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Neural interactions with the microbiome and immune system that produce inflammation in Hirschsprung disease models

在先天性巨结肠症模型中神经与微生物组和免疫系统的相互作用产生炎症

基本信息

批准号：
10671530
负责人：
Kristen Michelle Smith-Edwards
金额：
$ 24.9万
依托单位：
MAYO CLINIC ROCHESTER
依托单位国家：
美国
项目类别：
财政年份：
2022
资助国家：
美国
起止时间：
2022-08-01 至 2025-07-31
项目状态：
未结题

来源：
https://reporter.nih.gov/project-details/10671530
关键词：
16S ribosomal RNA sequencing Adult Affect Age Anatomy Autonomic nervous system Biological Assay Calcium Cell Count Cells Child Childhood Chronic Clinical Colon Communication Complication Congenital Abnormality Congenital Megacolon Data Defect Development Digestive System Disorders Disease Disease model Distal Electrophysiology (science)Endothelin Enteral Enteric Nervous System Enterocolitis Etiology Exhibits Flow Cytometry Functional disorder Ganglia Genes Goals Health Heterozygote Human Image Immune Immune System Diseases Immune system Immunity Impairment Inflammation Inflammatory Inflammatory Bowel Diseases Intestines Lamina Propria Life Longevity Measures Mediating Microscopy Modeling Mucosal Immunity Mus Mutation Nerve Neuroimmune Neuronal Dysfunction Neurons Newborn Infant Operative Surgical Procedures Pathway interactions Patients Phenocopy Phenotype Predisposition Preparation Prevention Probiotics Reporting Research Research Proposals Risk Role Siblings Signal Transduction Sodium Dextran Sulfate Symptoms Synapses Technical Expertise Techniques Testing Therapeutic Training Visceral pain calcium indicator cell motility disease diagnosis dysbiosis epithelial injury experience experimental study fecal transplantation immune function in vivo loss of function mutation microbial microbiome microbiome composition microbiota motility disorder mouse model nerve supply neural neuromechanism novel postnatal prevent programs receptor sensory input

项目摘要

ABSTRACT The importance of the enteric (ENS) and autonomic nervous systems (ANS) in maintaining intestinal health is made evident in Hirschsprung disease (HSCR), defined by the absence of the ENS in distal bowel and caused by a number of mutations (e.g., Ednrb). HSCR is managed with surgery to remove the ‘abnormal’ bowel, but many patients suffer from persistent functional and inflammatory bowel complications (e.g., Hirschsprung Associated Enterocolitis, HAEC), indicating that the ENS in proximal bowel is also affected by HSCR-related mutations despite appearing anatomically normal. Our lab generated a novel HSCR mouse model with Ednrb mutations that expresses GCaMP, a genetically-encoded calcium indicator, to measure synaptic connectivity in proximal bowel where the ENS is present. By using in vivo and ex vivo colon preparations that keep intrinsic and extrinsic nerve pathways intact, we have previously shown how ENS, ANS (sympathetic and parasympathetic), and sensory inputs normally influence colon function. Ednrb-/- (null)-GCaMP mice had specific changes in myenteric neuron activity (spontaneous and synaptically-evoked) in proximal colon at post-natal ages that likely contribute to the chronic issues in HSCR. Interestingly, age-matched Ednrb+/- (het)-GCaMP mice displayed a similar functional phenotype, despite having ENS innervation in the entire bowel, and they continued to be significantly different from wild-type littermates as adults. These mice exhibited dysmotility, had altered immune cell counts in the lamina propria, and appeared to be more vulnerable to experimentally-induced inflammation. Therefore, ‘subclinical’ mutations in HSCR-related genes (i.e., those that would not cause a HSCR diagnosis) appear to be sufficient to impair aspects of ENS circuit development. Importantly, Ednrb-/- and Ednrb+/- GCaMP mice model different aspects of HSCR: ‘clinical’ HSCR complications in newborns and ‘subclinical’ HSCR issues that persist into childhood and adulthood. Several recent HSCR studies have identified shifts in the microbiome and impaired immunity that may underlie increased inflammation and HAEC, but the causal role of the microbiome in producing HSCR-related dysfunction is unknown. Based on what is known about neuro- immune-microbiota interactions, I hypothesize that the ENS/ANS contributes to immune dysfunction indirectly via microbiome changes due to dysmotility, but also potentially through changes in direct neuro-immune communication. To test this hypothesis, experiments in Aim 1 (K99) will define the immune cell profile and microbiome in ‘clinical’ and ‘subclinical’ HSCR mouse models at post-natal ages, and determine whether the ‘HSCR microbiome’ is necessary and/or sufficient to produce ENS, ANS, or immune dysfunction. Experiments in Aim 2 (R00) will test whether HSCR-related dysfunction in the ENS/ANS impairs the ability to respond to inflammatory immune challenge, and determine the role of the ‘HSCR microbiome’ in resolving inflammation. As numerous digestive disorders exhibit neural, microbiome and/or immune dysregulation, the proposed research program will broadly impact human health.

