Abstract
Necrotizing enterocolitis (NEC) is a leading cause of mortality in preterm newborns. Intestinal barrier dysfunction is one key event in NEC pathogenesis. Human β-defensin-3 (hBD3), one member of cationic host defence peptides, was reported to reduce the development of necrotizing enterocolitis in a neonatal rat model. And autophagy was induced in the intestine of human and animals with NEC. We hypothesized that regulation of autophagy might play a critical role in hBD3-mediated protection against NEC injury. Autophagy activity was evaluated both in intestinal epithelial cells and in NEC models. Newborn Sprague-Dawley rats were divided randomly into four groups: Control + NS, Control + rapamycin, NEC + NS, and NEC + hBD3. Body weight, histological score, survival time, enterocyte migration and mucosal barrier were recorded. Our results showed that hBD3 pretreatment could effectively inhibit autophagy activity in cultured IEC-6 and Caco2 enterocytes, and CXCR4 might be involved in hBD3-mediated autophagy suppression. Moreover, hBD3-induced inhibition of autophagy significantly promoted the intestinal epithelial cell migration by wound healing assay and transwell migration assay. In the rat model of NEC, hBD3 could noticeably reduce the expression of autophagy-activated proteins, down-regulate the expression of inflammatory mediators, and promote the mucosal integrity. Our data suggest an additional role of hBD3-mediated protection against intestinal mucosal injury: inhibition of over-activated autophagy in enterocytes.
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Introduction
Necrotizing enterocolitis (NEC) is a digestive system disease which seriously threatens newborns as a result of multiple factors, such as premature birth, intestinal dysbacteriosis, formula feeding, and genetic predisposition1,2. Despite advancements in neonatal medicine, the mortality associated with NEC still ranges from 20% to 30%3. Even though many risk factors have been proved to be relevant4,5, the exact etiology and pathogenesis of NEC remain unknown6. Intestinal barrier dysfunction in premature newborns is one key cause leading to the onset of NEC.
Autophagy is an intracellular degrading and recycling pathway of proteins and organelles that relies on lysosomes, and is involved in many important biological processes, such as cell survival, cytoskeleton remodeling, antigen presentation, etc.7,8. Recent evidence has shown that uncontrolled activation of autophagy has been identified as a risk factor for the development of NEC9. Excessive activation of autophagy could damage intestinal barrier and increase permeability through degradation of tight junction protein such as claudin-210. Moreover, rapamycin (a classic autophagy inducer) has been confirmed to significantly inhibit the migration of several cell types including intestinal epithelial cells both in vitro and in vivo11, which suggests that autophagy participates in the repair process of intestinal mucosal barrier and plays an important role in maintaining the integrity of intestinal mucosal barrier.
Human beta-defensin-3 (hBD3, OMIM: 606611), first detected in lesion tissues of psoriatic patients in 2001, is a cationic antibacterial peptide with antimicrobial activity and immune modulation linking innate and adaptive immunity12,13. Jenke et al.14 reported low beta defensin expression in severe NEC. In addition, we have previously reported that hBD3 treatment can significantly induce intestinal epithelial cell migration and reduce the severity and mortality of NEC model in neonatal rats15. However, the underlying mechanism has not been elucidated clearly.
We now hypothesized that regulation of autophagy played a critical role in hBD3-mediated protection against NEC injury. Consequently, the present study was designed to shed light on the effect of hBD3 on autophagy both in intestinal epithelial cells and in experimental NEC model.
Results
Pharmacologic induction of autophagy in intestinal epithelial cells
In order to detect the optimal concentration and incubation period, intestinal epithelial cells IEC-6 and Caco2 were respectively incubated with rapamycin (a classic autophagy inducer) for the indicated concentrations and periods over a broad range. After the rapamycin administration, the conversion of microtubule-associated protein 1 light chain 3-I (LC3-I) to LC3-II, as the hallmark of autophagy, was increased both in Caco2 and IEC-6 cells. Beclin1, another essential protein as a way to monitor autophagy, was also increased after rapamycin treatment. In addition, p62 (also known as sequestosome-1), which serves as a link between LC3 and ubiquitinated substrates, was decreased in rapamycin-treated cells. According to the expression of autophagy-related proteins, the autophagy flux in Caco2 increased significantly after being incubated with 50 nM rapamycin for 24 h (Fig. 1A–C,E). Accordingly, the autophagy in IEC-6 was effectively induced by rapamycin at the concentration of 200 nM for 24 h (Fig. 1A,B,D,F).
