Maternal separation (MS) in neonates can lead to intestinal injury. MS in neonatal mice disrupts mucosal morphology, induces colonic inflammation and increases trans-cellular permeability. Several studies indicate that intestinal epithelial stem cells are capable of initiating gut repair in a variety of injury models but have not been reported in MS. The pathophysiology of MS-induced gut injury and subsequent repair remains unclear, but communication between the brain and gut contribute to MS-induced colonic injury. Corticotropin-releasing hormone (CRH) is one of the mediators involved in the brain–gut axis response to MS-induced damage. We investigated the roles of the CRH receptors, CRHR1 and CRHR2, in MS-induced intestinal injury and subsequent repair. To distinguish their specific roles in mucosal injury, we selectively blocked CRHR1 and CRHR2 with pharmacological antagonists. Our results show that in response to MS, CRHR1 mediates gut injury by promoting intestinal inflammation, increasing gut permeability, altering intestinal morphology, and modulating the intestinal microbiota. In contrast, CRHR2 activates intestinal stem cells and is important for gut repair. Thus, selectively blocking CRHR1 and promoting CRHR2 activity could prevent the development of intestinal injuries and enhance repair in the neonatal period when there is increased risk of intestinal injury such as necrotizing enterocolitis.
Neonatal maternal separation (MS) is a documented model of stress in early life1. This model has been used to study irritable bowel syndrome (IBS) and inflammatory bowel disease (IBD) in adulthood2,3, as well as neonatal intestinal disorders4,5,6. Premature infants are separated from their mothers and commonly fed while in incubators. These infants experience little physical human contact, are not breastfed, and are exposed to various stress factors such as infection, mechanical ventilation, hypothermia, and hypoxia. These stresses increase their risk of developing early intestinal disorders, such as necrotizing enterocolitis (NEC). MS during the neonatal period in a mouse model can lead to significant intestinal epithelial dysfunction. We have previously shown that MS in neonatal mice changes the intestinal mucosal morphology, increases trans-cellular permeability and causes colonic inflammation4,5,6. In addition, changes in the microbiome are associated with MS-induced gut injury7. Intestinal epithelial stem cells (IESCs) expressing leucine-rich repeat containing G-protein-coupled receptor5 (Lgr5) initiate gut repair and prevent further intestinal damage resulting from various causes8,9. However, in the MS model, the induced gut injury and subsequent repair mechanism remains to be elucidated.
The brain-gut axis is a complex network which mediates communication between the central nervous system (CNS) and the gastrointestinal tract10. Some of its components include sensory fibers of the spinothalamic tract, parasympathetic fibers from the vagus nerve, and the hypothalamic pituitary axis (HPA) where the CNS interfaces with the endocrine system11,12. It has been shown that the brain-gut axis influences gut function, contributing to MS-induced colonic injury13,14. Corticotropin-releasing hormone (CRH) is one of the primary brain-gut axis mediators in response to MS-induced behavioural, neuroendocrine, and autonomic changes15. CRH is released from the hypothalamus and stimulates adrenocorticotropic hormone secretion from the pituitary gland, which in turn leads to cortisol release from the adrenal glands15. In addition, CRH influences the activities of intestinal cells, such as immune cells, epithelial cells, enteric neurons, and smooth muscle cells15. Moussauoi et al. have shown that hypersensitivity to corticosteroids increases intestinal permeability in a newborn rat undergoing MS16. CRH-induced acetylcholine release is associated with increased macromolecular permeability of the colon in neonatal rats after MS17.
CRHR1 and CRHR2 are the two known G-protein coupled CRH receptors18. Interestingly, CRHR1 promotes intestinal inflammation and angiogenesis in an animal model of colitis, but the effects of CRHR1 are reversed by CRHR2 activation19. This suggests a dual role of CRH in regulating mucosal injury. Our study aims to distinguish the roles of CRHR1 and CRHR2 in MS-induced intestinal injury and repair during early postnatal life (postnatal days 5–9) in mice. This knowledge will facilitate the design of experimental treatments and prevention strategies for neonatal intestinal injury.
MS induced colonic inflammation through CRHR1
Similar to what we have previously demonstrated6, MS induced morphological damage in the colon, but not in the ileum (Fig. 1A,B). In addition, MS induced a significant increase in CRH levels in plasma compared to controls (Fig. 1C).
To elucidate the roles of CRHR1 and CRHR2 in MS-induced gut injury, we administered: i) Astressin, a non-specific CRHR antagonist of both CRHR1 and CRHR2, ii) Antalarmin, a CRHR1 antagonist, or iii) Astressin-2β, a CRHR2 antagonist prior to MS on each day from postnatal day 5 to 9 (Fig. 1D).
