC, which could serve as a diagnostic/prognostic circulating tumor biomarker.
RNA regulons are essential in intestinal homeostasis Parham, Louis R; Williams, Patrick A; Chatterji, Priya ...
American journal of physiology. Gastrointestinal and liver physiology/American journal of physiology: Gastrointestinal and liver physiology,
01/2019, Letnik:
316, Številka:
1
Journal Article
Recenzirano
Odprti dostop
Intestinal epithelial cells are among the most rapidly proliferating cell types in the human body. There are several different subtypes of epithelial cells, each with unique functional roles in ...responding to the ever-changing environment. The epithelium's ability for rapid and customized responses to environmental changes requires multitiered levels of gene regulation. An emerging paradigm in gastrointestinal epithelial cells is the regulation of functionally related mRNA families, or regulons, via RNA-binding proteins (RBPs). RBPs represent a rapid and efficient mechanism to regulate gene expression and cell function. In this review, we will provide an overview of intestinal epithelial RBPs and how they contribute specifically to intestinal epithelial stem cell dynamics. In addition, we will highlight key gaps in knowledge in the global understanding of RBPs in gastrointestinal physiology as an opportunity for future studies.
Calorie restriction can enhance the regenerative capacity of the injured intestinal epithelium. Among other metabolic changes, calorie restriction can activate the autophagy pathway. Although ...independent studies have attributed the regenerative benefit of calorie restriction to downregulation of mTORC1, it is not known whether autophagy itself is required for the regenerative benefit of calorie restriction. We used mouse and organoid models with autophagy gene deletion to evaluate the contribution of autophagy to intestinal epithelial regeneration following calorie restriction. In the absence of injury, mice with intestinal epithelial-specific deletion of autophagy gene
(
) exhibit weight loss and histological changes similar to wild-type mice following calorie restriction. Conversely, calorie-restricted
mice displayed a significant reduction in regenerative crypt foci after irradiation compared with calorie-restricted wild-type mice. Targeted analyses of tissue metabolites in calorie-restricted mice revealed an association between calorie restriction and reduced glycocholic acid (GCA) in wild-type mice but not in
mice. To evaluate whether GCA can directly modulate epithelial stem cell self-renewal, we performed enteroid formation assays with or without GCA. Wild-type enteroids exhibited reduced enteroid formation efficiency in response to GCA treatment, suggesting that reduced availability of GCA during calorie restriction may be one mechanism by which calorie restriction favors epithelial regeneration in a manner dependent upon epithelial autophagy. Taken together, our data support the premise that intestinal epithelial
is required for the regenerative benefit of calorie restriction, due in part to its role in modulating luminal GCA with direct effects on epithelial stem cell self-renewal.
Calorie restriction is associated with enhanced intestinal regeneration after irradiation, but the requirement of autophagy for this process is not known. Our data support the premise that intestinal epithelial autophagy is required for the regenerative benefit of calorie restriction. We also report that luminal levels of primary bile acid glycocholic acid are modulated by epithelial cell autophagy during calorie restriction with direct effects on epithelial stem cell function.
The intestinal epithelium exhibits a rapid and efficient regenerative response to injury. Emerging evidence supports a model where plasticity of differentiated cells, particularly those in the ...secretory lineages, contributes to epithelial regeneration upon ablation of injury‐sensitive stem cells. However, such facultative stem cell activity is rare within secretory populations. Here, we ask whether specific functional properties predict facultative stem cell activity. We utilize in vivo labeling combined with ex vivo organoid formation assays to evaluate how cell age and autophagic state contribute to facultative stem cell activity within secretory lineages. Strikingly, we find that cell age (time elapsed since cell cycle exit) does not correlate with secretory cell plasticity. Instead, high autophagic vesicle content predicts plasticity and resistance to DNA damaging injury independently of cell lineage. Our findings indicate that autophagic status prior to injury serves as a lineage‐agnostic marker for the prospective identification of facultative stem cells.
Synopsis
Facultative intestinal stem cells promote epithelial regeneration in response to injury, but the contributing cellular properties are unclear. This study shows that autophagic vesicle content positively correlates with plasticity and injury‐resistance in intestinal epithelial cells.
Chga+ enteroendocrine cells generate intestinal 3D organoids and contribute to epithelial regeneration following irradiation.
Cell age does not correlate with cellular plasticity within secretory lineages in vitro.
Autophagic vesicle content positively correlates with cellular plasticity in vitro in a lineage agnostic manner.
