Intestinal antigen-presenting cells in mucosal immune homeostasis:Crosstalk between dendritic cells,macrophages and B-cells

The intestinal immune system maintains a delicate balance between immunogenicity against invading pathogens and tolerance of the commensal microbiota. Inflammatory bowel disease (IBD) involves a breakdown in tolerance towards the microbiota. Dendritic cells (DC), macrophages (MΦ) and B-cells are known as professional antigen-presenting cells (APC) due to their specialization in presenting processed antigen to T-cells, and in turn shaping types of T-cell responses generated. Intestinal DC are migratory cells, unique in their ability to generate primary T-cell responses in mesenteric lymph nodes or Peyer’s patches, whilst MΦ and B-cells contribute to polarization and differentiation of secondary T-cell responses in the gut lamina propria. The antigen-sampling function of gut DC and MΦ enables them to sample bacterial antigens from the gut lumen to determine types of T-cell responses generated. The primary function of intestinal B-cells involves their secretion of large amounts of immunoglobulin A, which in turn contributes to epithelial barrier function and limits immune responses towards to microbiota. Here, we review the role of all three types of APC in intestinal immunity, both in the steady state and in inflammation, and how these cells interact with one another, as well as with the intestinal microenvironment, to shape mucosal immune responses. We describe mechanisms of maintaining intestinal immune tolerance in the steady state but also inappropriate responses of APC to components of the gut microbiota that contribute to pathology in IBD.

Cinnamon extract suppresses experimental colitis through modulation of antigen-presenting cells

AIM:To investigate the anti-inflammatory effects of cinnamon extract and elucidate its mechanisms for targeting the function of antigen presenting cells.METHODS:Cinnamon extract was used to treat murine macrophage cell line(Raw 264.7),mouse primary antigen-presenting cells(APCs,MHCII+) and CD11c+dendritic cells to analyze the effects of cinnamon extract on APC function.The mechanisms of action of cinnamon extract on APCs were investigated by analyzing cytokine production,and expression of MHC antigens and co-stimulatory molecules by quantitative real-time PCR and flow cytometry.In addition,the effect of cinnamon extract on antigen presentation capacity and APC-dependent T-cell differentiation were analyzed by [H3]-thymidine incorporation and cytokine analysis,respectively.To confirm the anti-inflammatory effects of cinnamon extract in vivo,cinnamon or PBS was orally administered to mice for 20 d followed by induction of experimental colitis with 2,4,6 trinitrobenzenesulfonic acid.The protective effects of cinnamon extract against experimental colitis were measured by checking clinical symptoms,histological analysis and cytokine expression prof iles in inflamed tissue.RESULTS:Treatment with cinnamon extract inhibited maturation of MHCII+ APCs or CD11c+ dendritic cells(DCs) by suppressing expression of co-stimulatory molecules(B7.1,B7.2,ICOS-L),MHCII and cyclooxygenase(COX)-2.Cinnamon extract induced regulatory DCs(rDCs) that produce low levels of pro-inflammatory cytokines [interleukin(IL)-1β,IL-6,IL-12,interferon(IFN)-γ and tumor necrosis factor(TNF)-α] while expressing high levels of immunoregulatory cytokines(IL-10 and transforming growth factor-β).In addition,rDCs generated by cinnamon extract inhibited APC-dependent T-cell proliferation,and converted CD4+ T cells into IL-10high CD4+ T cells.Furthermore,oral administration of cinnamon extract inhibited development and progression of intestinal colitis by inhibiting expression of COX-2 and pro-inflammatory cytokines(IL-1β,IFN-γ and TNF-α),while enhancing IL-10 levels.CONCLUSION:Our study suggests the potential of cinnamon extract as an anti-inflammatory agent by targeting the generation of regulatory APCs and IL-10+ regulatory T cells.

