黏膜免疫佐剂的研究进展

佐剂对于增强疫苗的免疫效果以及改变免疫应答类型发挥着非常重要的作用。然而,在人用疫苗中可使用的佐剂数量有限,尤其是有效的黏膜免疫佐剂缺乏。黏膜免疫佐剂能有效提高抗原的免疫原性,减少抗原用量或免疫接种次数,促进抗原提呈细胞的提呈作用,从而增强特异性免疫应答;但黏膜免疫佐剂安全性、有效性、免疫效力仍未达到理想的效果,需进一步深入研究。就目前常用的几种黏膜免疫佐剂的研究进展作一综述。     

关于黏膜免疫佐剂的研究现状

佐剂（Aldjuvants）是先于抗原或与抗原同时应用,能非特异性地改变或增强机体对抗原的特异性免疫应答,能增强相应抗原的免疫原性或改变免疫反应类型,而本身并无抗原性的物质,又称免疫佐剂或抗原佐剂。1925年法国免疫学家拉蒙发现在疫苗中加入某些与之无关的物质可以特异性地增强机体的免疫反应。此后,许多国家都不同程度地开展了这方面的研究。     

核酸疫苗佐剂的研究进展

免疫佐剂是一种免疫调节剂,可增强抗原的免疫原性、提高免疫效果。为增强疫苗的免疫原性,在病毒性疫苗、DNA疫苗、多肽疫苗的研制中通常需加入免疫佐剂。随着DNA疫苗研究的深入和扩展,推动了用于提高DNA疫苗免疫效果的免疫佐剂的研究。本文就常用佐剂的研究进展作一综述。     

新型疫苗佐剂的研究进展

与传统的灭活或活体疫苗相比,由基因工程重组抗原或化学合成多肽组成的现代疫苗往往存在免疫原性弱等问题,需要新型的免疫佐剂来增强其作用。尽管传统的铝盐佐剂是目前唯一全球公认的人用佐剂,但存在激发细胞免疫应答能力差等不足,因此,需要研发更为安全有效的人用新型佐剂,尤其是安全无毒、能够刺激较强细胞免疫应答的佐剂,以及适合粘膜疫苗、DNA疫苗和癌症疫苗的免疫佐剂。分析阐述了新型佐剂研究状况和佐剂发展方向,并进一步对新型佐剂的临床前和临床试验研究以及已批准上市的新型疫苗佐剂进行了综述。     

免疫佐剂分类及作用机制

通过现代生物技术制成的DNA疫苗、重组疫苗和亚单位疫苗等新型疫苗,虽然安全性较传统疫苗有所提高,但其免疫原性不及传统疫苗,需要通过佐剂增强疫苗的免疫效力。随着对佐剂研究的不断深入,铝佐剂、油乳佐剂、微生物类佐剂、蜂胶佐剂、左旋咪唑佐剂、脂质体佐剂、中药佐剂及小肽类佐剂等相继问世,其作用机制也随研究的不断深入逐渐清晰。通过动物免疫实验结果发现,小肽类免疫佐剂不仅可以增强特异性免疫反应,具备免疫增强剂的功效,而且获取简单,便于运输保存,安全性高,可能是未来佐剂研究的一个主要方向。     

免疫佐剂在肿瘤免疫疗法中的应用进展

免疫疗法是预防和治疗疾病的有效手段之一。近年来,肿瘤免疫疗法已成为一种新型治疗方法,相关肿瘤疫苗已在多种肿瘤的治疗中被证明有效。然而,在肿瘤疫苗的设计中,肿瘤抗原免疫原性弱、应答率低等问题是目前面对的一大挑战,佐剂的加入为问题的解决提供了一种新的方法和思路。免疫佐剂在提高肿瘤抗原免疫原性、激活机体适应性免疫应答等方面起着十分重要的作用。为了解近几年免疫佐剂的发展及其研究现状,针对目前常用的抗肿瘤佐剂进行综述,并总结了其对免疫系统的作用机制,为后续的疫苗设计策略提供帮助。     