摘要肠道(ENS)和自主神经系统(ANS)在维持肠道健康方面的重要性是在先天性巨结肠症(HSCR)中表现明显，定义为远端肠道内无ENS，并引起通过一些突变(例如，EDNRB)。HSCR的治疗方法是通过手术切除“异常”的肠道，但许多患者患有持续性功能性和炎症性肠道并发症(如先天性巨结肠)。相关性小肠结肠炎(HAEC)，表明近端肠道的ENS也受到HSCR相关的影响突变，尽管在解剖学上看起来是正常的。我们的实验室用EDNRB建立了一种新的HSCR小鼠模型表达GCaMP的突变，一种遗传编码的钙指示剂，以测量突触连接肠系膜存在的近端肠道。通过使用体内和体外结肠制剂，保持固有的和外部神经通路完好无损，我们之前已经展示了ENS，ANS(交感和副交感神经)，感觉输入通常会影响结肠功能。EDNRB-/-(空)-GCaMP小鼠具有特异性出生后近端结肠肌间神经元活动(自发和突触诱发)的变化这可能导致了HSCR中的长期问题。有趣的是，年龄匹配的EDNRB+/-(Het)-GCaMP小鼠表现出相似的功能表型，尽管在整个肠道有ENS神经支配，他们继续成年后与野生型产仔显著不同。这些小鼠表现出运动障碍，已经改变免疫细胞在固有层中计数，似乎更容易受到实验诱导的影响发炎。因此，HSCR相关基因(即那些不会导致HSCR的基因)的“亚临床”突变诊断)似乎足以损害ENS电路发展的各个方面。重要的是，EDNRB-/-和EDNRB+/- GCaMP小鼠建立HSCR不同方面的模型：新生儿和亚临床的HSCR并发症 HSCR问题一直持续到儿童和成年。最近的几项HSCR研究发现，微生物群和免疫受损可能是炎症和HAEC增加的基础，但其因果作用微生物群在产生HSCR相关功能障碍中的作用尚不清楚。基于对神经的了解- 免疫-微生物区系的相互作用，我假设ENS/ANS间接导致免疫功能障碍通过微生物组的变化引起的运动障碍，但也可能通过直接神经免疫的变化沟通。为了验证这一假设，目标1(K99)中的实验将定义免疫细胞配置文件和在“临床”和“亚临床”HSCR小鼠模型出生后年龄的微生物组，并确定是否 ‘HSCR微生物群’是产生ENS、ANS或免疫功能障碍所必需的和/或足够的。实验在AIM 2(R00)中，将测试ENS/ANS中与HSCR相关的功能障碍是否会损害对炎症免疫挑战，并确定‘HSCR微生物群’在消炎中的作用。由于许多消化疾病表现出神经、微生物组和/或免疫失调，建议的研究计划将广泛影响人类健康。