Impact of PRRSV on activation and viability of antigen presenting cells

Porcine reproductive and respiratory syndrome(PRRS) is one of the most important diseases of swine industry. The causal agent, PRRS-virus(PRRSV), is able to evade the host immune response and survive in the organism causing transient infections. Despite all scientific efforts, there are still some gaps in the knowledge of the pathogenesis of this disease. Antigen presenting cells(APCs), as initiators of the immune response, are located in the first line of defense against microorganisms, and are responsible for antigen recognition, processing and presentation. Dendritic cells(DCs) are the main type of APC involved in antigen presentation and they are susceptible to PRRSV infection. Thus, PRRSV replication in DCs may trigger off different mechanisms to impair the onset of a host effective immune response against the virus. On the one side, PRRSV may impair the basic functions of DCs by regulating the expression of major histocompatibility complex class Ⅱ and CD80/86. Other strategy followed by the virus is the induction of cell death of APCs by apoptosis, necrosis or both of them. The impairment and/or cell death ofAPCs could lead to a failure in the onset of an efficient immune response, as long as cells could not properly activate T cells. Future aspects to take into account are also discussed in this review.

Interaction between antigen presenting cells and autoreactive T cells derived from BXSB mice with murine lupus

Systemic lupus erythematosus （SLE） is a typical autoimmune disease involving multiple systems and organs. Ample evidence suggests that autoreactive T cells play a pivotal role in the development of this autoimmune disorder. This study was undertaken to investigate the mechanisms of interaction between antigen presenting cells （APCs） and an autoreactive T cell （ATLI） clone obtained from lupus-prone BXSB mice. ATLI cells, either before or after 7-ray irradiation, were able to activate naive B cells, as determined by B cell proliferation assays. Macrophages from BXSB mice were able to stimulate the proliferation of resting ATL 1 cells at a responder/stimulator （R/S） ratio of 1/2.5. Dendritic cells （DCs） were much more powerful stimulators for ATLI cells on a per cell basis. The T cell stimulating ability ofmacrophages and B cells, but not DCs, was sensitive to T-ray irradiation. Monoclonal antibodies against mouse MHC-Ⅱ and CD4 were able to block DC-mediated stimulation of ATL 1 proliferation, indicating cognate recognition between ATL 1 and APCs. Our data suggest that positive feedback loops involving macrophages, B cells and autoreactive T cells may play a pivotal role in keeping the momentum of autoimmune responses leading to autoimmune diseases.

Changes of the Transcriptional Levels of Molecules Associated with Endogenous Antigen Processing and Presentation in Porcine Skin-derived Dendritic Cells Infected with PCV2 in vivo

[Objective] This study aimed to investigate the changes of the transcriptional levels of molecules associated with endogenous antigen processing and presenta- tion in porcine skin-derived dendritic cells infected with PCV2 in vivo. [Method] Healthy 40-day-old Landrace piglets were infected with porcine circovirus type 2 （PCV2） and euthanized on the 34, 7rd, 14th, 21st and 35th d post inoculation （DPI）. The porcine skin-derived dendritic cells （DCs） were collected to analyze the transcrip- tional levels of molecules （LMP7, UBP, MHC-I, calreticulin） associated with endogenous antigen processing and presentation by using real-time fluorescent quantitative PCR （real-time FQ-PCR）. [Result] The results showed that the level of LMP7 mR- NAs was reduced significantly on the 3DPI （P〈0.05）; the level of UBP mRNAs was consistently up-regulated, which increased significantly on the 21DPI and 35DPI （P〈 0.05）; the level of MHC-I mRNAs was significantly down-regulated on the 7DPI （P〈 0.05）; the level of calreticulin mRNAs was up-regulated slightly without significant dif- ference. [Conclusion] PCV2 can inhibit the endogenous antigen processing and presentation ability of porcine skin-derived DCs at early stages of infection.

