The role of DOCK8 in autoimmunity

DOCK8在自身免疫中的作用

• 批准号: 9277401
• 负责人: ERIN Margaret JANSSEN
• 金额: $ 19.45万
• 依托单位: BOSTON CHILDREN'S HOSPITAL
• 依托单位国家: 美国
• 财政年份: 2015
• 资助国家: 美国
• 起止时间: 2015-06-15 至 2020-05-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/9277401
• 关键词: Advisory Committees; Age; Aging; Agonist; Allergic; Antibodies; Autoantibodies; Autoimmune Diseases; Autoimmune Process; Autoimmune hemolytic anemia; Autoimmunity; B-Lymphocytes; Blood specimen; Boston; Cell Count; Cell physiology; Cells; Child; Chronic; Clinical; Clinical Immunology; Colitis; Cutaneous; Data; Defect; Dermatitis; Development; Disease; Doctor of Medicine; Doctor of Philosophy; Eczema; Engineering; Eosinophilia; Exons; FOXP3 gene; Faculty; Fellowship; Funding; Generations; Goals; Human; Hypersensitivity; Hypothyroidism; IgE; Immune; Immunoglobulin Class Switching; Immunologic Deficiency Syndromes; Immunology; Impairment; In Vitro; Infection; Infectious Skin Diseases; Inflammation; International; Journals; Knockout Mice; Lead; Lung; Lymphatic Diseases; Lymphocyte; Lymphocyte Subset; Maintenance; Manuscripts; Memory; Mentors; Mus; Mutation; Nonsense Mutation; Partner in relationship; Patients; Pediatric Hospitals; Physicians; Process; Production; Proteins; Publishing; Recurrence; Regulatory T-Lymphocyte; Reporting; Research; Residencies; Rheumatology; Role; Sampling; Scientist; Serological; Signal Transduction; Skin; Splenomegaly; T-Lymphocyte; TLR4 gene; Testing; Training; Universities; Validation; Vasculitis; Viral; Virus Diseases; autoreactivity; career; career development; catalyst; cohort; congenital immunodeficiency; experience; human disease; improved; in vivo; in vivo Model; insight; medical schools; mouse development; mouse model; public health relevance

 DESCRIPTION (provided by applicant): DOCK8 deficiency is characterized by recurrent sinopulmonary infections, chronic viral skin infections, eosinophilia, and elevated IgE levels. DOCK8 patients are also predisposed to autoimmunity; they develop autoimmune hemolytic anemia, colitis, sclerosing colitis, and vasculitis. We found that DOCK8 deficiency in patients leads to the development of autoantibodies, and patients have decreased numbers of regulatory T (Treg) cells and impaired Treg cell in vitro suppressive activity (Janssen et al. J Allergy Clin Immunol (2014) in press). In addition, we have preliminary data that Dock8-/- mice develop autoantibodies and have impaired Treg numbers and in vitro suppressive ability. Furthermore, mice with a selective Dock8 deficiency in Foxp3 expressing Treg cells develop spontaneous splenomegaly and lymphadenopathy at an early age. Our overall hypothesis is that DOCK8 deficiency leads to the generation of autoreactive lymphocytes. We will test this hypothesis using mouse models, and when possible utilize samples from DOCK8 deficient patients to confirm our findings in humans. To test the hypothesis that Dock8 deficient mice develop autoimmune disease with aging, we will age Dock8-/- mice and do serial examinations for autoantibody production and signs of autoimmune disease. If Dock8-/- mice do not develop spontaneous autoimmune disease, we will look at inducing disease with TLR agonists. Simultaneously, we will examine Dock8-/- mice for accelerated disease in the context of autoimmune prone backgrounds. Next, we will examine the role of T and B cell intrinsic Dock8 deficiency in developing autoimmunity, using Dock8 conditional knock-out mice that have already been generated. Finally, we have preliminary data that Dock8 is important for Treg cell number and suppressive activity. We will examine the development, survival, and stability of Treg cells in Dock8 deficient mice and elucidate whether these defects are Treg cell intrinsic. In addition, using several in vivo models of autoimmunity/inflammation, we will test Dock8 deficient Treg cell suppressive function. Together, these studies should yield answers regarding the mechanism of developing of autoimmunity in DOCK8 deficient patients. We have generated Dock8 deficient mice in-house. The Dock8 locus in these mice have a mutation in exon 9 that mimics a nonsense mutation found in a DOCK8 deficient patient who does not express any DOCK8 protein. In addition, we have engineered Dock8flox/flox conditional knock-out mice. We have already bred these mice with Cd4-Cre and Foxp3-YFP-Cre mice to examine role of Dock8 in a T cell and Treg cell intrinsic manner. We are in the process of mating the Dock8flox/flox mice with mb-1-Cre to examine B cell intrinsic effects. These mice will allow us to examine cell intrinsic roles of Dock8 in the generation of autoantibodies and autoimmunity. We also have access to a unique cohort of DOCK8 deficient patients through participation in the International Consortium of Immunodeficiency (ICID). Often patients referred through the ICID are evaluated and treated at Boston Children's hospital, and this allows us to obtain blood samples for validation of our mouse findings. Here, we present promising data that forms the basis for this scientific application. Through the utilization of thee mouse models and patient samples, we should be able to delve into these questions in a meaningful way to explain the human disease. Dr. Janssen received her M.D. and Ph.D. in Immunology at Duke University. Her graduate studies focused on lymphocyte signaling. During her residency and fellowship, Dr. Janssen acquired training in clinical immunology and rheumatology. She is currently mentored by Dr. Raif Geha, Chief of Immunology, at Boston Children's Hospital. Under his guidance, Dr. Janssen published two first author manuscripts on lymphocyte subsets in DOCK8 deficient patients and the role of TLR4 in IgE class switching. In addition, she had two first author manuscripts recently accepted to the Journal of Allergy and Clinical Immunology on the development of autoimmunity and impaired regulatory T cells in DOCK8 and LRBA deficient patients. Successful funding of this K08 application will give Dr. Janssen the ability to continue these studies, as well as to further develop her career as a physician scientist. She will continue to have the opportunity to participate in the various career development opportunities provided by Boston Children's, the Harvard Medical School, and the Harvard Catalyst. Dr. Janssen's goal over the next five years is to progress to research independence under the guidance of her mentor, advisory committee, and the experienced faculty at Harvard Medical School. She would like to continue to draw from her clinical experience to explore new questions in autoimmunity and immune dysregulation.