IECs with high autophagic vesicle content are mainly secretory and partially protected against radiation‐induced DNA damage.
Facultative intestinal stem cells promote epithelial regeneration in response to injury, but the contributing cellular properties are unclear. This study shows that autophagic vesicle content positively correlates with plasticity and injury‐resistance in intestinal epithelial cells.
RNA binding proteins, including IMP1/IGF2BP1, are essential regulators of intestinal development and cancer. Imp1 hypomorphic mice exhibit gastrointestinal growth defects, yet the specific role for ...IMP1 in colon epithelial repair is unclear. Our prior work revealed that intestinal epithelial cell‐specific Imp1 deletion (Imp1ΔIEC) was associated with better regeneration in mice after irradiation. Here, we report increased IMP1 expression in patients with Crohn's disease and ulcerative colitis. We demonstrate that Imp1ΔIEC mice exhibit enhanced recovery following dextran sodium sulfate (DSS)‐mediated colonic injury. Imp1ΔIEC mice exhibit Paneth cell granule changes, increased autophagy flux, and upregulation of Atg5. In silico and biochemical analyses revealed direct binding of IMP1 to MAP1LC3B, ATG3, and ATG5 transcripts. Genetic deletion of essential autophagy gene Atg7 in Imp1ΔIEC mice revealed increased sensitivity of double‐mutant mice to colonic injury compared to control or Atg7 single mutant mice, suggesting a compensatory relationship between Imp1 and the autophagy pathway. The present study defines a novel interplay between IMP1 and autophagy, where IMP1 may be transiently induced during damage to modulate colonic epithelial cell responses to damage.
Synopsis
The RNA binding protein IGF2BP1/IMP1 is upregulated in patients with Crohn's disease and ulcerative colitis. Imp1 deletion increases autophagy and recovery from colonic epithelial damage, suggesting that IMP1 modulates colonic inflammation and epithelial homeostasis.
Mice with Imp1 deletion exhibit increased autophagy flux and enhanced recovery from colonic epithelial damage.
IMP1 protein binds directly to autophagy transcripts.
Deletion of autophagy gene Atg7 sensitizes mice with Imp1 deletion to colonic epithelial damage.
The RNA binding protein IGF2BP1/IMP1 is upregulated in patients with Crohn's disease and ulcerative colitis. Imp1 deletion increases autophagy and recovery from colonic epithelial damage, suggesting that IMP1 modulates colonic inflammation and epithelial homeostasis.
Autophagy plays roles in esophageal pathologies both benign and malignant. Here, we aim to define the role of autophagy in esophageal epithelial homeostasis.
We generated tamoxifen-inducible, ...squamous epithelial-specific Atg7 (autophagy related 7) conditional knockout mice to evaluate effects on esophageal homeostasis and response to the carcinogen 4-nitroquinoline 1-oxide (4NQO) using histologic and biochemical analyses. We fluorescence-activated cell sorted esophageal basal cells based on fluorescence of the autophagic vesicle (AV)-identifying dye Cyto-ID and then subjected these cells to transmission electron microscopy, image flow cytometry, three-dimensional organoid assays, RNA sequencing, and cell cycle analysis. Three-dimensional organoids were subjected to passaging, single-cell RNA sequencing, cell cycle analysis, and immunostaining.
Genetic autophagy inhibition in squamous epithelium resulted in increased proliferation of esophageal basal cells under homeostatic conditions and also was associated with significant weight loss in mice treated with 4NQO that further displayed perturbed epithelial tissue architecture. Esophageal basal cells with high AV level (Cyto-IDHigh) displayed limited organoid formation capability on initial plating but passaged more efficiently than their counterparts with low AV level (Cyto-IDLow). RNA sequencing suggested increased autophagy in Cyto-IDHigh esophageal basal cells along with decreased cell cycle progression, the latter of which was confirmed by cell cycle analysis. Single-cell RNA sequencing of three-dimensional organoids generated by Cyto-IDLow and Cyto-IDHigh cells identified expansion of 3 cell populations and enrichment of G2/M-associated genes in the Cyto-IDHigh group. Ki67 expression was also increased in organoids generated by Cyto-IDHigh cells, including in basal cells localized beyond the outermost cell layer.
Autophagy contributes to maintenance of the esophageal proliferation-differentiation gradient. Esophageal basal cells with high AV level exhibit limited proliferation and generate three-dimensional organoids with enhanced self-renewal capacity.
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