Particle elasticity influences polymeric artificial antigen presenting cell effectiveness in vivo via CD8+T cell activation,macrophage uptake,and the protein corona

Adoptive cell therapy(ACT)is an immunotherapy strategy for cancer that has seen widespread clinical success.During ACT,patient-derived lymphocytes are stimulated with the antigen of interest ex vivo,proliferated,then returned to the patient to initiate an antigen-specific antitumor response.While effective,this process is resource-intensive and logistically impossible for many patients.Particulate artificial antigen presenting cells(aAPCs)offer a potential“off-the-shelf”alternative to ex vivo ACT.While particulate aAPCs perform well in vitro,they have had limited success in vivo due to poor bioavailability after injection.Barriers to bioavailability include rapid clearance,unfavorable biodistribution,and inadequate interactions with CD8+T cells at sites of interest.Biomaterial properties such as elasticity have been shown to vastly impact the bioavailability and particle-cell interactions,but this has yet to be investigated in the context of aAPCs for in vivo T-cell stimulation.Previous literature likewise indicates that biomaterial properties,especially elasticity,can modulate T-cell activation in vitro.With the goal of creating a more biomimetic,next-generation particulate aAPC,we developed a poly(ethylene)glycol hydrogel particle platform with tunable elasticity to investigate the impact of elasticity on antigen-specific T cell activation for in vivo adoptive transfer.Using this knowledge,we were able to gain more precise control over in vivo T cell activation and investigate possible mechanisms including the effects of aAPC elasticity on T cell binding,macrophage uptake,and the protein corona.

Hepatitis C virus and ethanol alter antigen presentation in liver cells

Alcoholic patients have a high incidence of hepatitis C virus （HCV） infection. Alcohol consumption enhances the severity of the HCV disease course and worsens the outcome of chronic hepatitis C. The accumulation of virally infected cells in the liver is related to the HCV- induced inability of the immune system to recognize infected cells and to develop the immune responses. This review covers the effects of HCV proteins and ethanol on major histocompatibility complex （MHC） class Ⅰ- and class Ⅱ-restricted antigen presentation. Here, we discuss the liver which functions as an immune privilege organ; factors, which affect cleavage and loading of antigenic peptides onto MHC class I and class ~I in hepatocytes and dendritic cells, and the modulating effects of ethanol and HCV on antigen presentation by liver cells. Altered antigen presentation in the liver limits the ability ＇of the immune system to clear HCV and infected cells and contributes to disease progression. HCV by itself affects dendritic cell function, switching their cytokine profile to the suppressive phenotype of interleukin-10 （IL-10） and transforming growth factor beta （TGFβ） predominance, preventing cell maturation and allostimulation capacity. The synergistic action of ethanol with HCV results in the suppression of MHC class Ⅱ-restricted antigen presentation. In addition, ethanol metabolism and HCV proteins reduce proteasome function and interferon signaling, thereby suppressing the generation of peptides for MHC class I -restricted antigen presentation. Collectively, ethanol exposure further impairs antigen presentation in HCV-infected liver cells, which may provide a partial explanation for exacerbations and the poor outcome of HCV infection in alcoholics.

Cilostazol inhibits plasmacytoid dendritic cell activation and antigen presentation

Background Cilostazol, an anti-platelet drug for treating coronary heart disease, has been reported to modulate immune cell functions Plasmacytoid dendritic cells （pDCs） have been found to participate in the progression of atherosclerosis mainly through interferon ct （IFN-ct） production. Whether cilostazol influences pDCs activation is still not clear. In this study, we aimed to investigate the effects of cilostazol on cell activation and antigen presentation ofpDCs in vitro in this study. Methods Peripheral blood mononuclear cells isolated by Ficoll cen- trifugation and pDCs sorted by flow cytometry were used in this study. After pretreated with cilostazol for 2 h, cells were stimulated with CpG-A, R848 or virus for 6 h or 20 h, or stimulated with CpG-B for 48 h and then co-cultured with naive T cell for five days. Cytokines in supernatant and intracellular cytokines were analyzed by ELISA or flow cytometry respectively. Results Our data indicated that cilostazol could inhibit IFN-α and tumor necrosis factor α （TNF-α） production from pDCs in a dose-dependent manner. In addition, the ability of priming na ve T cells of pDCs was also impaired by cilostazol. The inhibitory effect was not due to cell killing since the viability of pDCs did not change upon cilostazol treatment. Conclusion Cilostazol inhibits pDCs cell activation and antigen presentation in vitro, which may explain how cilostazol protects against atherosclerosis.

