固相MHC Ⅰ类相关抗原A刺激的NK细胞对树突状细胞活性的影响

目的:观察固相MHC I类相关抗原A(iMICA)刺激的NK细胞对树突状细胞(DCs)活性的影响。方法:首先取新鲜分离及受固相MICA刺激的异体NK细胞,或IL-2、及IL-2联合iMICA刺激的自体NK细胞与未成熟DCs(iDCs)按5∶1比例孵育24 h后,用流式细胞术(FCM)分析HLA-DR+或CD86+频率的DCs。然后取自体NK细胞以iMICA刺激后,按1∶5的比例与iDCs孵育24 h后,FCM检测DCs上HLA-DR、CD86的表达。最后在NK细胞与DCs的共培养体系中加入抗IFN-γ抗体,观察DCs上HLA-DR、CD86表达的变化。结果:当NK细胞与iDCs孵育比例为5∶1时,异体新鲜分离的与自体活化的NK细胞均能杀伤iDCs;而iMICA无协同作用。当NK细胞与iDCs孵育的比例为1∶5时,iMICA刺激的NK细胞可促进DCs表达HLA-DR和CD86;而加入抗IFN-γ抗体可抑制NK细胞诱导DCs表面HLA-DR和CD86表达的上调。结论:异体新鲜分离的或自体活化的NK细胞杀伤iDCs时,无需iMICA的刺激;但当NK细胞的数目明显低于iDCs时,iMICA可刺激NK细胞分泌IFN-γ促进DCs成熟。     

重组可溶性MHC Ⅰ类相关蛋白A对NK细胞生物学活性的影响

目的:研究体外重组可溶性MHC Ⅰ类相关蛋白A(sMICA)对NK细胞杀伤靶细胞活性、分泌IFN-γ、增殖和凋亡的影响.方法:将重组sMICA蛋白与人外周血NK细胞相互作用过夜后,流式细胞仪检测NK细胞杀伤K562靶细胞的能力;ELISA检测培养上清IFN-γ浓度;MTS/PMS法检测sMICA对NK细胞增殖的影响;给NK细胞标记Annexin V和碘化丙啶检测凋亡情况.结果:可溶性MICA抑制NK细胞杀伤K562细胞的活性,下调IFN-γ的分泌,却对NK细胞的增殖和凋亡没有影响.结论:肿瘤细胞表面脱落的sMICA抗原可通过抑制NK细胞活性而逃逸机体的免疫监视功能.     

NK细胞识别MHC Ⅰ类分子的机理

人及鼠Ｎ细胞上抑制性受体的结构功能已研究得较为清楚了。其识别ＭＨＣⅠ类分子的机理公认的“失去自己”的假说,具体作用模式为效应抑制模式和靶干扰模式,前者已越来越为实验所证实,本文对效应抑制模式的信号传导机制及ＮＫ细胞抑制性受体识别ＭＨＣ Ⅰ类分子位点的研究进行了综述。     

NK细胞识别MHC Ⅰ类分子的机理

人及鼠Ｎ细胞上抑制性受体的结构功能已研究得较为清楚了，其识别ＭＨＣⅠ类分子的机理公认的为“失去自己”假说，具体作用模式为效应抑制模式和靶干扰模式，前者已越来越为实验所证实。本文对效应抑制模式的信号传导机制及ＮＫ细胞抑制性受体识别ＭＨＣⅠ类分子位点的研究进行了综述。     

MHC I类分子呈递抗原的途径与肽疫苗研制的进展

主要组织相容性复合体Ｉ类分子主要呈递内源合成抗原，供ＣＤ８＾＋细胞毒Ｔ淋巴细胞识别，抗原呈递转运子与肽相互作用是特异性抗原肽转运和呈递的关键。外源性抗原通过树突状细胞和巨噬细胞等只性抗原呈递细胞加工处理后也可被ＭＨＣＩ类分子呈递。     

膜型/分泌型MICA对NK细胞受体NKG2D的相反调节效应及其对NK细胞受体谱的影响

目的　观察膜型和分泌型MICA对NK细胞受体表达的影响 ,以探讨NK细胞抗肿瘤活化机制及肿瘤细胞表达MICA分子的意义。方法　用MTT法测定人NK细胞系 (NK92 )的细胞毒活性 ;用RT PCR或FACS检测NK细胞受体 (NKG2D ,NKG2A B ,KIR2DL1,KIR2DS1)及NKG2D的识别配体MICA的表达。结果　肿瘤细胞表面的MICA分子可上调NKG2D的表达 ,下调抑制性受体NKG2A B和KIR2DL1的表达 ;而分泌型MICA (sMICA)分子对NKG2D及抑制性受体的表达均有抑制作用。结论　膜型MICA分子可上调NKG2D的表达 ,激发NK细胞对肿瘤细胞的细胞毒效应 ;分泌型MICA分子则通过降低NKG2D的表达下调机体的抗肿瘤免疫效应 ,肿瘤细胞分泌sMICA分子为肿瘤发生免疫逃逸的机制之一。     

紫草萘醌提取物对小鼠NK细胞活性的增强作用

本文研究了紫草萘醌单体提取物(Lm)对小鼠NK细胞毒活性的调节作用。每日经腹腔注射每公斤体重6mg的Lm,连续5天,小鼠脾细胞NK细胞毒提高约20%(p<0.001).细胞毒动力学分析的结果显示:给药小鼠的动力学实验参数Vmax和Kmapp均明显增加而Vmax/Kmapp则无明显变化,提示Lm增强NK活性的机理为增加了杀伤细胞的频率.     

