PMCCPMCCPMCC

Search tips
Search criteria 

Advanced

 
Logo of nihpaAbout Author manuscriptsSubmit a manuscriptHHS Public Access; Author Manuscript; Accepted for publication in peer reviewed journal;
 
Nature. Author manuscript; available in PMC 2009 November 13.
Published in final edited form as:
PMCID: PMC2695978
NIHMSID: NIHMS76764

A unique role for autophagy and Atg16L1 in Paneth cells in murine and human intestine

Abstract

Susceptibility to Crohn's disease (CD), a complex inflammatory disease involving the small intestine, is controlled by up to 32 loci1. One CD risk allele is in ATG16L1, a gene homologous to the essential yeast autophagy gene ATG162. It is not known how Atg16L1 or autophagy contributes to intestinal biology or CD pathogenesis. To address these questions we generated and characterized mice that are hypomorphic for Atg16L1 protein expression, and validated conclusions based on studies in these mice by analyzing intestinal tissues that we collected from CD patients carrying the CD risk allele of ATG16L1. We show that Atg16L1 is a bona fide autophagy protein. Within the ileal epithelium, both Atg16L1 and a second essential autophagy protein Atg5 are selectively important for the biology of the Paneth cell, a specialized epithelial cell which functions in part by secretion of granule contents containing antimicrobial peptides and other proteins that alter the intestinal environment3. Atg16L1 and Atg5-deficient Paneth cells exhibited striking abnormalities in the granule exocytosis pathway. In addition, transcriptional analysis revealed an unexpected gain of function specific to Atg16L1-deficient Paneth cells including increased expression of genes involved in PPAR signaling and lipid metabolism, acute phase reactants, as well as two adipocytokines, leptin and adiponectin, known to directly influence intestinal injury responses. Importantly, CD patients homozygous for the ATG16L1 CD risk allele displayed Paneth cell granule abnormalities similar to those observed in autophagy protein-deficient mice and expressed increased levels of leptin protein. Thus, Atg16L1, and likely the process of autophagy, play their role within the intestinal epithelium of mice and CD patients by selective effects on the cell biology and specialized regulatory properties of Paneth cells.

Crohn's disease typically involves the distal ileum and in its most severe form is characterized by pathological changes including transmural acute and chronic inflammation. CD is associated with increased expression of immunoregulatory cytokines including leptin4 and adiponectin5. Multiple genetic factors predispose to CD, but the specific relationship between the function of these genes and the diverse pathologies observed in CD is not well understood. One CD susceptibility allele is in the predicted autophagy gene ATG16L1 6,7,8,9. Autophagy is an evolutionarily conserved process that recycles cellular components via delivery of double membrane-bound vesicles containing cytoplasm and cytoplasmic organelles to the lysosome10. Autophagy has an important role in cell and tissue homeostasis, and has been implicated in a range of human diseases10. The mammalian Atg16L1 protein contains an N-terminal domain that is homologous to yeast Atg162 which functions in autophagy as part of a complex with autophagy proteins Atg5 and Atg122,11. Atg16 is responsible, in both yeast and mammalian cells, for proper sub-cellular localization of the autophagy machinery12,8,11.

To determine the role of Atg16L1 and autophagy in the intestine, we generated two mouse lines with gene trap-mediated disruptions of Atg16L1 and a third line lacking Atg5 in intestinal epithelial cells. Gene trap vectors introduce a false splice acceptor into an intron, and can inhibit expression of intact mRNA13 (Fig. 1a). This can result in decreased expression of a protein, potentially generating viable mice when full disruption of a gene is lethal. This approach is attractive since Atg5 is part of the Atg16L1 complex and full disruption of Atg5 is lethal14,2. Mouse lines homozygous for gene trap mutations were generated from commercially available ES cells carrying gene trap mutations in the intron 3’ to either exon 6 or exon 10 of Atg16L113. Atg16L1 mutant murine embryo fibroblasts (MEFs) expressed low levels of Atg16L1 protein (Fig. 1b) indicating that both mouse lines, Atg16L1HM1 and Atg16L1HM2, are hypomorphic (HM) for expression of Atg16L1 protein. Atg16L1HM mice were born at Mendelian ratios (Supplementary Fig. 1a), and survive to adulthood; the characteristics of the two Atg16L1HM lines in vivo were similar across all experiments.