超抗原SEA增强小鼠对HBV DNA 疫苗的免疫反应

观察超抗原SEA(D227A)的真核表达载体(pmSEA),对HBVDNA疫苗诱导Balbc小鼠(H2d)免疫应答的调节作用。肌内注射空载体pcDNA3、HBVDNA疫苗加pmSEA佐剂(pHBVS2S+pmSEA)或不加佐剂(pHBVS2S);ELISA法测定血清抗HBs;ELISPOT检测分泌IFNγ的脾淋巴细胞;4h51Cr释放法检测小鼠脾细胞CTL活性。HBVDNA佐剂组免疫小鼠抗HBsAg抗体滴度明显高于不加佐剂组,其IgG1IgG2a的比例不同于多肽免疫组,二者分别为0.282与10。HBVDNA佐剂组均能增强IgG1和IgG2a的产生,是不加佐剂组的1.36、1.73倍。佐剂组小鼠脾淋巴细胞IFNγ的分泌量是不加佐剂组2～3倍。CTL细胞杀伤活性(E:T=100)佐剂组与不加佐剂组分别为:69.77%±7.5%、42.81%±7.7%,差异显著(P<0.05)。HBVDNA疫苗具有较强的免疫原性,能够诱导机体产生特异性的抗体及CTL反应;pmSEA佐剂能够提高小鼠对DNA疫苗的免疫应答,有望成为DNA疫苗的免疫佐剂。     

免疫佐剂在肿瘤免疫疗法中的应用进展 *

免疫疗法是预防和治疗疾病的有效手段之一.近年来,肿瘤免疫疗法已成为一种新型治疗方法,相关肿瘤疫苗已在多种肿瘤的治疗中被证明有效.然而,在肿瘤疫苗的设计中,肿瘤抗原免疫原性弱,应答率低等问题是目前面对的一大挑战,佐剂的加入为问题的解决提供了一种新的方法和思路.免疫佐剂在提高肿瘤抗原免疫原性,激活机体适应性免疫应答等方面起着十分重要的作用.为了解近几年免疫佐剂的发展及其研究现状,针对目前常用的抗肿瘤佐剂进行综述,并总结了其对免疫系统的作用机制,为后续的疫苗设计策略提供帮助.     

超抗原SEA增强小鼠对HBV DNA 疫苗的免疫反应

观察超抗原SEA(D227A)的真核表达载体（pmSEA）, 对HBV DNA 疫苗诱导Balb/c 小鼠(H2d）免疫应答的调节作用。 肌内注射空载体pcDNA3、HBV DNA 疫苗加pmSEA佐剂（pHBVS2S+pmSEA）或不加佐剂（pHBVS2S）; ELISA 法测定血清抗HBs; ELISPOT检测分泌IFN-γ的脾淋巴细胞;4 h51Cr 释放法检测小鼠脾细胞CTL 活性。HBV DNA佐剂组免疫小鼠抗HBsAg抗体滴度明显高于不加佐剂组,其IgG1/IgG2a的比例不同于多肽免疫组,二者分别为0.282与10。HBV DNA佐剂组均能增强IgG1和IgG2a的产生,是不加佐剂组的1.36、1.73倍。佐剂组小鼠脾淋巴细胞IFN-γ的分泌量是不加佐剂组2～3倍。CTL 细胞杀伤活性（E:T=100）佐剂组与不加佐剂组分别为：69.77%±7.5%、 42.81%±7.7%,差异显著(P<0.05)。HBV DNA 疫苗具有较强的免疫原性, 能够诱导机体产生特异性的抗体及CTL反应;pmSEA佐剂能够提高小鼠对DNA 疫苗的免疫应答,有望成为DNA 疫苗的免疫佐剂。     

黏膜免疫佐剂研究进展

免疫佐剂是加入疫苗制剂后能促进、延长或增强对疫苗抗原特异性免疫应答的物质。好的免疫佐剂可使少量的抗原诱导机体产生早期、高效和持久的免疫应答。本文主要就近几年国内外对黏膜免疫佐剂种类(主要包括细菌性物质、各种细胞因子、某些无机成分、可增强抗原呈递的相关载体)及作用机理的研究近况作一综述。     

Adjuvant formulations and delivery systems for DNA vaccines

DNA vaccines have become a reliable and major means to elicit immune responses in the past decade. We and others have attempted to obtain stronger, more long lasting, and optimized immune responses, subsequent to the pioneering works demonstrating the ability of plasmid DNA to raise specific immune responses. Advances in molecular biology and biotechnology allow the application of various adjuvants, immunologic agents that increase the antigenic response, in DNA vaccines. Adjuvants can be broadly separated into two classes based on their origin-genetic and conventional. Genetic adjuvants are expression vectors of cytokines or other molecules that can modulate immune responses when administered with a vaccine antigen. Conventional adjuvants are chemical compounds that enhance, prolong, or modulate antigen-specific immune responses. The use of an appropriate adjuvant is pivotal in optimizing the response to DNA vaccines. Moreover, DNA vaccines themselves possess their own adjuvant activity because of the presence of unmethylated CpG motifs in particular base contents. The route of inoculation is also a critical factor in determining the outcome of vaccination. It is well known that intramuscular injection preferentially induces Th1-type immunity, whereas particle bombardment by gene gun predominantly induces Th2-type response. This article focuses on providing the detailed procedure to construct genetic adjuvant plasmids and prepare DNA vaccines formulated with conventional adjuvants. We also offer a practical guide for the procedure of intramuscular DNA injection.     