hBD3 inhibited autophagy in intestinal epithelial cells
Wu et al. reported that beta-defensin-3 could suppress autophagy in macrophages16. Thus, we studied the effects of hBD3 on the autophagic process in the intestinal epithelial cells. The expression of Beclin1 and LC3-II/LC3-I ratio increased and protein p62 decreased with the treatment of rapamycin when compared with unstimulated control. A reversion of protein expression mentioned above was observed after the pretreatment of hBD3 at the concentration of 5 μg/ml for 12 h (Figs. 2A and 3B). The expression of p62 was also decreased by immunofluorescence, which was accordant with western blotting (Fig. 2B). Ad-mRFP-GFP-LC3 was used to monitor autophagic flux based on the different pH stabilities of mRFP and GFP, as the GFP signal would be quenched by the acidic environment of the lysosome. Therefore, autophagosomes were represented by the yellow merged dots (mRFP+ GFP+), while the autophagic flux indicated by the formation of autolysosomes was reflected by the red dots (mRFP+ GFP−). Our results demonstrated a significant decrease of mRFP-GFP colocalization dots and free red dots after hBD3 treatment compared with the autophagy induction group, confirming its inhibition of autophagic flux in IEC-6 cells (Fig. 2C–E). Transmission electron microscopy (TEM) was used to monitor the ultrastructure of IEC-6 and Caco2 cells. After the rapamycin exposure, degradative autophagic vacuoles (AVd) were markedly accumulated, while hBD3 treatment could decrease the formation of AVd (Fig. 2F). Taken together, hBD3 treatment could inhibit excessive autophagy in cultured intestinal epithelial cell.
Involvement of CXCR4 in hBD3-mediated autophagy suppression
It has been reported that CXCR4 was involved in mTOR-dependent migration of gastric carcinoma cells17. Moreover, structural analysis revealed similarities between hBD3 and SDF-1α, natural ligand of CXCR418,19. In order to confirm the role of CXCR4 signaling pathway in the process of hBD3-mediated autophagy suppression in enterocytes, CXCR4 inhibitor (AMD3100) and specific CXCR4 small interfering RNA (siRNA) were used to pretreat the intestinal epithelial cells. Compared with hBD3 treatment group, the autophagy-associated proteins Beclin1 and LC3-II/LC3-I ratio increased after incubation with 10 uM AMD3100 for 24 h, while protein p62, p-AKT and p-mTOR were showed in decline expression (Fig. 3A,B). Moreover, IEC-6 and Caco2 cells were transfected with CXCR4 siRNA to further confirm the results caused by CXCR4 inhibition. The knockdown efficiency of CXCR4 siRNA was approximately 60% and resulted in a remarkable reduction in CXCR4 expression compared with control siRNA (Fig. 3C,D). After being transfected with CXCR4 siRNA for 36 h, the expression of autophagy-associated proteins was evaluated and the results showed that the effects on protein expression induced by transfection of CXCR4 siRNA were more significant than that of inhibitor AMD3100 (Fig. 3E,F). Together, these findings indicated that the CXCR4 might be involved in the hBD3-induced autophagy inhibition.
hBD3-mediated autophagy suppression attenuated the inhibition of intestinal epithelial cell migration
Decreased mucosal barrier repairing capacity in neonates, especially in premature infants, is one major risk factor of necrotizing enterocolitis. Therefore, wound healing assay and transwell migration assay were conducted to measure the migration ability of IEC-6 cells in different groups. In our study, the migration distance of IEC-6 cells was significantly decreased in the group incubated with rapamycin compared with the unstimulated control. However, pretreatment of hBD3 could noticeably reverse the inhibition effect of rapamycin (Fig. 4A,B). The results of the transwell migration assay were consistent with the wound healing assay with the TGF-β1 as the positive control (Fig. 4C,D). IEC-6 cells were transfected with ATG7 siRNA to confirm the effect of hBD3-mediated autophagy suppression on the migration of intestinal epithelial cells. Knockdown efficiency of ATG7 siRNA was more than 65% and markedly down-regulated the protein expression of ATG7 compared with control siRNA (Fig. 4E,F). The migration distance of IEC-6 cells transfected with ATG7 siRNA increased obviously compared with autophagy induction group no matter whether hBD3 incubation or not, which indicated that hBD3 did regulate intestinal epithelial cell migration by inhibiting autophagy (Fig. 4G,H).
It has been reported that the Rho signaling pathway played an important role in the regulation of cell migration20. Thus, we first examined the protein expression of activated Rho (Rho-GTP) with GTP as the positive control and GDP as the negative control. Autophagy induced by rapamycin down-regulated the activation of Rho, while hBD3 markedly increased the conversion from Rho-GDP to Rho-GTP (Fig. 5A,C). In addition, the downstream effectors were also assessed. Phosphorylation of Myosin Light Chain 2 (MLC2) was detected by western blotting which demonstrated that hBD3 up-regulated the phosphorylation of MLC2 compared with the autophagy induction group (Fig. 5B,D). The accumulation of F-actin in IEC-6 and Caco2 cells incubated with fluorescein isothiocyanate labeled phalloidin was monitored. hBD3 could effectively attenuate the inhibition effect of rapamycin (Fig. 5E).