Figure 1
Role of Atg16L1 in autophagy in cells and intestine

To determine if Atg16L1 is an autophagy protein, we studied low-passage and transformed MEFs from Atg16L1HM mice compared to MEFs lacking the essential autophagy protein Atg514. Rapamycin-induced and autophagy-dependent15 degradation of the adapter protein p62 was diminished in Atg16L1HM and Atg5−/− cells (Fig. 1c-e). Decreased degradation of p62 in Atg16L1HM cells was restored by expressing Atg16L1 (Supplementary Fig. 1b, c). Atg16L1HM MEFs also showed diminished rapamycin-induced production of LC3-II, the phosphatidylethanolamine-conjugated form of Atg8/LC3-I generated during autophagy10 (Fig. 1e, f). The induction of autophagosomes, as measured by LC3-positive dot formation after rapamycin treatment or starvation, was also decreased in Atg16L1HM MEFs (Supplementary Fig. 2), although the defect of Atg16L1HM2 cells was more subtle in starved cells; this was confirmed in cells transfected with GFP-LC3 (Supplementary Fig. 3). Mammalian Atg16L1 is therefore an autophagy protein.

We next determined if markers of autophagy were abnormal in the distal small intestine (ileum, a common site of CD) of Atg16L1HM mice by measuring the expression of Atg16L1, LC3, and p62 proteins in ileal lysates (Fig. 1g-i). Atg16L1 mRNA is expressed throughout the crypt-villus axis (Supplementary Fig. 4). Atg16L1HM mice expressed 23−37% of the expected level of Atg16L1 protein (Fig. 1g, h). Consistent with a role for Atg16L1 in ileal autophagy, both the ratio of LC3-I to LC3-II, and the total amount of LC3-I and p62 were increased in lysates from Atg16L1HM mice (Fig. 1g, i). To validate these results, we studied ileal lysates from mice generated by breeding Atg5flox/flox mice16 to mice expressing the Cre recombinase under the control of the intestinal epithelium-specific villin promoter (Atg5flox/floxvillin-Cre mice)17. Atg5 expression was significantly diminished in ileal lysates of Atg5flox/floxvillin-Cre mice, and these mice exhibited changes in expression of LC3 and p62 similar to those observed in Atg16L1HM mice (Supplementary Fig. 5). These data are consistent with a role for Atg16L1 and Atg5 in ileal autophagy.

Deficiency in Atg16L1 had no effect on the overall morphology of the ileum or colon as measured by analysis of crypt height or villus length (data not shown). However, there were obvious abnormalities in Paneth cells, leading us to focus our studies on these critically important intestinal innate immune cells. Paneth cells are ileal epithelial cells thought to play a role in control of intestinal microbiota via secretion of granule contents including antimicrobial peptides and lysozyme18. Staining of whole mounts of ileum revealed the expected colocalization of lysozyme and mucus (Fig. 2a). However, there was a striking lack of lysozyme staining in the mucus of Atg16L1HM mice, suggesting an abnormality of Paneth cell secretion (Fig. 2b). We examined PAS/alcian blue stained sections and found extraordinary abnormalities in Paneth cells including aberrant, disorganized granules as well as decreased granule numbers (Fig 2c, d, and not shown). Blinded analysis of these sections from 16 control and 30 mutant mice revealed a 100% concordance between Atg16L1HM genotype and abnormal Paneth cell morphology. We quantified these Paneth granule abnormalities by staining sections for lysozyme which is normally packaged efficiently in the granules18 (Fig. 2e-h). In these sections, we observed a striking population of Atg16L1HM cells with diffuse lysozyme staining (Fig. 2f, h). We also observed the presence of intact granules in the crypt lumen of whole mounts of ileum from Atg16L1HM mice (Supplementary Fig. 6a-c), a finding confirmed by EM (Supplementary Figure 6d, e), potentially explaining the absence of lysozyme staining in the mucus layer of the ileum (Fig. 3a, b). These observations indicate that Atg16L1 is required for maintaining the integrity of the Paneth cell granule exocytosis pathway. Based on these data, and the published role for Nod2 in resistance to infection19, we orally challenged Atg16L1HM mice with Listeria monocytogenes. We found no change in L. monocytogenes titers in spleen, liver, and mesenteric lymph nodes (Supplementary Fig. 7), indicating that the striking changes in release of granules in ATG16L1HM mice did not affect L. monocytogenes resistance. This argues that the phenotypes of mutations analyzed to date in Atg16L1 and Nod 2 are distinct.