Our group has shown that MS induces the expression of pro-inflammatory cytokines IL-6, TNFα and iNOS in colonic epithelium5. In addition, these cytokines are upregulated in neonatal intestinal diseases such as NEC20,21. In the present study, the increases in IL6, TNFa and iNOS were inhibited by pre-treatment with Astressin (Fig. 1E–G). Similarly, Antalarmin, but not Astressin-2β, prevented the MS-induced elevation in pro-inflammatory cytokines (Fig. 1E–G). These results confirm that MS induces an increase in pro-inflammatory cytokines via CRH, which can be inhibited by blocking CRHR1.
MS-induced mucosal injury is dependent on CRHR1
We further investigated the effects of CRHRs on mucosal morphology, immune activation and colonic permeability. MS caused colonic morphological damage (Fig. 2A,B,K), a reduction in crypt length (Fig. 2L), and a loss of goblet cells (Fig. 2F,G,M). However, the administration of Antalarmin and Astressin during MS improved colonic morphology (Fig. 2C,D,K), increased crypt length (Fig. 2L) and the number of goblet cells per crypt (Fig. 2H,J,M). Treatment with Astressin-2β did not rescue the MS-induced colonic injury (Fig. 2E,J).
We have reported that levels of myeloperoxidase (MPO), a pro-inflammatory enzyme highly expressed in neutrophils, are increased following MS22. The current results are in accordance with the above findings (Fig. 2N). In addition, administration of Antalarmin reduced MPO expression to a level similar to control. On the contrary, the other two CRH receptor antagonists, Astressin and Astressin-2β, did not exert any effects on MPO levels which remained similar to MS alone.
NF-κB plays a key role in initiating and regulating inflammation, and has been implicated in inflammatory bowel disease23,24,25. To elucidate whether NF-κB acts as the mediator for intestinal inflammation downstream of CRHR1, we examined its protein expression. The ratio of phosphorylated to total NF-κB was higher in the MS group compared to controls, and was rescued by Antalarmin, but not Astressin or Astressin-2β (Fig. 2O,P).
We have previously established an experimental protocol to study intestinal permeability in MS using Ussing Chamber. Only colonic trans-cellular permeability increased in the MS group6 and the increase was inhibited by the administration of Antalarmin and Astressin, whereas Astressin-2β did not (Fig. 2Q).
These results indicate that the CRHR1 pathway is involved in MS-associated changes in mucosal morphology, NF-κB phosphorylation, inflammation, and permeability. In contrast, the antagonist of CRHR2, Astressin-2β, did not exert any effect on morphology, immune activation and colonic permeability. Taken together, these results demonstrated that selective inhibition of CRHR1 activity with Antalarmin reduces MS-induced colonic injury.
MS induced the activation of Lgr5+ IESCs and promoted epithelial cell proliferation
We hypothesized that in response to MS, intestinal stem cells induce gut repair and prevent further intestinal damage. To test this hypothesis, we performed MS experiments in Lgr5-EGFP-IRES-creERT2 pups, as their Lgr5+ intestinal epithelial stem cells (IESCs) are GFP-positive and can be easily visualized. After MS, the expression of Lgr5+ IESCs was increased at the base of the crypts, compared to controls (Fig. 3A,B,O, blue arrow). Moreover, Ki67+ proliferating cells were also increased in the MS group (Fig. 3F,G,P). Double staining of Lgr5 and Ki67 in the intestine of pups subjected to MS indicated that Lgr5+ IESCs were proliferative (Fig. 3K–N, yellow arrow). These results indicated that Lgr5+ IESCs were activated and proliferated during MS, representing a compensatory mechanism in response to MS-induced colonic injury.
CRHR2 mediated MS-induced increases in Lgr5+ IESCs and intestinal repair through IL-22
To distinguish the roles of CRHR1 from CRHR2 in MS-induced activation of Lgr5+ IESCs, we compared the effects of specific CRHR inhibitors. Lgr5+ IESCs and Lgr5 mRNA levels in the colon were significantly increased by MS compared to control, and this increase was also observed when Antalarmin was administered (Fig. 3C,O). In contrast, the increase in Lgr5+ IESCs and Lgr5 mRNA levels was inhibited by Astressin and Astressin-2β (Fig. 3D,E,O). Similarly to Lgr5, the number of Ki67+ proliferating cells increased in Antalarmin, but not in Astressin-2β (Fig. 3H,I,J,P).