Taken together, we concluded that autophagy inhibited the migration of intestinal epithelial cells and hBD3 treatment could significantly mitigate the inhibition effect induced by autophagy, which was confirmed to be associated with the Rho activation, MLC2 phosphorylation and F-actin accumulation.
Preliminary evaluation of hBD3-mediated autophagy inhibition in rat NEC model
Sprague–Dawley neonatal rats were divided randomly into four groups: Control + NS, rapamycin, NEC + NS and NEC + hBD3. The rat NEC model was further optimized in our study, including hypertonic formula feeding combined with asphyxia-cold stress exposure15,21,22, to better stimulate clinical development of NEC. The effect of hBD3 on autophagy in the ileum was assessed first. The conversion of LC3-I to LC3-II and protein expression of Beclin1 were significantly increased in group rapamycin and group NEC + NS, while the protein expression of p62 was unchanged significantly. Autophagic activity was down-regulated after hBD3 treatment (Fig. 6A). The results of our study showed that body weight of the formula-fed rats was markedly lower than that of the mother-fed rats. Rats in group NEC suffered obvious weight loss, however, the body weight increased to some extent after hBD3 intervention and the difference was statistically significant (P = 0.007, Supplemental Fig. 1 and Table S1). The survival rate of rats was significantly decreased from 100% in control group to 42% in NEC group, which could be effectively improved by the treatment of hBD3 (P < 0.001, Fig. 6B and Table S2). All pups were sacrificed and the entire digestive tract was displayed to present the macroscopic changes among different groups. Edema and necrosis of the small intestine was observed in group NEC, which could be effectively ameliorated with the administration of hBD3 (Supplemental Fig. 2). Hematoxylin and eosin (H&E) staining of terminal ileum tissue was performed and representative images were shown (Supplemental Fig. 2). The degree of bowel damage, evaluated by the histological scores of ileum, was reduced in group NEC + hBD3, compared with the group NEC, with a mean NEC score of 1.33 and 2.52, respectively (P < 0.001, Fig. 6C).
Rats in each group were intra-peritoneal injected with BrdU 18 h before sacrificed. The migration distance was indicated by the distance between the bottom of the small intestine crypt to the apical cell labelled BrdU, and the mobility were evaluated by the ratio of migration distance to intestinal villus height. Representative images were shown and the intestinal epithelial cells migration ability was markedly decreased in group rapamycin and in group NEC, which was effectively up-regulated after hBD3 administration (Fig. 6D–F). Inflammation played a central role in the development of NEC, we detected the inflammatory cytokine expression in ileum and in serum to further explore the underlying relationship between hBD3-mediated autophagy inhibition and inflammatory cytokine expression. In group NEC, inflammatory cytokines including IL-6, IL-10 and TNF-α were noticeably increased in the ileum and serum, but the intervention of hBD3 could relatively down-regulated the indicated cytokines (Supplemental Fig. 3) and then attenuated the inflammatory injury of rat NEC model. ZO-1 and occludin were immunostained to evaluate the mucosal integrity. ZO-1 staining loss was observed in group NEC, which was consistent with occludin staining. The inhibition of ZO-1 and occludin expression could be prevented to some extent after hBD3 intervention (Fig. 6G).
Together, hBD3-stimulated autophagy down-regulation promoted intestinal epithelial cells migration and mucosal integrity, and down-regulated inflammatory cytokines expression.
Discussion
In the present study, we reported that initiation of autophagy was blocked in cultured intestinal epithelial cells after hBD3 treatment. Furthermore, we provided evidence that impaired enterocyte migration was ameliorated both in enterocytes and in a rat model of NEC by hBD3, which was associated with inhibition of excessive intestinal autophagy. Our data suggested an additional role of hBD3-mediated protection against intestinal mucosal injury: inhibition of over-activated autophagy in small intestine.
Previous studies23,24,25 have demonstrated that G-protein coupled receptor CXCR4 was widely expressed in intestinal epithelial cells. And activation of CXCR4, by its natural ligand SDF-1α, was involved in migration of enterocytes and restitution of wounded barrier. In current study, we did not provide direct evidence of hBD3 binding to CXCR4. However, similarities indicated by structural analysis between hBD3 and SDF-1α, including the β-sheet conformation and three N-terminal surface cationic residues, may be the molecular structure basis of their binding to CXCR4. The β-sheet conformation is stabilized by three intramolecular disulfide bonds among six conserved cysteines18. Three N-terminal surface cationic residues (i.e., K1, R8 and R12) are believed to be the key structure of CXCR4-SDF-1α binding19. Correspondingly, three similar cationic residues are present on the surface of hBD3: K8, K32, and R36. Substituting all six cysteines or all three cationic residues of hBD3 was reported to result in an obviously decreased combination with CXCR426. Thus, we speculated that the distinctive conformation was essential for hBD3-interaction with CXCR4.