α₂-macroglobulin co-administered <i>in vivo</i>promotes antigen delivery and presentation

Administered in vivo, covalent receptor-recognized α2-macroglobulin (α2M*)-antigen complexes enhance humoral and cell-mediated immunity. We hypothesized that in vivo α2M*-encapsulation could be promoted in the setting of vaccines that co-deliver α2M* with unbound antigen, thereby eliminating the need to prepare complexes in vitro. Mice immunized intradermally with co-delivered α2M* and OVA demonstrated antigen-specific immune responses, including anti-tumor responses, similar to those elicited by conjugated α2M*-OVA complexes. Enhanced immunity appears to result from in vivo α2M*-encapsulation of antigen. This finding represents a significant advancement in the development of α2M* as an antigen delivery vehicle capable of enhancing the presentation of subunit vaccines.

动物疫病活载体疫苗研究进展

活载体疫苗是以细菌或病毒作为载体表达外源抗原和治疗因子的载体系统,具有安全性高、毒力返祖风险低、成本低,可诱导免疫机体产生高水平的体液免疫、细胞免疫或黏膜免疫等优点,是目前最具发展潜力的基因工程疫苗之一,在动物疫病防控领域应用较多。病毒载体包括DNA病毒(如腺病毒、腺相关病毒和痘病毒等)和RNA病毒(如新城疫病毒、流感病毒等);细菌载体包括减毒致病菌与非致病菌两类,主要包括乳酸菌、沙门氏菌、大肠杆菌等。活载体疫苗常用的抗原呈递策略有载体-宿主平衡致死系统、微生物表面展示系统。多种疫苗载体的开发及抗原呈递策略的选择,使得活载体疫苗的使用价值最大化。不同载体疫苗在预防疫病方面均有不同优缺点,应根据实际情况选择最优最适合的活载体疫苗。本文综述了动物疫病防控领域的病毒和细菌活载体疫苗研究进展及其抗原呈递方式,以期为活载体疫苗的进一步研究提供参考。

T细胞免疫反应载体疫苗在人类疾病预防和治疗中的应用

人类疾病,特别是传染病和癌症,对公共卫生安全和全球经济构成前所未有的挑战。预防和治疗性疫苗的开发是应对人类疾病的优先对策。本文综述了疫苗载体的免疫学原理、T细胞载体疫苗设计策略及疫苗研究进展,为新型疫苗的设计提供新的思路。T细胞可以在机体发生感染后分化成不同的效应T细胞群,它们可以起到清除病原体的作用,关于效应T细胞功能和机制的研究对于设计能够引发基于T细胞免疫的疫苗至关重要。目前很多病毒(例如HIV、HCMV感染)和肿瘤疫苗的研发都侧重于T细胞类疫苗,在所有疫苗种类中,激活T细胞免疫反应的载体疫苗具有显著优势。许多来源的载体,包括病毒载体、细菌载体和核酸载体,它们在抗原提呈能力、免疫原性和保护效力方面都有良好的表现。此外,还总结了T细胞载体疫苗设计的策略,包括确定适当的抗原提呈途径和载体递送途径、确保生物安全性、如何选择合适的疫苗的载体、各种载体疫苗的优缺点等,尤其是mRNA疫苗在应对新冠疫情中发挥了重要的作用。疫苗载体的技术进步将会加速新型疫苗的研发,并且能促进人们对突发公共卫生事件的应对。