Thus, selective inhibition of CRHR2 blunts Lgr5 activation during MS, indicating a role for CRHR2 signaling in intestinal repair. The selective inhibition of CRHR1 did not alter Lgr5 expression. This would potentially allow specific targeting of CRHR1 to down regulate colonic injury, while maintaining the CRHR2-mediated repair mechanism.
To further assess the epithelial differentiation potential of Lgr5+ IESCs in response to MS, we quantified the expression of differentiation marker genes of goblet cells, the predominant type of cell in the colon, and Paneth cells. The mRNA levels of the goblet cell marker Muc2 (Fig. 3Q) and the Paneth cell marker Lyz1 (Lysozyme1, Fig. 3R) were significantly lower in the MS group, compared to controls, but were significantly increased in mice treated with Antalarmin. In contrast, in the Astressin-2β treated group, Muc2 and Lyz1 levels did not fully recover to control levels (Fig. 3Q,R).
To assess the gut repair mechanisms, we measured levels of IL-22 mRNA and the ratio of phosphorylated STAT3 to total STAT3, which are factors implicated in intestinal epithelial tissue regeneration and remodeling26,27. IL-22 (Fig. 3S) and phosphorylated STAT3 (Fig. 3T,U) increased in the MS group compared to the control group. The CRHR2 blocker Astressin-2β inhibited such increase.
Thus, CRHR2 is required for stem cell activation, and epithelium proliferation and differentiation during MS, and mediates intestinal repair in response to MS-induced injury.
CRHR1 restored MS-induced microbiome changes
Changes in the intestinal microbiota are associated with the development of impaired gut function during MS7. To investigate the role of CRHRs in alterations of the microbiome during MS, we compared the relative levels of specific microbial phyla in colonic epithelium. The ratio of Firmicutes to Bacteroidetes was significantly increased by MS, but was almost completely restored by administration of either Antalarmin or Astressin, but not Astressin-2β (Fig. 4A). The MS-induced increase in the Firmicutes to Bacteroidetes ratio was due primarily to a relative decrease in the Bacteroidetes phylum rather than changes in Firmicutes (Fig. 4B,C). These results demonstrate that MS induces changes in the colonic microbiota, and that CRHRs are involved in these alterations, particularly CRHR1.
We have demonstrated that treatment with the CRHR1 antagonist Antalarmin protects against colonic injury following MS by preventing changes in colonic morphology, inflammation, permeability and microbiota. Astressin-2β, a CRHR2 antagonist, inhibited intestinal stem cell activity and subsequent epithelial cell repair induced by MS. These results indicate that the interactions between the brain and the gut are modulated by opposing effects of CRHR1 and CRHR2. CRHR1 induces colonic injury while CRHR2 promotes healing and repair of the intestine (Fig. 5).
Stress during early life plays an important role in gut disorders such as NEC28; however, there is limited information on the role of CRHRs in mediating neonatal intestinal injury or intestinal repair. Our data suggests the opposing roles for CRHR1 and CRHR2, in agreement with previous experiments in adult mice with gut injury such as colitis19,29,30. Inhibition of CRHR1 has been shown to dramatically reduce intestinal injury in animal models of colitis19,29,30. Herein, we demonstrated that blocking CRHR1 prior to intestinal injury protects mouse pups from MS-induced damage, changes in gut morphology, mucosal inflammation, and barrier function. We found that the elevation in MPO expression induced by MS was rescued by the CRHR1 antagonist but not by the CRHR2 antagonist. Additionally, our MS gut injury model revealed a role of CRHR2 in mucosal repair. Activation of CRHR2 inhibits CRHR1-induced intestinal inflammation, as well as endogenous and inflammatory angiogenesis19. Furthermore, CRHR2 antagonists aggravate disease, delay healing, and decrease epithelial cell proliferation after DSS-induced colitis26.
It has been shown that Lgr5+ IESCs are responsible for epithelial cell renewal and gut repair by giving rise to functional Paneth cells and goblet cells9. MS markedly alters the distribution of intestinal epithelial secretory cells in the duodenum in association with changes in IESCs31. We have demonstrated that in MS, Lgr5+ IESCs are activated at the base of crypts where there is an increase in epithelial cell proliferation. CRHR2 is involved in epithelial tissue repair by promoting Lgr5+ IESCs. CRHR2 activation can initiate intestinal wound repair via phosphorylation of STAT326, which subsequently increases the expression of IL-2227. A recent study suggested that IL-22 directly regulates IESCs during epithelial regeneration after tissue damage32. We confirmed that MS, mediated by CRHR2, increases phosphorylation of STAT3 and IL-22, resulting in increased expression of Lgr5+ IESCs. Components of this pathway can be targeted clinically for treatment of injuries associated with Lgr5+ IESC dysfunction, such as NEC in stressed prematurely born infants.