Figure 2
Mutation of Atg16L1 or Atg5 leads to disruption of the Paneth cell granule exocytosis pathway
Figure 3
Critical role of Atg16L1 in the structure and transcriptional profile of Paneth cells

Despite these profound alterations in the granule exocytosis pathway, we found no evidence of increased epithelial cell death or proliferation as determined by quantification of apoptotic bodies and M-phase cells (not shown). Importantly, deletion of Atg5 in the intestinal epithelium in Atg5flox/floxvillin-Cre mice led to Paneth cell and granule abnormalities similar to those observed in Atg16L1HM mice (Fig. 2i and Supplementary Fig. 8), while other epithelial cells appeared normal. This indicates that, within the intestinal epithelium, Paneth cells have a unique sensitivity to autophagy gene disruption.

To better characterize the effects of Atg16L1 deficiency in Paneth cells, we used transmission electron microscopy (EM). We observed degenerating mitochondria, loss of granules, and the frequent absence of apical microvilli in Atg16L1HM Paneth cells (Fig. 3ae; Supplementary Fig. 6d, e). EM also showed Atg16L1HM Paneth cells with marked increases in cytoplasmic vesicles (Fig 3b, d); a similar abnormality has been reported in Paneth cells from a CD patient20. Importantly, such dramatic findings were not present in epithelial progenitors or enterocytes (Fig. 3b, d and Supplementary Fig. 9), confirming that Atg16L1 deficiency selectively affects Paneth cells within the intestinal epithelium. We next performed transcriptional profiling of Paneth cell RNA procured by laser capture microdissection (LCM)21 (see methods and analysis in Supplementary Figure 10). Consistent with a lack of cell death or degeneration as detected by EM, microarray analysis revealed that less than 1.5% of probe sets detected changes in RNA levels using low stringency criteria (≥ 1.3-fold difference; Supplementary Table 1 and Supplementary Fig. 11). Cluster analysis of significantly enriched transcripts in Atg16L1 deficient Paneth cells revealed a striking signature of genes involved in PPAR pathways, adipocytokine signaling, and aspects of lipid metabolism (Fig. 3f and Supplementary Fig. 12). Additionally, transcripts for several acute phase reactants including serum amyloid A1, haptoglobin, and complement factors D and I were elevated (Fig. 3g). Of particular interest was the observation that the adipocytokines leptin and adiponectin, previously reported to be increased in CD patients5,4, were amongst the most highly enriched transcripts (Fig. 3g). To determine if these transcriptional changes are unique to Atg16L1 deficient Paneth cells, we examined a second primary cell type from Atg16L1HM mice. Autophagy is important in the function of T cells22. Thymocytes from Atg16L1HM mice were normal in number but expressed low levels of Atg16L1 and exhibited decreased conversion of LC3I to LC3II (Supplementary Fig. 13) demonstrating that Atg16L1 is important for autophagy in thymocytes. Microarray analysis of these cells revealed that, in striking contrast to Paneth cells, expression of only 27 genes was altered more than 1.3 fold (Supplementary Fig. 14). There was no significant change in expression of the most significant clusters of transcripts altered in Atg16L1HM Paneth cells, and only one gene altered in thymocytes was also altered in Paneth cells (Fig. 3g). Therefore the transcriptional signature of Atg16L1 deficiency is specific to Paneth cells, again emphasizing the unique effects of Atg16L1 deficiency on these cells. Taken together with the extensive morphologic abnormalities documented above, we conclude that Atg16L1 deficiency is associated with profound alterations in the specialized properties of Paneth cells including defective granule exocytosis and unexpected increases in expression of genes involved in regulating injury responses.