单细胞测序揭示心脏移植物中树突状细胞和B细胞的抗原提呈特性

目的探讨心脏移植物中树突状细胞(DC)和B细胞的抗原提呈特性。方法将BALB/c小鼠的心脏移植到C57BL/6J小鼠腹腔内,术后5 d(急性排斥反应早期)提取并流式分选心脏移植物中的CD45+细胞,进行单细胞RNA测序。以心脏移植物中的DC和B细胞的亚群为主要对象,通过生物信息学分析和流式细胞术,研究其在心脏移植后变化趋势、抗原提呈能力及其与T细胞之间的胞间通讯情况。采用基因本体(GO)功能富集差异分析佐证细胞亚群特异性功能和细胞亚群注释可信度。结果生发中心样B细胞(GC-L B)是急性排斥反应期心脏移植物中增幅最大、比例高达87%的B细胞亚群,经典DC(cDC)2是心脏移植急性排斥期间唯一大量增多的DC亚群,占44%,是心脏移植后与T细胞的胞间通讯中占据最高通讯强度的DC亚群;单核样DC(moDC)与记忆性B细胞(MBC)是未心脏移植中T细胞输入信号的主要发出者,而在心脏移植后急性排斥反应期中,转变为cDC2与GC-L B;其中MBC与GC-L B分别是心脏移植前后的主要T细胞输入信号来源。结论在未移植心脏和移植心脏指向T细胞的胞间通讯中,与DC相比,B细胞均占据更高的通讯数量和权重,推测在心脏移植急性排斥反应早期,B细胞的抗原提呈活动比DC更加活跃,强度更大。

胃腺癌中抗原处理相关转运蛋白1的表达和临床意义

目的探讨胃腺癌(stomach adenocarcinoma,STAD)中抗原处理相关转运蛋白1(transporter associated with antigen processing 1,TAP1)表达与临床病理特征的关系及其预后意义。方法通过癌症基因组图谱(The Cancer Genome Atlas,TCGA)数据库收集TAP1在STAD组织中的mRNA表达水平和患者临床资料。采用GraphPad Prism软件分析TAP1表达与临床病理特征的关系,采用Kaplan-Meier曲线分析其与患者总生存期的关系。采用蛋白质印迹法检测STAD细胞株MKN45和AGS以及人正常胃黏膜上皮细胞株GES-1中TAP1的蛋白表达。收集2020年1月1日至12月31日武汉大学中南医院病理科的STAD组织标本122例和2020年10月1日至12月31日武汉大学中南医院病理科的正常胃切除标本24例,采用免疫组织化学法检测组织中的TAP1表达,分析其与患者临床病理特征的关系。结果TCGA数据库分析和组织标本的免疫组织化学分析均显示,TAP1在STAD组织中较正常胃组织高表达(均P<0.05)。TAP1在STAD细胞株MKN45中的表达较正常胃黏膜上皮细胞株GES-1高(P<0.01),而人STAD细胞株AGS与GES-1中TAP1水平比较,差异无统计学意义(P>0.05)。在STAD组织中,TAP1蛋白表达水平在STAD的Laurén分型方面比较,差异具有统计学意义(P<0.05)。TCGA数据库分析发现,TAP1表达水平随肿瘤组织分级的增加而升高(P<0.05)。TCGA数据库中STAD患者按TAP1表达中位数6.82分为TAP1高表达组和低表达组。TAP1高表达组中位总生存期更长(57.1个月vs 25.1个月,P<0.05)。结论TAP1在STAD组织中高表达,且与Laurén分型和组织分级相关,为预后保护因素,可作为STAD预后的潜在标志物。

合成生物技术助力纳米颗粒疫苗理性设计时代的到来

纳米颗粒疫苗自1981年首次应用于人体以来,经历逾40年的发展历程,在临床应用方面已取得了极大成功。尤其是在乙型肝炎病毒(hepatitis B virus,HBV)、人乳头瘤病毒(human papillomavirus,HPV)等疫苗领域,纳米颗粒疫苗以显著的免疫原性和良好的安全性在遏制病毒传播和疾病防控方面发挥了不可替代的作用,为人类社会的健康安全作出了巨大贡献。自新型冠状病毒疫情爆发以来,迫切的防控需要进一步推动了包括纳米颗粒疫苗在内的各类新型疫苗技术的发展。然而,由于被相对更经验化的设计方式和更复杂的制备工艺制约,纳米颗粒疫苗临床转化应用的速度并不突出。因此,通过理性设计来提升纳米颗粒疫苗的研制效率和应用范围,正成为其未来发展的重要方向和关键目标。合成生物技术在纳米颗粒疫苗发展的过程中一直起着重要作用。近年来,新型合成生物技术的应用在推动纳米颗粒平台灵活性方面取得了显著进展,有望满足未来对抗原承载多样性的需求。本文首先综述了纳米颗粒疫苗发展的技术沿革与进展,从抗原自组装形成的纳米颗粒疫苗到抗原协助组装的纳米颗粒疫苗,再到抗原平台展示的纳米颗粒疫苗。其次,总结了纳米颗粒疫苗提高抗原淋巴引流效率、抗原增强B细胞信号活化、抗原具有独特的抗原提呈方式等增强抗原免疫原性的特殊作用。最后概括了纳米颗粒疫苗在新型冠状病毒流行中的转化应用,如新型冠状病毒刺突蛋白三聚体疫苗、协助组装的新冠纳米颗粒疫苗、标签偶联展示的新冠纳米颗粒疫苗。随着对免疫应答机理的深入研究和对抗原提呈新规律的发现,利用合成生物技术也将有助于充分发掘纳米颗粒疫苗的独特免疫功能、满足高难度疫苗研制的要求。因此有理由相信:在合成生物技术助力下,未来纳米颗粒疫苗将在新突发及重大传染性疾病的防控中做出更突出的贡献。