Autophagy can be activated by stress such as starvation and injury to maintain cell survival by degrading harmful proteins and damaged organelles27,28,29. The process of autophagy can be divided into four stages: the formation of the separation membrane, the formation of autophagosomes, the fusion of autophagosomes and lysosomes, and the degradation of autophagolysosomes30. Different methods were applicated to evaluate the autophagy level according to the guideline. The expression of autophagy-related proteins, Beclin1 and LC3-II/LC3-I ratio, noticeably increased both in rapamycin treated cells and in the rat NEC model, while the protein expression of p62 in ileum tissues was statistically insignificantly among different rat groups. One possible explanation is that p62 is a multifunctional protein regulated by a variety of signaling pathways, including NF-κB signaling pathway, and apoptosis pathway31,32,33. Because of just using of rapamycin in current study, only initiation of autophagy was evaluated after hBD3 treatment. Reduction in degradative activity as a result of a block in trafficking to lysosomes might also be involved in the process.
The destruction of mucosal integrity in neonates, especially in premature infants, is one critical cause of NEC. Intestinal epithelial cell migration plays a vital role in the reparative process of mucosal barrier. Cell migration occurs within a few hours after injury with intestinal epithelial cells losing polarity and migrating to the lesion through epithelial-mesenchymal transition. In children with NEC, it has been proved that the expression and distribution of genes involved in the reparative process of intestinal mucosal barrier were abnormal34. Recent research has revealed that autophagy induced by rapamycin noticeably inhibits the migration of intestinal epithelial cells11. Our results showed that impaired enterocyte migration was induced after activation of autophagy, and hBD3 treatment promoted the migration of intestinal epithelial cells. In the early stage of autophagosome formation, the Atg5-Atg12 complex binds to LC3-PE complexes via the kinase Atg7 and then promotes the localization of LC3-PE on autophagosomes35. Thus, ATG7 is an essential part of the whole autophagy process. ATG7 siRNA was transfected in our study to confirm that the promotion effect of hBD3 on intestinal epithelial cell migration was mediated by inhibiting autophagy. The activation of Rho, a GTPase in the Ras superfamily, and its downstream effectors is essential in the regulation of cell migration20. Our data demonstrated that hBD3-mediated autophagy inhibition could significantly promote cell migration by activating Rho protein, phosphorylating MLC2 and accumulating F-actin, resulting in intestinal mucosal healing. Obviously, there are other molecular mechanism underlying hBD3-mediated protection. For instance, recent studies suggested defensin also serves to help shape the composition of the intestinal microbiota36. And the effects of hBD3 on these targets deserve further investigation.
In summary, we reveled that down-regulation of excessive autophagy might be involved in hBD3-mediated protection, which resulted in the promotion of enterocyte migration and reduction of the severity of NEC in rat pup model. These results also provide evidence of therapeutic potential of host defence peptides.
Materials and Methods
Reagents and antibodies
Human β-defensin-3 (hBD3) was purchased from PEPTIDE INSTITUTE, INC (#4382-s, Ibaraki, Osaka, Japan). Reagents like rapamycin (#V900930), Lipopolysaccharides (LPS, #L4524), Chloroquine (CQ, #C6628), 5-Bromo-2′-deoxyuridine (BrdU, #B5002) were acquired from Sigma (St. Louis, MO, USA). Plerixafor (AMD3100) was procured from Selleckchem (#S8030, Houston, TX, USA). Reagents like Dulbecco’s modified eagle medium (DMEM) (#11995065), Fetal bovine serum (FBS) (#10099141), Opti-MEM® Reduced-Serum Medium (#31985062), 0.25% Trypsin-EDTA (#25200072), Penicillin Streptomycin (#15140122), Phosphate Buffered Saline (PBS) (#10010023) were obtained from Gibco (Grand Island, NY, USA). Antibodies against CXCR4 (#ab124824), p-AKT (Phospho- T308) (#ab38449), AKT (#ab8805), Beclin1(#ab207612), SQSTM1/P62 (#ab109012) were from Abcam (Cambridge, UK). Other antibodies, including anti- LC3A/B (#4108S), mTOR (#2972S), p-mTOR (#2971S), Myosin Light Chain 2 (MLC2, #8505T), p-Myosin Light Chain 2 (S19) (#3671T), FAK (#13009T), p-FAK (Y576/577) (#3281T), Glyceraldehyde-3-phosphate dehydrogenase (GAPDH, #5174S) were purchased from Cell Signaling Technology (CST, Beverly, MA, USA).