Given the importance of Atg16L1 and Atg5 in Paneth cells in mice, we examined the role of the human ATG16L1 CD risk allele via a retrospective analysis of ileocolic resection specimens from patients with CD. We studied tissue sections from the uninvolved proximal margins, containing little or no inflammation, from 10 CD patients homozygous for the ATG16L1 risk allele compared to 7 CD controls without the risk allele. All 17 patients lacked the three major NOD2 risk alleles and the protective IL23R allele for CD7,23. Independent blinded examination by T.S.S. and E.M.B. revealed that 100% of at risk patients and 0% of controls contained abnormal Paneth cells similar to those in Atg16L1HM mice (Fig. 4a, b). We quantified lysozyme staining in CD patient specimens, and like Atg16L1HM mice, found that patients carrying the ATG16L1 risk allele contained an increased proportion of Paneth cells with disorganized or diminished granules or exhibiting diffuse cytoplasmic lysozyme staining (Fig. 4c-g). Moreover, consistent with transcriptional analysis in mice, 19% of Paneth cells from at risk patients that exhibited diffuse lysozyme staining also stained positive for leptin protein compared to only 2% of controls (p<0.05) (Fig. 4e, f). These findings demonstrate a remarkable concordance between the pathology and transcriptional profile of Paneth cells from Atg16L1HM mice and Paneth cell abnormalities observed in CD patients with the risk allele of ATG16L1. These data provide the first indication that Atg16L1 has a specific role in humans and mice in regulating the specialized properties of Paneth cells, and provide a novel and relevant mouse model that emulates one of the many diverse pathological hallmarks of human CD. We show that Atg16L1 and a second autophagy protein Atg5 are critically important for the known role of Paneth cells in secretion of granule contents that may alter the intestinal microbiota. In addition, we demonstrate a previously unknown role of Atg16L1 in the regulation of Paneth cell expression of adipocytokines previously associated with CD. Within the intestinal epithelium, the dramatic effect of autophagy protein deficiency on Paneth cells, but not enterocytes which share a common progenitor, indicates that autophagy can contribute to disease pathogenesis via a highly specific role within a single cell lineage. Indeed, the effects of hypomorphic expression of Atg16L1 were specific to Paneth cells and not seen in Atg16L1-deficient thymocytes. An important implication of this type of ‘within-lineage’ specificity is that future studies will need to focus on how Atg16L1 polymorphisms affect the function of differentiated Paneth cells. Since both environment and genotype play a role in human CD pathogenesis7, it will be interesting to determine whether environmental triggers including agents that damage the intestine or pathogens alter the pathological features associated with compromised Atg16L1 function.