B细胞在非感染性葡萄膜炎中的研究进展

非感染性葡萄膜炎是一种严重威胁视力,治疗棘手的自身免疫性眼病。目前主流观点认为非感染性葡萄膜炎的发病机制是主要由CD4+T细胞介导的免疫失衡。但近年来许多证据表明B细胞也发挥关键作用,通过产生抗体、抗原提呈、分泌细胞因子、形成异位淋巴结构等多种方式参与到实验性自身免疫性葡萄膜炎模型及人类葡萄膜炎中。针对B细胞的治疗已广泛应用于多种自身免疫性疾病。利妥昔单抗,一种B细胞抑制剂,在对传统皮质类固醇和免疫抑制剂治疗无效的难治性非感染性葡萄膜炎中发挥不错疗效。本文总结了B细胞在非感染性葡萄膜炎中的作用及细胞疗法,旨在为更深入的机制研究提供理论基础,并为开发精准有效的防治策略开辟新视角。

抗原提呈细胞亚群预测肝癌患者的免疫治疗疗效研究

背景原发性肝细胞癌(hepatocellular carcinoma,HCC)患者中免疫治疗应用广泛,但需寻找有效的疗效预测标志物,以此提供个体化和精准化的治疗。目的探讨抗原提呈细胞(antigen presenting cell,APC)亚群与HCC患者免疫治疗的疗效关系。方法前瞻性纳入2022年5月—2023年9月在解放军总医院第五医学中心初次接受免疫治疗的中晚期HCC患者,通过流式细胞仪检测免疫治疗前的B细胞/淋巴细胞(B/LYM)、巨噬细胞/所有核细胞(MA/TNC)和树突细胞/所有核细胞(DC/TNC)的比值。根据均值将患者分为高水平组和低水平组,并比较两组间无进展生存期(progression free survival,PFS),并通过Cox分析影响PFS的因素。最后利用ROC曲线预测疾病控制的效能。结果共纳入84例患者,中位年龄为57岁;男性58例,女性26例。APC亚群基线数据:B/LYM均值为16.54%±6.27%,MA/TNC均值为9.14%±2.87%,DC/TNC均值为0.051%±0.021%。Kaplan-Meier生存分析和Cox回归分析显示B/LYM高值组的mPFS显著高于低值组(5.90个月vs 5.50个月,P=0.019;HR=0.588,95%CI:0.358~0.966),MA/TNC低值组的mPFS显著高于高值组(7.20个月vs 5.40个月,P=0.034;HR=0.617,95%CI:0.374~1.019),DC/TNC高值组的mPFS显著高于低值组(6.30个月vs 5.50个月,P=0.026;HR=0.615,95%CI:0.378~0.955)。且高水平的MA/TNC是疾病进展的独立危险因素,高水平的DC/TNC、B/LYM是疾病进展的保护因素。基线B/LYM、MA/TNC、DC/TNC对HCC患者接受2周期治疗后的疾病控制情况而言,具有较好的预测效能,且联合应用时效能进一步提高,AUC分别为0.685、0.723、0.745、0.865。结论高DC/TNC、B/LYM水平和低MA/TNC水平的HCC患者,可能更容易从免疫治疗中获益。