NEXT GENERATION DNA VACCINES FOR HIV-1

ABSTRACT

We studied the effects of first generation HIV-1 plasmid vaccines in 167 individuals. The vaccines were very well tolerated and induced helper T cell responses in most vaccine recipients. However, the CTL responses were below a 20% response rate. Improvement in vaccine potency is an important goal of this technology and a central focus of our laboratory. To improve on these response rates, we used RNA optimized constructs pGag and pEnv). These vaccines express 20–100 fold better than first generation vectors. However, our studies support that additional enhancements are needed to further boost the immune response. We report that we can significantly enhance the induced CD8 effector cell response by including engineered B7 costimulatory molecules. We observed that B7.2 was more effective at driving cellular immune responses than B7.1 as a plasmid vaccine. We developed gene swaps and deletions between these two molecules. This manipulation resulted in a dramatically enhanced cellular immune response as measured by CTL, or ICC or Elispot. We have also explored the use of cytokines as plasmid vaccine adjuvants. We observed that IL-12 and IL-15 were effective as plasmid vaccine adjuvants. Interestingly, IL-15 appeared to allow T cell expansion in the absence of significant T cell help. Improvement of the immune response induced by plasmid vaccines can be engineered in multiple ways. Our studies show that both costimulation as well as cytokine signals can be harnessed for more potent vaccine development. These results have important implications for the design of vaccines for prophylaxis and therapy.     

Beyond empiricism: informing vaccine development through innate immunity research

Although a great public heath success, vaccines provide suboptimal protection in some patient populations and are not available to protect against many infectious diseases. Insights from innate immunity research have led to a better understanding of how existing vaccines work and have informed vaccine development. New adjuvants and delivery systems are being designed based upon their capacity to stimulate innate immune sensors and target antigens to dendritic cells, the cells responsible for initiating adaptive immune responses. Incorporating these adjuvants and delivery systems in vaccines can beneficially alter the quantitative and qualitative nature of the adaptive immune response, resulting in enhanced protection.     

Next generation DNA vaccines for HIV-1

We studied the effects of first generation HIV-1 plasmid vaccines in 167 individuals. The vaccines were very well tolerated and induced helper T cell responses in most vaccine recipients. However, the CTL responses were below a 20% response rate. Improvement in vaccine potency is an important goal of this technology and a central focus of our laboratory. To improve on these response rates, we used RNA optimized constructs pGag and pEnv). These vaccines express 20-100 fold better than first generation vectors. However, our studies support that additional enhancements are needed to further boost the immune response. We report that we can significantly enhance the induced CD8 effector cell response by including engineered B7 costimulatory molecules. We observed that B7.2 was more effective at driving cellular immune responses than B7.1 as a plasmid vaccine. We developed gene swaps and deletions between these two molecules. This manipulation resulted in a dramatically enhanced cellular immune response as measured by CTL, or ICC or Elispot. We have also explored the use of cytokines as plasmid vaccine adjuvants. We observed that IL-12 and IL-15 were effective as plasmid vaccine adjuvants. Interestingly, IL-15 appeared to allow T cell expansion in the absence of significant T cell help. Improvement of the immune response induced by plasmid vaccines can be engineered in multiple ways. Our studies show that both costimulation as well as cytokine signals can be harnessed for more potent vaccine development. These results have important implications for the design of vaccines for prophylaxis and therapy.     

Probiotics,antibiotics and the immune responses to vaccines

Orally delivered vaccines have been shown to perform poorly in developing countries. There are marked differences in the structure and the luminal environment of the gut in developing countries resulting in changes in immune and barrier function. Recent studies using newly developed technology and analytic methods have made it increasingly clear that the intestinal microbiota activate a multitude of pathways that control innate and adaptive immunity in the gut. Several hypotheses have been proposed for the underperformance of oral vaccines in developing countries, and modulation of the intestinal microbiota is now being tested in human clinical trials. Supplementation with specific strains of probiotics has been shown to have modulatory effects on intestinal and systemic immune responses in animal models and forms the basis for human studies with vaccines. However, most studies published so far that have evaluated the immune response to vaccines in children and adults have been small and results have varied by age, antigen, type of antibody response and probiotic strain. Use of anthelminthic drugs in children has been shown to possibly increase immunogenicity following oral cholera vaccination, lending further support to the rationale for modulation of the immune response to oral vaccination through the intestinal microbiome.     