Figure 4
Crohn's Disease patients homozygous for the disease risk allele of ATG16L1 display Paneth cell abnormalities similar to Atg16L1HM mice

Supplementary Material

Suppfigs

supptables

1

Supplementary Figure 1. Allelic inheritance in Atg16L1 HM mice and rescue of autophagy deficiency in Atg16L1 deficient fibroblasts. a, Mice heterozygous for the gene trap mutation were bred to each other and produced wild-type (wt), heterozygous (hm/+) and homozygous (hm/hm) progeny which were separated by genotype ~4 weeks after birth. Both gene trap alleles displayed Mendelian inheritance (no significant deviation by Fisher's chi-square test, p>0.2 for ATG16L1 HM1 and p>0.3 for ATG16L1 HM2) b-c, Atg16L1 cDNA or vector control were reintroduced into Atg16L1 HM1 MEFs via retroviral transduction. MEFs were selected for successful transduction with 5μ g/ml puromycin, then grown in the presence of the chemical inducer of autophagy rapamycin (50μg/ml) and cyclohexamide (5 μg/ml) for 0, 4, and 8 h. Western blot analysis of cell lysates show a restoration of p62 degradation in MEFs selected for Atg16L1 expression but not vector control (b) which was quantified by densitometry and normalized to actin (n = 3) (c).

Supplementary Figure 2. MEFs derived from Atg16L1 HM1 and Atg16L1 HM2 lines show reduced endogenous LC3 dot form ation. a, Representative immunofluorescence images of primary low-passage MEFs grown in 50 μg/ml rapamycin for 4h or in amino acid and serum replete EBSS media for 2h to induce autophagy and stained with LC3. LC3-positive dots >0.5μm in diameter are indicated by arrow heads. Scale bar, 20μm. b-e, Q uantification of LC3 dots revealed that both the accumulation of LC3 dots per cell (b and d) or % cells with LC3 dots (c and e) after autophagy induction were compromised in Atg16L1 HM cells, indicating that autophagosome formation was aberrant under these conditions (n = 3, at least 70 cells were analyzed per sample). The increase in LC3 dots was statistically significant in all WT samples. There was no statistically significant increase in Atg16L1 HM cells (note: Atg16L1 HM1 cells display a statistically significant decrease in dots per cell under starvation conditions). P values were calculated using two-tailed student's t test. Error bars represent SEM.

Supplementary Figure 3. GFP-LC3 dot form ation is reduced in Atg16L1 HM1 MEFs. a, Representative fluorescence im ages of in im m ortalized Atg16L1 HM MEFs stably expressing GFP-LC3. Cells were cultured in DMEM with 10% FBS or DMEM without amino acids and serum for 2 h. Scale bar, 10 μm. b, Quantification of the num ber of GFP-LC3 dots per cell (counted in at least 5 different images) show a significant reduction in dot form ation in Atg16L1HM1 cells. Atg16L1 HM2 cells did not show a statistically significant reduction in dot form ation, consistent with the higher expression of Atg16L1 in these cells. P values were calculated using two-tailed student's t test. Error bars represent SEM .

Supplementary Figure 4. Atg16L1 is expressed throughout the ileal crypt-villus axis. RNA was procured by LCM from the villus tip, villus base, and crypt base of the distal ileum from Atg16L1HM mice. qRT-PCR analysis shows detectable Atg16L1 transcripts in all three compartm ents (n = 3). There was a statistically significant difference between the villus tip and the villus base (p<0.1) or crypt (p<0.05) indicating that Atg16L1 transcripts are enriched in the villus base and crypt. P values were calculated using two-tailed student's t test. Error bars represent SEM.

Supplementary Figure 5. Conditional deletion of Atg5 in the intestinal epithelium leads to reduced LC3 conversion and accumulation of p62. a, Western blot analysis of ileal lysates from Atg5flox/floxvillin-Cre mice reveal decreased Atg5 expression and an increase in LC 3-I to LC 3-II ratio similar to Atg16L1 HM mice suggesting a critical role for these proteins in intestinal autophagy (n = 3 of each genotype, 2 of each shown). b-c, Atg5flox/floxvillin-Cre mice also display an increase in p62 protein expression in the ileal epithelium (b) similar to Atg16L1HM mice. Quantification of p62 levels by densitometry normalized to actin revealed ~7 -fold increase in Atg5flox/floxvillin-Cre+ mice (n = 3) (c). P values were calculated using two-tailed student's t test. Error bars represent SEM.