Impact of nanoparticles on immune cells and their potential applications in cancer immunotherapy

Nanoparticles represent a heterogeneous collection of materials,whether natural or synthetic,with dimensions aligning in the nanoscale.Because of their intense manifestation with the immune system,they can be harvested for numerous bio-medical and biotechnological advancements mainly in cancer treatment.This review article aims to scrutinize various types of nanoparticles that interact differently with immune cells like macrophages,dendritic cells,T lymphocytes,and natural killer(NK)cells.It also underscores the importance of knowing how nanoparticles influence immune cell functions,such as the production of cytokines and the presentation of antigens which are crucial for effective cancer immunotherapy.Hence overviews of bio-molecular mechanisms are provided.Nanoparticles can improve antigen presentation,boost T-cell responses,and overcome the immunosuppressive tumor environment.The regulatory mechanisms,signaling pathways,and nanoparticle characteristics are also presented for a comprehensive understanding.We review the nanotechnology platform options and challenges in nanoparticlesbased immunotherapy,from an immunotherapy perspective including precise targeting,immune modulation,and potential toxicity,as well as personalized approaches based on individual patient and tumor characteristics.The development of emerging multifunctional nanoparticles and theranostic nanoparticles will provide new solutions for the precision and efficiency of cancer therapies in next-generation practice.

真菌毒素对树突状细胞免疫应答的影响

真菌毒素是病原真菌产生的次级代谢产物,常污染多种农作物,通过食物链对人畜健康造成严重危害。真菌毒素具有多种毒性作用,包括神经毒性、肝毒性、免疫毒性、致畸性和致癌性等,但其免疫毒性机制尚不完全清楚。树突状细胞(DCs)作为功能最强大的抗原提呈细胞,在启动先天免疫和获得性免疫应答中发挥重要作用。现有研究发现真菌毒素能够影响DCs的内吞作用、刺激T细胞活化的能力以及细胞因子和趋化因子的分泌,本文旨在综述真菌毒素对DCs免疫应答的影响,为后续研究阐明真菌毒素的免疫毒性机制提供参考。

肿瘤细胞原位重编程为抗原呈递细胞的策略

免疫逃逸是肿瘤的基本特征之一,而免疫疗法近年来在肿瘤治疗中取得了巨大成功。这些疗法包括免疫检查点抑制剂、过继性细胞疗法[如嵌合抗原受体T细胞疗法(CAR-T)和肿瘤浸润淋巴细胞(TIL)]、癌症疫苗、溶瘤病毒等。细胞疗法在多种血液肿瘤中疗效显著,但在实体肿瘤的治疗中效果并不理想,主要原因是回输的免疫细胞难以充分浸润到肿瘤部位。为解决这一难题,研究者尝试将肿瘤组织内的癌细胞原位重编程为免疫细胞,从而充分激活抗肿瘤免疫反应并克服以往细胞治疗依赖体外细胞扩增的局限,同时具有免疫排斥反应弱的优点。目前,肿瘤原位重编程的目标细胞包括巨噬细胞、粒细胞、树突状细胞(DC)和T细胞等,其中树突状细胞作为经典抗原呈递细胞(APC)在启动免疫反应中发挥核心作用,是增强抗肿瘤免疫应答的关键效应细胞。迄今有两种原位重编程的方法,即基于转录因子异位表达及共刺激信号分子和细胞因子共表达策略,均显示出较强的转化应用前景。

In vitro and in vivo analyses of a genetically-restricted antigen specific factor from mixed cell cultures of macrophage, T and B lymphocytes

An immunostimulatory factor was identified to be secreted by antigen-pulsed maorophages. This factor was able to induce the generation of antigen specific T helper lymphocytes in vitro as well as in vivo. Further in vitro experiments testing for the genetic restriction of this factor indicated that it is a genetically-restricted antigen specific factor (ASF). The Cunningham plaque assay was used to quantify the generation of T helper lymphocytes by measuring the number of plaque forming cells after sequential incubations of antigen-pulsed maorophages with T lymphocytes, and then spleen cells, and finally the TNP-coated sheep red blood cells.