Mice in the neonatal period are highly prone to alterations in their microbiota composition, resulting from exposure to changes in the environment33. These early microbial changes can be durable and persist into adulthood7. For these reasons, we investigated changes in the microbiota following MS in early life, and found that MS changes the microbiota by decreasing levels of Bacteroidetes, resulting in an increased Firmicutes to Bacteroidetes ratio. This finding is in line with studies of IBS in humans, in which Bacteroidetes is reduced, along with microbial diversity34,35. The microbiota of IBS patients compared to controls has a two-fold increase in the ratio of Firmicutes to Bacteroidetes36,37. In addition, IBS patients have increased expression of TLR4 and TLR5, which initiate innate immune responses through microbial stimuli38. Probiotics have been shown to stabilize intestinal microbiota in clinical trials39, alleviate inflammation40, and improve IBS symptoms41. We found that the CRHR1 selective antagonist Antalarmin and the non-selective CRHR antagonist Astressin can both partially rescue microbial dysbiosis caused by MS, while the CRHR2-selective antagonist Astressin-2β cannot. These results emphasize the potential therapeutic effects of Antalarmin in maintaining microbiota balance during stress induced by MS. However, at this point, we cannot rule out the possibility that disturbances in microbiota diversity altered CRH signaling. A full characterization of the role of microbiota and CRH signaling in neonatal intestinal disorders is needed.
Blocking CRHR1 directly improves motility, endocrine secretion, immune response, and inflammation in the mouse gut19,29,30,40,41. Our study demonstrated that the CRHR1 antagonist Antalarmin reduces colonic damage by modulating the mucosal immune system, improving intestinal barrier function and stabilizing gut microbiota in a model of MS. Blocking CRHR1 with Antalarmin did not interfere with Lgr5+ IESC-mediated initiation of epithelial repair, while the CRHR2-selective antagonist Astressin-2β did. Since 2004, various CRHR1 antagonists have entered clinical trials for the treatment of depression, IBS, and social anxiety disorder. However, none of the investigated CRHR1 antagonists have successfully completed a Phase III clinical trial42. This discrepancy is likely related to the differences in route of administration, dose, and side effects of CRHR1 antagonists between animals and humans. Nevertheless, our study demonstrates the benefits of blocking the CRHR1 pathway in an experimental model of neonatal bowel injury.
Preterm babies fed while in incubators have been shown to experience maternal separation. Preterm birth and MS cause a myriad of complications including alterations in the gut microbial composition and changes in barrier function43. Although our MS model induces a localized moderate colonic injury, which is not as severe as that found in NEC, there are studies that demonstrate that MS in mouse pups causes activation of the hypothalamic–pituitary–adrenal axis (an indicator of stress), colonic epithelial barrier dysfunction and bowel inflammation44. This could be likened to that seen in the early stages of NEC45. Hence, the mechanisms by which Antalarmin affects the CRHR1 pathway could represent a novel therapeutic strategy in premature babies to prevent the progression from early/suspected to advanced NEC. It is notable that some of the CRHR1-associated beneficial effects could be specific to NEC, since the mechanism of NEC development does not resemble that of intestinal disorders that develop in adulthood. For example, MPO elevation was only found in the intestinal mucosa of NEC46 and IBD47 but not in IBS47 patients. Therefore, further experimental studies are needed to investigate the specific role of Antalarmin in NEC initiation and progression.
In conclusion, our study demonstrates that the brain-gut axis acts through CRH to modulate colonic injury during maternal separation. CRHR1 signaling mediates intestinal injury by promoting intestinal inflammation, affecting epithelial cell permeability and morphology, and altering the colonic microbiome in response to MS. In contrast, CRHR2 mediates the activation of intestinal stem cells and is important for epithelial repair after injury. The findings of this study suggest, therefore, that inhibiting the action of CRHR1, while promoting the activity of CRHR2 could be a novel strategy to prevent gut injury in preterm infants.
Animals and maternal separation
All animal experiments (no. 32238) were approved by, and followed according to guidelines and regulations from the Animal Care Committee at The Hospital for Sick Children.
Postnatal day 5 C57BL/6 mouse pups were randomly assigned to control (n = 10) and maternal separation (n = 40) groups. To establish our MS model, C57BL/6 pups were separated from their mothers at the same time each day for 3 hours between postnatal day five (P5) and day nine (P9), as described previously1. Control neonatal mice remained with their mothers for the duration of the study. Several litters were used and pups from each litter were randomly assigned to each of the experimental groups to eliminate potential differences between litters and litter effects. Lgr5-EGFP-IRES-creERT2 mice were obtained from The Jackson Laboratory (Sacramento, USA), to study the state of intestinal stem cells in their resulting pups after exposure to our MS model.