Supplementary Figure 6. Abnormal Paneth granule exocytosis in Atg16L1 deficient mice. a-c, Whole mounts of the small intestines from control (a) and Atg16L1 HM (b, c) mice stained with FITC-conjugated Helix pomatia lectin that labels goblet cell mucus (green) and antisera directed against lysozyme (red). Lectin positive goblet cells stud the surface of the villi. No accumulated mucin is shown in these fields. Strikingly, the lysozyme staining in the Atg16L1HM mice is concentrated in small clusters of spherical aggregates (white arrow in b) that are present in the crypt lumen. High power view of the aggregate in (c) is 40μm in its greatest dimension. d-e, EM analysis of the Atg16L1 HM ileum reveals diminished microvilli on Paneth cells (d) and the adjacent crypt lumen (indicated by arrow heads) contains intact Paneth granules and cytoplasm (e). Scale bars: a, b, 200 μm; d, e, 2 μm.

Supplementary Figure 7. Atg16L1 mutant mice do not display increased susceptibility to oral L. m onocytogenes infection. Littermate WT (n = 10) and Atg16L1HM (n = 5 for HM 1 and n = 4 for HM 2) mice were infected orally with 10 9 L. monocytogenes re-suspended in 200 μl of 5% sodium bicarbonate by gastric gavage. The num ber of bacteria in liver, spleen, and mesenteric lymph nodes were determined 72 h after infection and displayed no significant differences with WT. P values were calculated using two-tailed Mann-Whitney test. Horizontal bars represent the geometric mean.

Supplementary Figure 8. Mice with conditional deletion of Atg5 in the intestinal epithelium have abnormal lysozyme distribution in Paneth cells similar to observations made in Atg16L1 deficient mice. Representative images of indirect immunofluorescence of sections stained for lysozyme (red) in Atg5flox/flox control and Atg5flox/floxvillin-Cre mouse ileal crypts. Dotted lines denote crypt unit. Scale bars: 10 μm.

Supplementary Figure 9. Enterocytes in the ileal epithelium are similar between Atg16L1 mutant and wild-type controls by ultrastructural analysis. ab, EM of ileal villus enterocytes from WT (a, c, d) and Atg16L1 HM (b, e, f) mice show similar morphology with intact mitochondria. Scale bars: a, b, 2 μm; c, e, 500 nm ; d, f, 100 nm.

Supplementary Figure 10. Validation of lack of contamination of LCM procured Paneth cells with villus epithelial cells. a, We quantified 6 genes by qRT-PCR known to be enriched in villus epithelial cells 1 and not involved in fatty acid or cholesterol metabolism . We compared gene expression in LCM -procured Paneth cells versus villus epithelial cells. The fold-enrichm ent for villus epithelial cells is indicated for each gene (experiments were performed in triplicate). For each of these 6 genes and 4 well-characterized markers of villus epithelial cells (indicated by an asterisk), we compared the fold -change for Atg16L1 HM Paneth cells versus WT. Transcripts highly enriched in villus epithelial cells were not enriched in LCM procured Paneth cells.

Supplementary Figure 10. Validation of lack of contamination of LCM procured Paneth cells with villus epithelial cells. a, We quantified 6 genes by qRT-PCR known to be enriched in villus epithelial cells 1 and not involved in fatty acid or cholesterol metabolism . We compared gene expression in LCM -procured Paneth cells versus villus epithelial cells. The fold-enrichment for villus epithelial cells is indicated for each gene (experiments were performed in triplicate). For each of these 6 genes and 4 well-characterized markers of villus epithelial cells (indicated by an asterisk), we compared the fold -change for Atg16L1 HM Paneth cells versus WT. Transcripts highly enriched in villus epithelial cells were not enriched in LCM procured Paneth cells.

