Estes D Mark
University of Texas Medical Branch, Department of Pathology and Microbiology and Immunology, Sealy Center for Vaccine Development and Center for Biodefense and Emerging Infectious Diseases, 6.200T Galveston National Laboratory, 301 University Boulevard, Galveston, TX 77555-0610, USA.
Vet Immunol Immunopathol. 2010 Dec 15;138(4):312-7. doi: 10.1016/j.vetimm.2010.10.009. Epub 2010 Oct 14.
Secretory IgA (SIgA) constitutes the largest component of the humoral immune system of the body with gram quantities of this isotype produced by mammals on a daily basis. Secretory IgA (SIgA) antibodies function by both blocking pathogen/commensal entry at mucosal surfaces and virus neutralization. Several pathways of induction of IgA responses have been described which depend on T cells (T cell dependent or TD) pathways or are independent of T cells (T-independent or TI) and are mediated by dendritic cells (DCs) and/or epithelial cells. Many elements of IgA regulation readily cross species barriers (adjuvants, soluble and cognate factors) and are highly conserved whereas other pathways may be more specific to any given species and must be evaluated. Regulation of IgA production in cattle is not completely understood and thus we have focused in part on highly conserved factors such as transforming growth factor beta, Type I and Type 2 interferons, neuropeptides which interdigitate mucosal tissues (vasoactive intestinal peptide or VIP), and a small peptide (IgA inducing peptide or IGIP) which can serve as targets for modulation and increasing SIgA virus-specific antibodies. We have evaluated the potential utility of modulating these factors in vitro in regulation of qualitative aspects of antibodies of the IgM, IgG and IgA isotypes at mucosal surfaces and in secretions of the upper and lower respiratory tract to a virus of economic and public health importance, foot and mouth disease virus (FMDV). IgA responses in cattle are essential for host defense in response to various infectious agents. In cattle, IgA is not released into the colostrum, as is the case for other mammals but only IgG1 is selectively transported. In previous studies in cattle, IgA has been shown to be regulated by several cytokines including IFN-gamma, Type I interferons such as IFN-alpha and IFN-tau, transforming growth factor beta, IgA inducing peptide and other potential factors such as APRIL and BlyS which have not yet been fully evaluated in cattle. Many of these factors, namely TGF-beta and Type I interferons block cell cycle progression which is an essential component of Ig class switching and thus these factors require additional regulatory factors such as IL-2 to drive cells through cell cycle resulting in class switch recombination. Among these factors, IgA inducing peptide was originally identified from a bovine gut associated lymphoid tissue expression library and is highly conserved in pigs and humans at >90% at the amino acid level. The factor is regulated differently in various species but is consistently produced by dendritic cells.
分泌型免疫球蛋白A(SIgA)是机体体液免疫系统的最大组成部分,哺乳动物每天可产生克级量的这种同种型。分泌型免疫球蛋白A(SIgA)抗体通过在黏膜表面阻断病原体/共生菌的进入以及中和病毒发挥作用。已经描述了几种诱导IgA应答的途径,这些途径依赖于T细胞(T细胞依赖性或TD)途径或不依赖于T细胞(T细胞非依赖性或TI),并由树突状细胞(DC)和/或上皮细胞介导。IgA调节的许多要素很容易跨越物种屏障(佐剂、可溶性和同源因子)并且高度保守,而其他途径可能对任何特定物种更具特异性,必须进行评估。牛体内IgA产生的调节尚未完全了解,因此我们部分关注了高度保守的因子,如转化生长因子β、I型和II型干扰素、交错分布于黏膜组织的神经肽(血管活性肠肽或VIP),以及一种小肽(IgA诱导肽或IGIP),这些因子可作为调节靶点并增加SIgA病毒特异性抗体。我们评估了在体外调节这些因子对黏膜表面以及上、下呼吸道分泌物中IgM、IgG和IgA同种型抗体质量方面的调节潜力,该病毒对经济和公共卫生具有重要意义,即口蹄疫病毒(FMDV)。牛体内的IgA应答对于宿主抵御各种感染因子至关重要。在牛中,IgA不像其他哺乳动物那样释放到初乳中,而是只有IgG1被选择性转运。在之前对牛的研究中,已表明IgA受多种细胞因子调节,包括干扰素-γ、I型干扰素如干扰素-α和干扰素-τ、转化生长因子β、IgA诱导肽以及其他潜在因子,如增殖诱导配体(APRIL)和B淋巴细胞刺激因子(BlyS),这些因子在牛中尚未得到充分评估。这些因子中的许多,即转化生长因子β和I型干扰素会阻断细胞周期进程,而细胞周期进程是Ig类别转换的重要组成部分,因此这些因子需要额外的调节因子,如白细胞介素-2来驱动细胞通过细胞周期,从而导致类别转换重组。在这些因子中,IgA诱导肽最初是从牛肠道相关淋巴组织表达文库中鉴定出来的,在猪和人类中氨基酸水平上的保守性超过90%。该因子在不同物种中的调节方式不同,但始终由树突状细胞产生