Role of immunostimulatory molecules in poultry vaccines

Immunization by vaccination is the most suitable and safest method for preventing infectious diseases in the poultry worldwide. Vaccines alone cannot effectively protect birds from variety of pathogens under field conditions. The combined use of potent immunostimulants in vaccines is an alternative to increase the efficacy of vaccines that can be achieved by the development of better adjuvant. One such adjuvant is cytokine; cytokines have been used extensively as adjuvant in vaccines and are responsible for the type and extent of an immune response following vaccination. Although the innate immune system in birds is not fully characterized but their immune system is very much similar to that of mammals, and moreover with the recent discovery of a number of avian cytokine genes it is now possible to study their effectiveness in enhancing the immune response during vaccination. This review focuses on the recent studies and developments involving the role of immunomodulating agents especially cytokines of avian origin in poultry vaccines.     

Increased Generation of HIV-1 gp120-Reactive CD8+ T Cells by a DNA Vaccine Construct Encoding the Chemokine CCL3

DNA vaccines based on subunits from pathogens have several advantages over other vaccine strategies. DNA vaccines can easily be modified, they show good safety profiles, are stable and inexpensive to produce, and the immune response can be focused to the antigen of interest. However, the immunogenicity of DNA vaccines which is generally quite low needs to be improved. Electroporation and co-delivery of genetically encoded immune adjuvants are two strategies aiming at increasing the efficacy of DNA vaccines. Here, we have examined whether targeting to antigen-presenting cells (APC) could increase the immune response to surface envelope glycoprotein (Env) gp120 from Human Immunodeficiency Virus type 1 (HIV-1). To target APC, we utilized a homodimeric vaccine format denoted vaccibody, which enables covalent fusion of gp120 to molecules that can target APC. Two molecules were tested for their efficiency as targeting units: the antibody-derived single chain Fragment variable (scFv) specific for the major histocompatilibility complex (MHC) class II I-E molecules, and the CC chemokine ligand 3 (CCL3). The vaccines were delivered as DNA into muscle of mice with or without electroporation. Targeting of gp120 to MHC class II molecules induced antibodies that neutralized HIV-1 and that persisted for more than a year after one single immunization with electroporation. Targeting by CCL3 significantly increased the number of HIV-1 gp120-reactive CD8⁺ T cells compared to non-targeted vaccines and gp120 delivered alone in the absence of electroporation. The data suggest that chemokines are promising molecular adjuvants because small amounts can attract immune cells and promote immune responses without advanced equipment such as electroporation.     

Highly potent mRNA based cancer vaccines represent an attractive platform for combination therapies supporting an improved therapeutic effect

Direct vaccination with mRNA encoding tumor antigens is a novel and promising approach in cancer immunotherapy. CureVac's mRNA vaccines contain free and protamine-complexed mRNA. Such two-component mRNA vaccines support both antigen expression and immune stimulation. These self-adjuvanting RNA vaccines, administered intradermally without any additional adjuvant, induce a comprehensive balanced immune response, comprising antigen specific CD4+ T cells, CD8+ T cells and B cells. The balanced immune response results in a strong anti-tumor effect and complete protection against antigen positive tumor cells. This tumor inhibition elicited by mRNA vaccines is a result of the concerted action of different players. After just two intradermal vaccinations, we observe multiple changes at the tumor site, including the up-regulation of many genes connected to T and natural killer cell activation, as well as genes responsible for improved infiltration of immune cells into the tumor via chemotaxis. The two-component mRNA vaccines induce a very fast and boostable immune response. Therefore, the vaccination schedules can be adjusted to suit the clinical situation. Moreover, by combining the mRNA vaccines with therapies in clinical use (chemotherapy or anti-CTLA-4 antibody therapy), an even more effective anti-tumor response can be elicited. The first clinical data obtained from two separate Phase I/IIa trials conducted in PCA (prostate cancer) and NSCLC (non-small cell lung carcinoma) patients have shown that the two-component mRNA vaccines are safe, well tolerated and highly immunogenic in humans.