Co-evolution of MHC class I and variable NK cell receptors in placental mammals

Shaping natural killer (NK) cell functions in human immunity and reproduction are diverse killer cell immunoglobulin-like receptors (KIRs) that recognize polymorphic MHC class I determinants. A survey of placental mammals suggests that KIRs serve as variable NK cell receptors only in certain primates and artiodactyls. Divergence of the functional and variable KIRs in primates and artiodactyls predates placental reproduction. Among artiodactyls, cattle but not pigs have diverse KIRs. Catarrhine (humans, apes, and Old World monkeys) and platyrrhine (New World monkeys) primates, but not prosimians, have diverse KIRs. Platyrrhine and catarrhine systems of KIR and MHC class I are highly diverged, but within the catarrhines, a stepwise co-evolution of MHC class I and KIR is discerned. In Old World monkeys, diversification focuses on MHC-A and MHC-B and their cognate lineage II KIR. With evolution of C1-bearing MHC-C from MHC-B, as informed by orangutan, the focus changes to MHC-C and its cognate lineage III KIR. Evolution of C2 from C1 and fixation of MHC-C drove further elaboration of MHC-C-specific KIR, as exemplified by chimpanzee. In humans, the evolutionary trajectory changes again. Emerging from reorganization of the KIR locus and selective attenuation of KIR avidity for MHC class I are the functionally distinctive KIR A and KIR B haplotypes.     

A one-step monoclonal antibody typing procedure that simplifies HLA class I and class II typing

Abstract: We have developed monoclonal antibodies to most HLA specificities, making it possible for us to devise a simple, rapid, one-step micro-cytotoxicity test. The test is performed by adding 1 μl of cells to 1 μl of antibody-complement mixture predotted on the microtest tray. The reactions are read following a 1-hour incubation period (30 minutes in some instances). The analysis of reactions seen on testing 105 class I antibodies and 50 class II antibodies is shown. A comparison of typing by the standard NIH method and the new one-step procedure showed a > 96% concordance in the 500 T cells and 200 B cells we examined. Class I and class II typing could be performed using B cells, thus obviating the need to isolate both T and B cells for HLA typing.     

Conformational changes in MHC class I molecules

In this article we review the role of MHC conformation, including peptide-induced MHC conformation, in forming antibody (Ab), T-cell receptor (TCR), and natural killer (NK) cell receptor epitopes. Abs recognize conformational major histocompatibility (MHC) epitopes that often are influenced by the identity of MHC-bound peptide. Diverse TCRs recognize a common docking site on peptide/MHC complexes and directly contact peptide. Human NK cell inhibitory receptors (KIR) appear to recognize limited regions of the HLA α₁ helix. DX9+ KIR specifically focus on HLA-B residues 82 and 83. However, NK cells recognize much broader regions of HLA class I molecules and are sensitive to bound peptides. Thus, several classes of lymphocyte receptors are peptidespecific. Peptide specificity could be the result of direct contact with the receptor, or to conformational shifts in MHC residues that interact with both receptor and bound peptide.     

Viral and bacterial minigene products are presented by MHC class I molecules with similar efficiencies

MHC class I molecules present short peptides, usually 8-10 amino acids in length, to CD8⁺ T cells. These peptides are typically generated from full-length endogenously synthesized proteins degraded by the antigen processing machinery of the target cell. However, exogenous proteins, whether originating from intracellular bacteria or parasites or via phagocytosis during cross-presentation, can also be processed for presentation by MHC class I molecules. It is currently not known whether endogenously synthesized proteins and proteins acquired from exogenous sources follow the same presentation pathway. One clue that the processing pathways followed by endogenous and exogenous proteins may not be identical is the vastly different presentation efficiencies reported for viral versus bacterial antigens. Because class I antigen processing involves multiple steps, we sought to determine where in the processing pathway these differences in efficiency occur. To accomplish this, we expressed identical minimal peptide determinants from viral and bacterial vectors using a minigene expression system and determined the rate of peptide-MHC generation per molecule of minigene product synthesized. We found that peptides expressed from either the viral or bacterial vector were presented with virtually identical efficiencies. These results suggest that differences in the processing pathways followed by endogenous versus exogenous proteins most likely occur at a point prior to where free peptide is liberated from full-length protein.     