Cell culture
Rat intestinal crypt epithelial cell line IEC-6 and human colorectal adenocarcinoma cell line Caco-2, provided by the Cell Resource Center of the Chinese Academy of Science (Shanghai, China), were cultured in DMEM supplemented with 10% FBS and 1% Penicillin Streptomycin solution at 37 °C with humidified 5% CO2 atmosphere.
Protein extraction and western blotting
Western blotting was performed as described previously15,22. Cells were treated as required in each group and then lysed step by step in RIPA lysis buffer containing 1 mM phenylmethyl sulfonylfluoride (PMSF) (CST, #8553S, Beverly, MA, USA) and 1% protease inhibitor cocktail (Sigma, #P8340, St. Louis, MO, USA). The lysate (30 ug) was separated by 10% or 12% SDS-PAGE and transferred to PVDF membranes (Millipore, ISEQ. 00010, Billerica, MA, USA). Afterwards, the membrane was incubated with blocking buffer (TBS containing 0.1% Tween-20 and 5% BSA) at room temperature for 1 h. Subsequently, indicated primary antibodies were used to probe the membrane with gentle agitation at 4 °C overnight. The membrane was then incubated with Peroxidase-conjugated AffiniPure Goat Anti-Rabbit IgG (H + L) (Jackson ImmunoResearch, #111-035-003, West Grove, PA, USA). The result of western blotting was detected by ImmobilonTM Western Chemiluminescent HRP Substrate (Millipore, #WBKLS0500, Billerica, MA, USA).
Transmission electron microscopy (TEM)
Morphology of autophagic structures during the dynamic maturation process from phagophore through autolysosome was revealed by the transmission electron microscopy (TEM) (HITACHI, HT7700, Chiyoda, Tokyo, Japan). First, cells in each group were collected by cell scrapers (CORNING, #3010, Corning, NY, USA) and then fixed in 2.5% glutaraldehyde after centrifugation at 800 rpm for 5 min. Afterwards, cells were post-fixed with 1% Osmium tetroxide (OsO4) in 0.1 M PBS for 2 h at room temperature. Dehydration, infiltration, embedment and cutting of ultrathin sections was carried out subsequently. After staining with uranyl acetate and lead citrate for 15 min respectively, ultrathin sections were observed and photographed with TEM.
RNA extraction and quantitative real-time PCR (qRT-PCR)
TRIzolTM reagent (Invitrogen, #15596026, Waltham, MA, USA) was used to extract total RNA of rat ileum tissues in each group according to the instruction of the manufacturer. Afterwards, cDNA was synthesized by PrimeScriptTM RT Master Mix (Takara, #RR036A, Kusatsu, Shiga, Japan). Subsequently, FastStart Essential DNA Green Master (Roche Diagnostics, #06924204001, Indianapolis, IN, USA) was used to monitor the target gene amplification dynamically. Primer sequences are listed in Table S3. The relative expression of mRNA was calculated with the 2−ΔΔCt method.
Small interfering RNA (siRNA) transfection
Small interfering RNA (siRNA) products respectively targeting at CXCR4 and ATG7 were procured from QIAGEN (Duesseldorf, Germany). Cells were seeded into 6-well culture plates at a final concentration of 2 × 105 cells/ml in DMEM and then incubated in the incubator for the short time until transfection. A mixture supplemented with 800 ng siRNA, 100 ul Opti-MEM® reduced-serum medium and 24 ul HiperFect Transfection Reagent (QIAGEN, #301705, Duesseldorf, Germany) were blended and incubated at room temperature for 10 min to allow the formation of transfection complexes. Complexes were drop-wised onto the cells and then incubated in the incubator. The efficiency of gene silencing was monitored by western blotting using validated antibodies 36 h after transfection. The effect of CXCR4 knockdown on hBD3 mediated suppression of autophagy was assessed with the expression levels of autophagy associated proteins by western blotting. The effect of ATG7 knockdown on autophagy mediated retardation of cell migration was assessed with wound healing assay.
Immunofluorescence
The cells were seeded on the coverslips disinfected and sterilized thoroughly at a final concentration of 1 × 105 cells/ml in DMEM. When cells reached 50% confluence, following treatments in each group were performed at the indicated time points. The cells were then rinsed with PBS for 3 times and fixed with 4% paraformaldehyde for 30 min, followed by soaking the cells in absolute ethyl alcohol for 20 min. After being blocked with blocking buffer contained with 1% BSA, 4% normal serum, 0.4% TritonX100 and 95.6% PBS for 30 min, the cells were subsequently stained with the indicated primary antibodies at 4 °C overnight. Then, the cells were incubated with CyTM3-conjugated AffiniPure Donkey Anti-Rabbit IgG (H + L) (Jackson ImmunoResearch, #711-165-152, West Grove, PA, USA) for 1 h at room temperature away from light after washing the nonspecific binding antibody with PBT supplemented with 99.9% PBS and 0.1% TritonX100. Finally, the nuclei were labeled with 4,6-diamidino-2-phenylindole (DAPI, #32670, Sigma, St. Louis, MO, USA) for 5 min at room temperature, and then the cells were rinsed with PBS for 3 times. The stained cells in each group were observed and photographed with the fluorescent microscope (Leica, Wetzlar, Germany).