Pups were injected with the following drugs at the same time each day between P5 and P9, before MS occurred: (i) Antalarmin, a CRHR1 antagonist (20 mg/kg/day, subcutaneously, n = 10), (ii) Astressin-2β, a CRHR2 antagonist (150 μg/kg/day, subcutaneously, n = 10), or (iii) Astressin, a non-specific CRHR antagonist inhibiting both CRHR1 and CRHR2 (60 μg/kg/day, intraperitoneally, n = 10). Injection was performed without any complications. Mice in the MS group (n = 10) received an injection of saline placebo vehicle. Routes of administration and doses were selected according to a previous report31. MS, as described above, was performed immediately after injections. On P9, mice pups were sacrificed and colonic tissue was harvested.
Colonic tissues were fixed in 4% paraformaldehyde, embedded in paraffin, cross-sectioned (5 μm) and stained with standard hematoxylin and eosin (H&E). Goblet cells were visualized by immunofluorescence staining according to the protocol described below. Histological scores, crypt length and the number of goblet cells per crypt (average of goblet cells counted on 5 crypts) were determined by three blinded independent investigators. Injury grades were assigned based on a previous publication6.
Blood was collected from neck arteries and veins upon sacrifice on postnatal day 9 by decapitation and centrifuged (10 minutes, 2500xg) to harvest plasma. CRH levels were measured by enzyme-linked immunosorbent assay (ELISA) (Kamiya Biomedical, Seattle, WA). Absorbance was determined using a micro-plate reader with an optical density of 412 nm (Molecular Devices SpectraMax Gemini EM) and concentration was determined using a standard curve.
Gene expression analysis
RNA was isolated from the proximal colon with TRIzol (Invitrogen, Carlsbad, CA). Total RNA (1 μg) was reverse transcribed by qScript cDNA supermix (Quanta Biosciences, Gaithersburg) and SYBR green-based qRT–PCR was performed with advanced qPCR Supermix (Wisent Inc., Quebec, Canada). The qPCR primer sequences (Supplementary Table S1) were taken from previous publications22,48,49, demonstrating primer efficiency, and were compared to the Nucleotide BLAST database for confirmation. GAPDH levels were similar in all experimental groups and served as control for normalization. Gene expression levels were quantified using Bio-Rad CFX Manager Software (Hercules, USA).
A Ussing chamber was used to measure trans-epithelial resistance and trans-cellular permeability as previously reported6,50,51. Briefly, fresh colon tissue specimen including the epithelium and muscle layers (no stripping was performed) were cut longitudinally to expose the lumen, and mounted into Ussing chamber (Physiologic Instruments, San Diego, CA). The trans-epithelial resistance (Rte) of the colon was measured. Unaltered Rte at the beginning and the end of the experiment indicated that the tissues remained intact during the experiment. Trans-cellular permeability to large molecules was measured by assessing the mucosal-to-serosal passage of Horseradish Peroxidase (HRP, 44 kDa) (Sigma, St. Louis, MO). 0.4 mg/ml HRP was added to the apical side and its translocation was measured on the basolateral side after 20 minutes6. The basolateral concentration of HRP was determined using a kinetic enzymatic assay and measuring the optical density (485 nm) with a micro-plate reader (Molecular Devices SpectraMax Gemini EM). Permeability of HRP was expressed as concentration/area/minute.
Myeloperoxidase (MPO) assay
Protein was isolated from colonic tissue by homogenization in tissue extraction buffer (Invitrogen, CA, USA) containing Protease Inhibitor Single-Use Cocktail (Sigma). Protein concentration was determined using bicinchoninic acid protein assay (Thermo Scientific, IL, USA).
MPO is a pro-inflammatory enzyme that is highly expressed in neutrophils22. MPO concentrations were determined using the Colorimetric Activity Assay Kit (Sigma). Absorbance readings at 412 nm were compared to a standard curve and concentration was expressed as μmol/mg protein.
Proteins were isolated as described above and were separated by NuPAGE 4–12% BisTris gel electrophoresis and transferred to a polyvinylidene fluoride (PVDF) membrane using iBlot Gel Transfer Device (Life Technologies, MD, USA). The membrane was probed with antibodies for phosphorylated NF-κB (3031, Cell Signaling Technology CST, Danvers, MA), NF-κB (8242, CST), phosphorylated STAT3 (9145, CST) and STAT3 (4904, CST). β-actin (4967, CST) served as a loading control. Blots were developed using an ECL Plus kit (Invitrogen, CA, USA). Band intensities were quantified using an Odyssey scanner (LI-COR Biosciences, Lincoln, NE).