Supplement Figure 11. Heat map for mRNAs that are significantly enriched or diminished in Atg16L1HM thymocytes relative to control. A 1.3-fold difference and a 90% lower bound cut-off were used.

Supplementary Figure 12. Functional analysis of enriched and diminished transcripts of Atg16L1-deficient Paneth cells. a-b, The Functional Classification Tool from the DAVID Bioinformatics Resource2 (NIAID, NIH) was used to determine the enriched functional categories of the two gene lists in Supplementary Table 1 comparing the transcriptome of Atg16L1HM versus WT Paneth cells (enriched (a) or diminished (b) in Atg16L1HM mice). In both cases, the highest statistically significant gene ontology (GO) terms that were represented within the gene list are indicated. We used medium stringency to cluster the genes. Count = number of genes in the list with a given GO term; % = fractional representation of a GO term within the list. Various statistical methods are available to determine significance (p-value, fold-enrichment, Bonferoni, Benjamini, and false-discovery rate, FDR). Functional groups were sorted by p-value in these tables. The statistical significance of the clustering for the top rated GO terms is much higher in the gene list for the enriched transcripts.

Supplementary Figure 13. Thym ocytes from Atg16L1HM mice have reduced Atg16L1 expression and conversion of LC3-I to LC3-II. Western blot analysis of whole cell thymocyte lysates from Atg16L1 HM mice reveal decreased Atg16L1 expression and an increase in LC3-I to LC3-II ratio compared to WT control.

Supplement Figure 14. Heat map for mRNAs that are significantly enriched or diminished in Atg16L1HM Paneth cells relative to control. A 1.3-fold difference and a 90% lower bound cut-off were used.

Acknowledgements

We would like to thank Namiko Abe for technical assistance with fluorescence microscopy, Valleria Cavalli for microscope use, Jason Eisenberg and Aylwin Ng for help with bioinformatics analysis, Andre J. Ouellette for technical advice, and Indira Mysorekar and Jason Mills for help with antibodies. This research was supported by grant U54 AI057160 Project 6 and the Broad Institute (K.C., J.Loh, and H.W.V.), training grant NIH T32 AR07279 (K.C.), the Lallage Feazel Wall Fellowship DRG-1972-08 (K.C.) from the Damon Runyon Cancer Research Foundation; the Pew Foundation (J.Liu., S.L.B., H.M., W.K.C., and T.S.S.); the Washington University Digestive Diseases Research Core Center P30 DK52574, Barnes Jewish Foundation, Johnson and Johnson Translational Seed Award, and the Crohn's Colitis Foundation of America (E.L., S.H., and C.S.); Grants-in-aid for Scientific Research from the Ministry of Education, Culture, Sports, Science and Technology of Japan, and the Toray Science Foundation (C.K. and N.M.); NIH R01 AI062832 (J.A.C.); NIH AI062773 and DK43351 (R.J.X.).