Adenovirus infection and laser confocal detection
Ad-mRFP-GTP-LC3 (HANBIO, #HB-AP2100001, Shanghai, China) was designed to monitor the induction of autophagy and the autophagy flux through detecting the degradation of GTP signal in the acidic condition of the lysosome lumen. Cells were seeded into 12-well culture plates at a final concentration of 1 × 105 cells/ml in DMEM. When cells reached 30% confluence, Ad-mRFP-GTP-LC3 (1.26 × 1010 PFU/ml) was added into each well and the multiplicity of infection (MOI) was 1000 following the manufacturer’s instructions. Following treatments in each group were performed 48 h after infection. After being rinsed with PBS for 3 times and fixed with 4% paraformaldehyde for 30 min, the cells were observed and photographed with the confocal microscopy (NIKON ECLIPSE TI, Chiyoda-KU, Tokyo, Japan).
Wound healing assay
Cell migration was assessed by wound healing assay. The horizontal lines were evenly drawn on the back of the 6-well culture plate with 0.5 cm spacing. Cells were seeded into the 6-well culture plate at a final concentration of 5 × 105 cells/ml in DMEM. When cells reached 100% confluence, sterile micropipette tips were used to scratch straight lines which were perpendicular to the horizontal lines on the back of the 6-well culture plate on the confluent monolayer cells. The interactions were used to mark the same field of microscope so that the dynamical changes of cell migration could be accurately measured by photographing five designated interactions at different indicated time points. The cell migration results were analyzed by ImageJ software.
Transwell migration assay
The transwell migration assay was a classical technique to quantify cell movement. 100 μl cell suspension containing 1 × 105 cells in Opti-MEM® Reduced-serum Medium was placed on the upper layer of the transwell chamber with 8 μm permeable membrane, and 500 μl DMEM containing 10% FBS was placed below the cell permeable membrane. Following an incubation period for 24 h, the transwell chamber was fixed by 4% paraformaldehyde for 30 min, and then the cells remaining on the upper layer of the permeable membrane were scraped with cotton swabs. After staining with 0.1% crystal violet for 15 min, the amount of migration cells in the bottom of the chamber was counted randomly in five microscopic fields.
Active Rho and downstream effectors detection
The Active Rho Detection Kit (CST, #11860S, Beverly, MA, USA) was used to detect the Rho activation level following the manufacturer’s protocol. The whole pull-down process included the binding of GTP-bound GTPase and glutathione resin through GST-linked binding protein, the centrifugation to remove unbound proteins, and the elution to remove glutathione resin through SDS buffer. Then, the elute sample could be analyzed by western blotting.
The downstream effector included Myosin Light Chain 2 (MLC2) and F-actin. MLC2 phosphorylation (Ser19) was detected by western blotting. To detect cellular F-actin expression, the cells were seeded into 12-well culture plate at a final concentration of 1 × 105 cells/ml in DMEM and incubated overnight, following treatments in each group were performed at the indicated time points. When cells reached 50% confluence, rinse, fixation and permeabilization were performed step by step, and then the cells were incubated with 50 g/ml fluorescein isothiocyanate labeled phalloidin for 30 min at room temperature away from light. The fluorescent microscope was used to observe and photograph the stained cells in each group.
Serum inflammatory factors measure
Enzyme linked immunosorbent assay (Elisa) was used to measure the expression levels of the inflammatory factors in serum. Elisa Kits targeting at TNF-α, IL-6 and IL-10 were obtained from ELK Biotechnology (#ELK1396, #ELK1158, #ELK1144, Wuhan, China). After clotting for two hours at room temperature, the serum was centrifuged for 20 min at approximately 1000 × g. Freshly prepared serum was used to detect inflammatory factors with the detailed manufacturer’s instructions. The microplates were pre-coated with an indicated antibody specific to the inflammatory factor, and the color change caused by the enzyme-substrate reaction could be measured spectrophotometrically at a wavelength of 450 nm.
Animal experimental design and evaluation
Experimental design was approved by the Animal Care Committee of the Children’s Hospital of Shanghai. It is confirmed that all methods were performed in accordance with the relevant guidelines and regulations. The rat NEC model described by Caplan et al.21 was used for reference and further optimized to better simulate the occurrence and development of NEC. Hypertonic formula feeding and asphyxia-cold stress exposure were conducted in our rat NEC model15,22. Forty-two newborn Sprague–Dawley rats originated from six different litters were divided randomly into four groups.