Staining for Muc2 (NB120-11197, Novus Biologicals, CO) and Ki67 (ab15580, Abcam Inc., Cambridge, MA) was performed to measure epithelial goblet cell numbers and enterocyte proliferation, respectively. Tissue sections were incubated with primary antibodies (1:500 dilution) overnight at 4 °C and with fluorescent secondary antibodies (1:1000) (Life Technologies, MD, USA) for two hours at room temperature. Positively stained cells were counted in five contiguous crypt units (for each section), and expressed as the number of positive cells per crypt.
To avoid contamination, mouse pups were sacrificed in a biosafety cabinet and one fragment of the whole proximal colon and its contents (1 cm) were harvested. DNA was extracted with TRIzol (Invitrogen, Carlsbad, CA) according to the manufacturer’s instructions. DNA was reconstituted to 40ng and examined by qPCR, using qPCR Supermix (Wisent Inc., Quebec, Canada) as described above. Primers sequences for 16 S ribosomal RNA genes for Bacteroidetes, Firmicutes, and Eubacteria (Universal) obtained from a previous publication49, are shown in the Supplementary Table S1.
Results are presented as mean ± SD, as data were normally distributed (Kolmogorov-Smirnov test). Groups were compared using Student’s t-test or one-way ANOVA with Bonferroni correction as appropriate. P < 0.05 was considered significant.
How to cite this article: Li, B. et al. Inhibition of corticotropin-releasing hormone receptor 1 and activation of receptor 2 protect against colonic injury and promote epithelium repair. Sci. Rep. 7, 46616; doi: 10.1038/srep46616 (2017).
Publisher's note: Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Longstaffe, S. Maternal deprivation masking as mental retardation in children. Canadian family physician 25, 1365–1367 (1979).
Barreau, F., Ferrier, L., Fioramonti, J. & Bueno, L. New insights in the etiology and pathophysiology of irritable bowel syndrome: contribution of neonatal stress models. Pediatric research 62, 240–245 (2007).
Soderholm, J. D. et al. Neonatal maternal separation predisposes adult rats to colonic barrier dysfunction in response to mild stress. American journal of physiology. Gastrointestinal and liver physiology 283, G1257–1263 (2002).
Zani, A. et al. A spectrum of intestinal injury models in neonatal mice. Pediatric surgery international 32, 65–70 (2016).
Li, B. et al. Endoplasmic reticulum stress is involved in the colonic epithelium damage induced by maternal separation. Journal of pediatric surgery 51, 1001–1004 (2016).
Li, B. et al. Early maternal separation induces alterations of colonic epithelial permeability and morphology. Pediatric surgery international 30, 1217–1222 (2014).
De Palma, G. et al. Microbiota and host determinants of behavioural phenotype in maternally separated mice. Nature communications 6, 7735 (2015).
Barker, N. et al. Identification of stem cells in small intestine and colon by marker gene Lgr5. Nature 449, 1003–1007 (2007).
Barker, N. & Clevers, H. Leucine-rich repeat-containing G-protein-coupled receptors as markers of adult stem cells. Gastroenterology 138, 1681–1696 (2010).
Bonaz, B. & Sabate, J. M. [Brain-gut axis dysfunction]. Gastroenterologie clinique et biologique 33 Suppl 1, S48–58 (2009).
Gaman, A. & Kuo, B. Neuromodulatory processes of the brain-gut axis. Neuromodulation 11, 249–259 (2008).
Drake, M. J. et al. Neural control of the lower urinary and gastrointestinal tracts: supraspinal CNS mechanisms. Neurourology and urodynamics 29, 119–127 (2010).
Cryan, J. F. & O’Mahony, S. M. The microbiome-gut-brain axis: from bowel to behavior. Neurogastroenterology and motility 23, 187–192 (2011).
Fukudo, S., Nomura, T., Muranaka, M. & Taguchi, F. Brain-gut response to stress and cholinergic stimulation in irritable bowel syndrome. A preliminary study. Journal of clinical gastroenterology 17, 133–141 (1993).
Behan, D. P. et al. Neurobiology of corticotropin releasing factor (CRF) receptors and CRF-binding protein: implications for the treatment of CNS disorders. Molecular psychiatry 1, 265–277 (1996).
Moussaoui, N. et al. Changes in intestinal glucocorticoid sensitivity in early life shape the risk of epithelial barrier defect in maternal-deprived rats. PloS one 9, e88382 (2014).