MHC class I expression protects target cells from lysis by Ly49-deficient fetal NK cells

Using appropriate conditions natural killer (NK) cells can be cultured from the liver and thymus of day 14 fetal mice. These fetal NK cells are phenotypically and functionally indistinguishable from adult NK cells with the exception that they lack measurable expression of all of the Ly49 molecules that can currently be detected with antibodies. Despite this, they preferentially kill tumor cells and blast cells deficient in the expression of major histocompatibility complex class I molecules, although the degree of discrimination is usually weaker than that shown by adult NK cells and varies depending on the particular combination of effector and target cells used. Polymerase chain reaction analysis revealed that although fetal NK cells are severely deficient in the expression of mRNA for Ly49A, B, C, D, G, H, and I they express high levels of Ly49E mRNA, raising the possibility that Ly49E may have an important and special function in the early development of the NK lineage.     

Identification of woodchuck class I MHC antigens using monoclonal antibodies

Abstract: Two class I major histocompatibility complex (MHC) proteins with molecular masses of 43- and 39-kDa were identified in the cell surface membranes of normal woodchucks using a newly developed anti-woodchuck class I monoclonal antibody (mAb) B1b.B9 and immuno-blotting. B1b.B9 was generated by immunizing mice with viable wood-chuck peripheral blood mononuclear cells and was selected for anti-class I MHC reactivity using a cellular enzyme–linked immunoassay, indirect immunofluorescence on tissue sections and flow cytofluorimetry. The distribution pattern of class I MHC antigen on woodchuck lymphoid cells was found to be similar to that reported in other species. Also, the antigen expression on normal woodchuck hepatocytes was comparable to that observed on normal human liver parenchymal cells; thus, the antigen was not detected on hepatocytes by staining of liver tissue sections, but was found by indirect immunofluorescence staining of isolated liver cells. Western blot analysis of the plasma membranes from normal woodchuck hepatocytes revealed the presence of a single species of class I MHC heavy chain protein with a molecular mass of 43-kDa, whereas splenocyte plasma membranes showed intense expression of a 43-kDa species, as well as the presence of a 39-kDa protein. The 39- and 43-kDa proteins were extracted with Triton X-114 to the hydrophobic protein phase, suggesting that they both contain a hydrophobic transmembrane domain. The data obtained indicate that the B1b.B9 identifies a nonpolymorphic epitope of woodchuck class I MHC heavy chains, providing an important reagent for the study of the pathogenesis of hepatitis B virus infection in a woodchuck model.     

The E5 oncoprotein of BPV-4 does not interfere with the biosynthetic pathway of non-classical MHC class I

The major histocompatibility complex (MHC) class I region in mammals contains both classical and non-classical MHC class I genes. Classical MHC class I molecules present antigenic peptides to cytotoxic T lymphocytes, whereas non-classical MHC class I molecules have a variety of functions. Both classical and non-classical MHC molecules interact with natural killer cell receptors and may under some circumstances prevent cell death by natural killer cytotoxicity. The E5 oncoprotein of BPV-4 down-regulates the expression of classical MHC class I on the cell surface and retains the complex in the Golgi apparatus. The inhibition of classical MHC class I to the cell surface results from both the impaired acidification of the Golgi, due to the interaction of E5 with subunit c of the H+ V-ATPase, and to the physical binding of E5 to the heavy chain of MHC class I. Despite the profound effect of E5 on classical MHC class I, E5 does not retain a non-classical MHC class I in the Golgi, does not inhibit its transport to the cell surface and does not bind its heavy chain. We conclude that, as is the case for HPV-16 E5, BPV-4 E5 does not down-regulate certain non-classical MHC class I, potentially providing a mechanism for the escape of the infected cell from attack by both cytotoxic T lymphocytes and NK cells.     

MHC class I restricted T cell responses tolisteria monocytogenes, an intracellular bacterial pathogen

Studies of the murine immune response to infection with the intracellular bacterial pathogenListeria monocytogenes have provided a wealth of information about innate and acquired immune defenses in the setting of an infectious disease. Our studies have focused on the MHC class I restricted, CD8⁺ T cell responses of Balb/c mice toL. monocytogenes infection. Four peptides that derive from proteins thatL. monocytogenes secretes into the cytosol of infected cells are presented to cytotoxic T lymphocyte (CTL) by the H2-K^d major histocompatibility complex (MHC) class I molecule. We have found that bacterially secreted proteins are rapidly degraded in the host cell cytosol by proteasomes that utilize, at least in part, the N-end rule to determine the rate of degradation. The MHC class I antigen processing pathway is remarkably efficient at generating peptides that bind to MHC class I molecules. The magnitude of in vivo T cell responses, however, is influenced to only a small degree by the amount of antigen or the efficiency of antigen presentation. Measurements of in vivo T cell expansion followingL. monocytogenes infection indicate that differences in the sizes of peptide-specific T cell responses are more likely owing to differences in the repertoire of naive T cells than to differences in peptide presentation. This notion is supported by our additional finding that dominant T cell populations express a more diverse T cell receptor (TCR) repertoire than do subdominant T cell populations.