Control + NS (n = 11), Control + rapamycin (n = 11), NEC + NS (n = 12), and NEC + hBD3 (n = 8). 18 h before the end of the experiment, BrdU (50 mg/kg) was intra-peritoneal injected to assess the migration of intestinal epithelial cells. All pups were sacrificed via cervical dislocation and the intestine and serum were collected according to demand. Hematoxylin and eosin (H&E) staining was used for experienced pathologists to score the pathological changes blindly according to the published NEC scoring system. Intestine tissues with scores 2 or higher were defined as NEC positive. Autophagy related proteins were assessed by western blotting. Inflammatory cytokines were measured via qRT-PCR and Elisa respectively. Tight junction proteins and BrdU were detected with immunohistochemistry.
Statistical analysis
Statistical analysis was performed with SPSS 24 software (SPSS, Chicago, Illinois, USA). Results were represented as Mean ± SD. Student’s t test and one-way analysis of variance (ANOVA) were used for comparison among groups. P < 0.05 was considered as statistically significant.
References
Tanner, S. M. et al. Pathogenesis of necrotizing enterocolitis: modeling the innate immune response. Am J Pathol 185, 4–16 (2015).
Grishin, A., Bowling, J., Bell, B., Wang, J. & Ford, H. R. Roles of nitric oxide and intestinal microbiota in the pathogenesis of necrotizing enterocolitis. Journal of pediatric surgery 51, 13–17 (2016).
Sheng, Q. et al. Short-term surgical outcomes of preterm infants with necrotizing enterocolitis: A single-center experience. Medicine (Baltimore) 95, e4379 (2016).
Li, Q. Y. et al. Differences in the Clinical Characteristics of Early- and Late-Onset Necrotizing Enterocolitis in Full-Term Infants: A Retrospective Case-Control Study. Sci Rep 7, 43042 (2017).
Vincent, D. et al. NEC is likely a NETs dependent process and markers of NETosis are predictive of NEC in mice and humans. Sci Rep 8, 12612 (2018).
Frost, B. L., Modi, B. P., Jaksic, T. & Caplan, M. S. New Medical and Surgical Insights Into Neonatal Necrotizing Enterocolitis: A Review. JAMA Pediatr 171, 83–88 (2017).
Baxt, L. A. & Xavier, R. J. Role of Autophagy in the Maintenance of Intestinal Homeostasis. Gastroenterology 149, 553–562 (2015).
Marino, G., Niso-Santano, M., Baehrecke, E. H. & Kroemer, G. Self-consumption: the interplay of autophagy and apoptosis. Nat Rev Mol Cell Biol 15, 81–94 (2014).
Maynard, A. A. et al. Epidermal growth factor reduces autophagy in intestinal epithelium and in the rat model of necrotizing enterocolitis. American journal of physiology. Gastrointestinal and liver physiology 299, G614–622 (2010).
Nighot, P. K., Hu, C. A. & Ma, T. Y. Autophagy enhances intestinal epithelial tight junction barrier function by targeting claudin-2 protein degradation. The Journal of biological chemistry 290, 7234–7246 (2015).
Neal, M. D. et al. A critical role for TLR4 induction of autophagy in the regulation of enterocyte migration and the pathogenesis of necrotizing enterocolitis. Journal of immunology (Baltimore, Md.: 1950) 190, 3541–3551 (2013).
Semple, F. & Dorin, J. R. Beta-Defensins: multifunctional modulators of infection, inflammation and more? J Innate Immun 4, 337–348 (2012).
Meisch, J. P. et al. Human beta-defensin 3 induces STAT1 phosphorylation, tyrosine phosphatase activity, and cytokine synthesis in T cells. J Leukoc Biol 94, 459–471 (2013).
Jenke, A. C., Zilbauer, M., Postberg, J. & Wirth, S. Human beta-defensin 2 expression in ELBW infants with severe necrotizing enterocolitis. Pediatr Res 72, 513–520 (2012).
Sheng, Q. et al. Human beta-defensin-3 promotes intestinal epithelial cell migration and reduces the development of necrotizing enterocolitis in a neonatal rat model. Pediatr Res 76, 269–279 (2014).
Wu, Y. et al. Beta-Defensin 2 and 3 Promote Bacterial Clearance of Pseudomonas aeruginosa by Inhibiting Macrophage Autophagy through Downregulation of Early Growth Response Gene-1 and c-FOS. Front Immunol 9, 211 (2018).