Gareau, M. G., Jury, J. & Perdue, M. H. Neonatal maternal separation of rat pups results in abnormal cholinergic regulation of epithelial permeability. American journal of physiology. Gastrointestinal and liver physiology 293, G198–203 (2007).
Perrin, M. H. & Vale, W. W. Corticotropin releasing factor receptors and their ligand family. Annals of the New York Academy of Sciences 885, 312–328 (1999).
Im, E. et al. Corticotropin-releasing hormone family of peptides regulates intestinal angiogenesis. Gastroenterology 138, 2457–2467, 2467 e2451-2455 (2010).
Chen, Y. et al. Formula feeding and systemic hypoxia synergistically induce intestinal hypoxia in experimental necrotizing enterocolitis. Pediatric surgery international 32, 1115–1119 (2016).
Rentea, R. M. et al. Early enteral stressors in newborns increase inflammatory cytokine expression in a neonatal necrotizing enterocolitis rat model. European journal of pediatric surgery 23, 39–47 (2013).
Li, B. et al. Intestinal epithelial injury induced by maternal separation is protected by hydrogen sulfide. Journal of pediatric surgery 52, 40–44 (2017).
Neurath, M. F. & Pettersson, S. Predominant role of NF-kappa B p65 in the pathogenesis of chronic intestinal inflammation. Immunobiology 198, 91–98 (1997).
Schmid, R. M., Adler, G. & Liptay, S. Activation of NFkappaB in inflammatory bowel disease. Gut 43, 587–588 (1998).
Borm, M. E., van Bodegraven, A. A., Mulder, C. J., Kraal, G. & Bouma, G. A NFKB1 promoter polymorphism is involved in susceptibility to ulcerative colitis. International journal of immunogenetics 32, 401–405 (2005).
Hoffman, J. M., Baritaki, S., Ruiz, J. J., Sideri, A. & Pothoulakis, C. Corticotropin-Releasing Hormone Receptor 2 Signaling Promotes Mucosal Repair Responses after Colitis. The American journal of pathology 186, 134–144 (2016).
Pickert, G. et al. STAT3 links IL-22 signaling in intestinal epithelial cells to mucosal wound healing. The Journal of experimental medicine 206, 1465–1472 (2009).
Decaro, M. H. & Vain, N. E. Hyperglycaemia in preterm neonates: what to know, what to do. Early human development 87 Suppl 1, S19–22 (2011).
la Fleur, S. E., Wick, E. C., Idumalla, P. S., Grady, E. F. & Bhargava, A. Role of peripheral corticotropin-releasing factor and urocortin II in intestinal inflammation and motility in terminal ileum. Proceedings of the National Academy of Sciences of the United States of America 102, 7647–7652 (2005).
Wlk, M. et al. Corticotropin-releasing hormone antagonists possess anti-inflammatory effects in the mouse ileum. Gastroenterology 123, 505–515 (2002).
Estienne, M. et al. Maternal deprivation alters epithelial secretory cell lineages in rat duodenum: role of CRF-related peptides. Gut 59, 744–751 (2010).
Lindemans, C. A. et al. Interleukin-22 promotes intestinal-stem-cell-mediated epithelial regeneration. Nature 528, 560–564 (2015).
Koenig, J. E. et al. Succession of microbial consortia in the developing infant gut microbiome. Proceedings of the National Academy of Sciences of the United States of America 108 Suppl 1, 4578–4585 (2011).
Krogius-Kurikka, L. et al. Microbial community analysis reveals high level phylogenetic alterations in the overall gastrointestinal microbiota of diarrhoea-predominant irritable bowel syndrome sufferers. BMC gastroenterology 9, 95 (2009).
Carroll, I. M., Ringel-Kulka, T., Siddle, J. P. & Ringel, Y. Alterations in composition and diversity of the intestinal microbiota in patients with diarrhea-predominant irritable bowel syndrome. Neurogastroenterology and motility 24, 521–530, e248 (2012).
Jeffery, I. B. et al. An irritable bowel syndrome subtype defined by species-specific alterations in faecal microbiota. Gut 61, 997–1006 (2012).
Rajilic-Stojanovic, M. et al. Global and deep molecular analysis of microbiota signatures in fecal samples from patients with irritable bowel syndrome. Gastroenterology 141, 1792–1801 (2011).
Brint, E. K., MacSharry, J., Fanning, A., Shanahan, F. & Quigley, E. M. Differential expression of toll-like receptors in patients with irritable bowel syndrome. The American journal of gastroenterology 106, 329–336 (2011).