Footnotes

References

1. Barrett JC, et al. Genome-wide association defines more than 30 distinct susceptibility loci for Crohn's disease. Nat. Genet. 2008;40:955–962. [PMC free article] [PubMed]
2. Mizushima N, et al. Mouse Apg16L, a novel WD-repeat protein, targets to the autophagic isolation membrane with the Apg12-Apg5 conjugate. J. Cell Sci. 2003;116:1679–1688. [PubMed]
3. Ouellette AJ. Paneth cell alpha-defensin synthesis and function. Curr. Top. Microbiol. Immunol. 2006;306:1–25. [PubMed]
4. Barbier M, et al. Overexpression of leptin mRNA in mesenteric adipose tissue in inflammatory bowel diseases. Gastroenterol. Clin. Biol. 2003;27:987–991. [PubMed]
5. Yamamoto K, et al. Production of adiponectin, an anti-inflammatory protein, in mesenteric adipose tissue in Crohn's disease. Gut. 2005;54:789–796. [PMC free article] [PubMed]
6. Genome-wide association study of 14,000 cases of seven common diseases and 3,000 shared controls. Nature. 2007;447:661–678. [PMC free article] [PubMed]
7. Xavier RJ, Podolsky DK. Unravelling the pathogenesis of inflammatory bowel disease. Nature. 2007;448:427–434. [PubMed]
8. Rioux JD, et al. Genome-wide association study identifies new susceptibility loci for Crohn disease and implicates autophagy in disease pathogenesis. Nat. Genet. 2007;39:596–604. [PMC free article] [PubMed]
9. Hampe J, et al. A genome-wide association scan of nonsynonymous SNPs identifies a susceptibility variant for Crohn disease in ATG16L1. Nat. Genet. 2007;39:207–211. [PubMed]
10. Levine B, Kroemer G. Autophagy in the Pathogenesis of Disease. Cell. 2008;132:27–42. [PMC free article] [PubMed]
11. Fujita N, Itoh T, Fukuda M, Noda T, Yoshimori T. The Atg16L Complex Specifies the Site of LC3 Lipidation for Membrane Biogenesis in Autophagy. Mol. Biol. Cell. 2008 [PMC free article] [PubMed]
12. Kuma A, Mizushima N, Ishihara N, Ohsumi Y. Formation of the approximately 350-kDa Apg12-Apg5.Apg16 multimeric complex, mediated by Apg16 oligomerization, is essential for autophagy in yeast. J. Biol. Chem. 2002;277:18619–18625. [PubMed]
13. Stryke D, et al. BayGenomics: a resource of insertional mutations in mouse embryonic stem cells. Nucleic Acids Res. 2003;31:278–281. [PMC free article] [PubMed]
14. Kuma A, et al. The role of autophagy during the early neonatal starvation period. Nature. 2004;432:1032–1036. [PubMed]
15. Komatsu M, et al. Homeostatic levels of p62 control cytoplasmic inclusion body formation in autophagy-deficient mice. Cell. 2007;131:1149–1163. [PubMed]
16. Hara T, et al. Suppression of basal autophagy in neural cells causes neurodegenerative disease in mice. Nature. 2006;441:885–889. [PubMed]
17. Madison BB, et al. Cis elements of the villin gene control expression in restricted domains of the vertical (crypt) and horizontal (duodenum, cecum) axes of the intestine. J. Biol. Chem. 2002;277:33275–33283. [PubMed]
18. Porter EM, Bevins CL, Ghosh D, Ganz T. The multifaceted Paneth cell. Cell Mol. Life Sci. 2002;59:156–170. [PubMed]
19. Kobayashi KS, et al. Nod2-dependent regulation of innate and adaptive immunity in the intestinal tract. Science. 2005;307:731–734. [PubMed]
20. Dvorak AM, Dickersin GR. Crohn's Disease: Transmission Electron Microscopic Studies I. Barrier Function. Possible Changes Related to Alterations of Cell Coat, Mucous Coat, Epithelial Cells, and Paneth Cells. Human Pathology. 1980;11:561–571. [PubMed]
21. Stappenbeck TS, Mills JC, Gordon JI. Molecular features of adult mouse small intestinal epithelial progenitors. Proc Natl Acad Sci U. S. A. 2003;100:1004–1009. [PubMed]
22. Pua HH, Dzhagalov I, Chuck M, Mizushima N, He YW. A critical role for the autophagy gene Atg5 in T cell survival and proliferation. J. Exp. Med. 2007;204:25–31. [PMC free article] [PubMed]
23. Duerr RH, et al. A genome-wide association study identifies IL23R as an inflammatory bowel disease gene. Science. 2006;314:1461–1463. [PubMed]
24. Subramanian A, et al. Gene set enrichment analysis: a knowledge-based approach for interpreting genome-wide expression profiles. Proc Natl Acad Sci U. S. A. 2005;102:15545–15550. [PubMed]