 描述（由申请方提供）：DOCK 8缺乏症的特征为复发性鼻窦炎感染、慢性病毒性皮肤感染、嗜酸性粒细胞增多和IgE水平升高。DOCK 8患者也易患自身免疫;他们发展自身免疫性溶血性贫血、结肠炎、硬化性结肠炎和血管炎。我们发现患者中的DOCK 8缺陷导致自身抗体的发展，并且患者具有减少的调节性T（Treg）细胞数量和受损的Treg细胞体外抑制活性（Janssen等人，J Allergy Clin Immunol（2014）出版中）。此外，我们有初步数据表明Dock 8-/-小鼠产生自身抗体，并且具有受损的Treg数量和体外抑制能力。此外，在表达Foxp 3的Treg细胞中具有选择性Dock 8缺陷的小鼠在早期发展自发性脾肿大和淋巴结病。 我们的总体假设是DOCK 8缺陷导致自身反应性淋巴细胞的产生。我们将使用小鼠模型测试这一假设，并在可能的情况下利用DOCK 8缺陷患者的样本来证实我们在人类中的发现。为了检验Dock 8缺陷小鼠随着衰老发展自身免疫性疾病的假设，我们将使Dock 8-/-小鼠老化并对自身抗体产生和自身免疫性疾病的体征进行系列检查。如果Dock 8-/-小鼠不发生自发性自身免疫性疾病，我们将研究用TLR激动剂诱导疾病。同时，我们将检查Dock 8-/-小鼠在自身免疫倾向背景下的加速疾病。接下来，我们将使用已经产生的Dock 8条件性敲除小鼠来检查T和B细胞内在Dock 8缺陷在发展自身免疫中的作用。最后，我们有初步数据表明Dock 8对Treg细胞数量和抑制活性很重要。我们将研究Dock 8缺陷小鼠中Treg细胞的发育、存活和稳定性，并阐明这些缺陷是否是Treg细胞固有的。此外，使用几种自身免疫/炎症的体内模型，我们将测试Dock 8缺陷型Treg细胞抑制功能。总之，这些研究应该产生关于DOCK 8缺陷患者中自身免疫发展机制的答案。 我们已经在内部产生了Dock 8缺陷小鼠。这些小鼠中的Dock 8基因座在外显子9中具有突变，其模拟在不表达任何DOCK 8蛋白的DOCK 8缺陷患者中发现的无义突变。此外，我们已经工程化了Dock 8 flox/flox条件性敲除小鼠。我们已经将这些小鼠与Cd 4-Cre和Foxp 3-YFP-Cre小鼠一起繁殖，以检查Dock 8在T细胞和Treg细胞内在方式中的作用。我们正在将Dock 8 flox/flox小鼠与mb-1-Cre交配以检查B细胞的内在效应。这些小鼠将使我们能够检查Dock 8在自身抗体和自身免疫产生中的细胞内在作用。我们还通过参与国际免疫缺陷联盟（ICID）获得了DOCK 8缺陷患者的独特队列。通过ICID转诊的患者通常在波士顿儿童医院接受评估和治疗，这使我们能够获得血液样本，以验证我们的小鼠研究结果。在这里，我们提出了有希望的数据，这些数据构成了这种科学应用的基础。通过利用这些小鼠模型和患者样本，我们应该能够以一种有意义的方式深入研究这些问题，以解释人类疾病。詹森博士获得了医学博士学位。和博士在杜克大学的免疫学专业。她的研究生课程集中在淋巴细胞信号传导。在她的住院医师和研究员期间，Janssen博士获得了临床免疫学和风湿病学的培训。她目前由波士顿儿童医院免疫学主任Raif Geha博士指导。在他的指导下，Janssen博士发表了两篇关于DOCK 8缺陷患者淋巴细胞亚群和TLR 4在IgE类别转换中的作用的第一作者手稿。此外，她有两个第一作者手稿最近接受了过敏和临床免疫学杂志关于DOCK 8和LRBA缺陷患者的自身免疫和受损调节性T细胞的发展。 K 08申请的成功资助将使Janssen博士能够继续这些研究，并进一步发展她作为医生科学家的职业生涯。她将继续 有机会参与波士顿儿童，哈佛医学院和哈佛催化剂提供的各种职业发展机会。詹森博士在未来五年的目标是在她的导师、咨询委员会和哈佛医学院经验丰富的教师的指导下，逐步实现研究独立。她希望继续从她的临床经验中汲取经验，探索自身免疫和免疫失调的新问题。