Ki Cha, B. et al. The effect of a multispecies probiotic mixture on the symptoms and fecal microbiota in diarrhea-dominant irritable bowel syndrome: a randomized, double-blind, placebo-controlled trial. Journal of clinical gastroenterology 46, 220–227 (2012).
Guglielmetti, S., Mora, D., Gschwender, M. & Popp, K. Randomised clinical trial: Bifidobacterium bifidum MIMBb75 significantly alleviates irritable bowel syndrome and improves quality of life–a double-blind, placebo-controlled study. Alimentary pharmacology & therapeutics 33, 1123–1132 (2011).
Silk, D. B., Davis, A., Vulevic, J., Tzortzis, G. & Gibson, G. R. Clinical trial: the effects of a trans-galactooligosaccharide prebiotic on faecal microbiota and symptoms in irritable bowel syndrome. Alimentary pharmacology & therapeutics 29, 508–518 (2009).
Koob, G. F. & Zorrilla, E. P. Update on corticotropin-releasing factor pharmacotherapy for psychiatric disorders: a revisionist view. Neuropsychopharmacology 37, 308–309 (2012).
Cong, X. et al. Gut Microbiome and Infant Health: Brain-Gut-Microbiota Axis and Host Genetic Factors. The Yale journal of biology and medicine 89, 299–308 (2016).
Gareau, M. G., Wine, E., Reardon, C. & Sherman, P. M. Probiotics prevent death caused by Citrobacter rodentium infection in neonatal mice. The Journal of infectious diseases 201, 81–91 (2010).
Halpern, M. D. & Denning, P. W. The role of intestinal epithelial barrier function in the development of NEC. Tissue barriers 3, e1000707 (2015).
Zani, A. et al. Amniotic fluid stem cells improve survival and enhance repair of damaged intestine in necrotising enterocolitis via a COX-2 dependent mechanism. Gut 63, 300–309 (2014).
Kristjansson, G., Venge, P., Wanders, A., Loof, L. & Hallgren, R. Clinical and subclinical intestinal inflammation assessed by the mucosal patch technique: studies of mucosal neutrophil and eosinophil activation in inflammatory bowel diseases and irritable bowel syndrome. Gut 53, 1806–1812 (2004).
de Groot, R. E. et al. Retromer dependent recycling of the Wnt secretion factor Wls is dispensable for stem cell maintenance in the mammalian intestinal epithelium. PloS one 8, e76971 (2013).
Grasberger, H. et al. Increased Expression of DUOX2 Is an Epithelial Response to Mucosal Dysbiosis Required for Immune Homeostasis in Mouse Intestine. Gastroenterology 149, 1849–1859 (2015).
Song, P. et al. Bile deficiency induces changes in intestinal Cl(−) and HCO3(−) secretions in mice. Acta physiologica 211, 421–433 (2014).
Matter, K. & Balda, M. S. Functional analysis of tight junctions. Methods 30, 228–234 (2003).
This work was supported by the Trainee Startup Fund, Research Institute, The Hospital for Sick Children. RYW is the recipient of a Vanier Graduate Scholarship from the Canadian Institutes of Health Research. PMS is the recipient of a Canada Research Chair in Gastrointestinal Disease. PDO is supported by Operational Funds from The Hospital for Sick Children, the Natural Sciences and Engineering Research Council of Canada (NSERC) grant 500865, and by the Canadian Institutes of Health Research (CIHR), Grant PJT-149046. AP was endorsed by the Robert M. Filler Chair of Surgery, The Hospital for Sick Children, and by Canadian Institutes of Health Research (CIHR) Foundation Grant (353857). The authors thank Celine Bourdon for her helpful comments on the experiments and manuscript, and Koroboshka Brand-Arzamendi for the illustration (Figure 5).
The authors declare no competing financial interests.
About this article
Cite this article
Li, B., Lee, C., Filler, T. et al. Inhibition of corticotropin-releasing hormone receptor 1 and activation of receptor 2 protect against colonic injury and promote epithelium repair. Sci Rep 7, 46616 (2017). https://doi.org/10.1038/srep46616
Molecular Medicine (2022)
Gene expression analysis in NSAID-induced rat small intestinal disease model with the intervention of berberine by the liquid chip technology
Genes and Environment (2021)
Potential Molecular Mechanism and Biomarker Investigation for Spinal Cord Injury Based on Bioinformatics Analysis
Journal of Molecular Neuroscience (2020)
Calcium/calmodulin-dependent protein kinase IV signaling pathway is upregulated in experimental necrotizing enterocolitis
Pediatric Surgery International (2020)
Pediatric Surgery International (2020)