Guang, C. et al. Inhibition of Chemokine (CXC Motif) Ligand 12/Chemokine (CXC Motif) Receptor 4 Axis (CXCL12/CXCR4)-mediated Cell Migration by Targeting Mammalian Target of Rapamycin (mTOR) Pathway in Human Gastric Carcinoma Cells. The Journal of biological chemistry 287, 12132–12141 (2012).
Huang, X. et al. Molecular dynamics simulations on SDF-1alpha: binding with CXCR4 receptor. Biophys J 84, 171–184 (2003).
Feng, Z., Dubyak, G. R., Jia, X., Lubkowski, J. T. & Weinberg, A. Human beta-defensin-3 structure motifs that are important in CXCR4 antagonism. Febs j 280, 3365–3375 (2013).
Chaturvedi, L. S., Marsh, H. M. & Basson, M. D. Role of RhoA and its effectors ROCK and mDia1 in the modulation of deformation-induced FAK, ERK, p38, and MLC motogenic signals in human Caco-2 intestinal epithelial cells. Am J Physiol Cell Physiol 301, C1224–1238 (2011).
Caplan, M. S., Hedlund, E., Adler, L. & Hsueh, W. Role of asphyxia and feeding in a neonatal rat model of necrotizing enterocolitis. Pediatr Pathol 14, 1017–1028 (1994).
Sheng, Q. et al. Protective effects of hydrogen-rich saline on necrotizing enterocolitis in neonatal rats. Journal of pediatric surgery 48, 1697–1706 (2013).
Werner, L., Guzner-Gur, H. & Dotan, I. Involvement of CXCR4/CXCR7/CXCL12 Interactions in Inflammatory bowel disease. Theranostics 3, 40–46 (2013).
Yoshitake, N. et al. Expression of SDF-1 alpha and nuclear CXCR4 predicts lymph node metastasis in colorectal cancer. Br J Cancer 98, 1682–1689 (2008).
Agle, K. A., Vongsa, R. A. & Dwinell, M. B. Calcium mobilization triggered by the chemokine CXCL12 regulates migration in wounded intestinal epithelial monolayers. The Journal of biological chemistry 285, 16066–16075, https://doi.org/10.1074/jbc.M109.061416 (2010).
Harder, J., Bartels, J., Christophers, E. & Schroder, J. M. Isolation and characterization of human beta -defensin-3, a novel human inducible peptide antibiotic. The Journal of biological chemistry 276, 5707–5713 (2001).
Yoshimori, T. Autophagy: a regulated bulk degradation process inside cells. Biochem Biophys Res Commun 313, 453–458 (2004).
Shintani, T. & Klionsky, D. J. Autophagy in health and disease: a double-edged sword. Science 306, 990–995 (2004).
Sheng, Q. et al. Autophagy protects pancreatic beta cell mass and function in the setting of a high-fat and high-glucose diet. Sci Rep 7, 16348 (2017).
Mizushima, N., Ohsumi, Y. & Yoshimori, T. Autophagosome formation in mammalian cells. Cell Struct Funct 27, 421–429 (2002).
Nakamura, K., Kimple, A. J., Siderovski, D. P. & Johnson, G. L. PB1 domain interaction of p62/sequestosome 1 and MEKK3 regulates NF-kappaB activation. The Journal of biological chemistry 285, 2077–2089 (2010).
Sanz, L., Diaz-Meco, M. T., Nakano, H. & Moscat, J. The atypical PKC-interacting protein p62 channels NF-kappaB activation by the IL-1-TRAF6 pathway. Embo j 19, 1576–1586 (2000).
Wong, W. W. & Silke, J. Another facet of ubiquitylation: death. J Mol Cell Biol 1, 80–81 (2009).
Hogberg, N., Stenback, A., Carlsson, P. O., Wanders, A. & Lilja, H. E. Genes regulating tight junctions and cell adhesion are altered in early experimental necrotizing enterocolitis. Journal of pediatric surgery 48, 2308–2312 (2013).
Yu, K. et al. miR-96-5p prevents hepatic stellate cell activation by inhibiting autophagy via ATG7. J Mol Med (Berl) 96, 65–74 (2018).
Coretti, L. et al. The Interplay between Defensins and Microbiota in Crohn’s Disease. Mediators Inflamm 2017, 8392523 (2017).
Acknowledgements
This work was supported by the National Natural Science Foundation of China (81601322, 81871194).
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Z.L., Q.S. designed the study. L.C., Z.G., G.G., X.W. performed the experiments. Q.S., L.C., J.Z. analyzed the data. Q.S., L.C., Z.L. wrote the manuscript.
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Chen, L., Lv, Z., Gao, Z. et al. Human β-defensin-3 reduces excessive autophagy in intestinal epithelial cells and in experimental necrotizing enterocolitis. Sci Rep 9, 19890 (2019). https://doi.org/10.1038/s41598-019-56535-3
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DOI: https://doi.org/10.1038/s41598-019-56535-3
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