The reverse proteomics for identification of tumor antigens

The identification of tumor antigens is essential for the development of anticancer therapeutic vaccines and clinical diagnosis of cancer. SEREX (serological analysis of recombinant cDNA expression libraries) has been used to identify such tumor antigens by screening sera of patients with cDNA expression libraries. SEREX-defined antigens provide markers for the diagnosis of cancers. Potential diagnostic values of these SEREX-defined antigens have been evaluated. SEREX is also a powerful method for the development of anticancer therapeutics. The development of anticancer vaccines requires that tumor antigens can elicit antigen-specific antibodies or T lymphocytes. More than 2000 antigens have been discovered by SEREX. Peptides derived from some of these antigens have been evaluated in clinical trials. This review provides information on the application of SEREX for identification of tumor-associated antigens (TAA) for the development of cancer diagnostics and anticancer therapeutics.     

Gold complexes as prospective metal-based anticancer drugs

Medical and therapeutic value of gold has been recognized thousands of years ago, but its rational use in medicine has not begun until the early 1920s. Cisplatin is one of the first metal-containing compounds with anti-cancer activity discovered in the 1960s. Despite the fact that cisplatin treatment is efficient for several types of solid tumors, its effectiveness is limited by toxic side effects and tumor resistance that often leads to the occurrence of secondary malignancies. Since gold(III) is isoelectronic with platinum(II) and tetracoordinate gold(III) complexes have the same square-planar geometries as cisplatin, the anticancer activity of gold(III) compounds has been investigated. Previous studies suggested that, in contrast to cisplatin, gold complexes target proteins but not DNA. Recently, we have investigated gold(III) dithiocarbamates for their anticancer activity and showed that their primary target is the proteasome. Treatment of human breast tumor-bearing nude mice with a gold(III) dithiocarbamate complex resulted in significant inhibition of tumor growth, associated with proteasome inhibition and massive apoptosis induction in vivo. Better understanding of physiological processing of gold compounds will provide a rational basis for their further development into novel anticancer drugs.     

A comparison and critical analysis of preclinical anticancer vaccination strategies

Anticancer vaccines have been extensively studied in animal models and in clinical trials. While vaccination can lead to tumor protection in numerous murine models, objective tumor regressions after anticancer vaccination in clinical trials have been rare. B16 is a poorly immunogenic murine melanoma that has been extensively used in anticancer vaccination experiments. Because B16 has been widely used, different vaccination strategies can be compared. We reviewed the results obtained when B16 was treated with five common vaccine types: recombinant viral vaccines, DNA vaccines, dendritic cell vaccines, whole-tumor vaccines, and peptide vaccines. We also reviewed the results obtained when B16 was treated with vaccines combined with adoptive transfer of tumor antigen-specific T cells. We found several characteristics of vaccination regimens that were associated with antitumor efficacy. Many vaccines that incorporated xenogeneic antigens exhibited more potent anticancer activity than vaccines that were identical except that they incorporated the syngeneic version of the same antigen. Interleukin-2 enhanced the antitumor efficacy of several vaccines. Finally, several effective regimens generated large numbers of tumor antigen-specific CD8(+) T cells. Identification of vaccine characteristics that are associated with antitumor efficacy may aid in the development of more effective anticancer vaccination strategies.     

Pilot study of a novel combination of two therapeutic vaccines in advanced non-small-cell lung cancer patients

Cancer vaccines contain tumor antigens in a pro-inflammatory context with the purpose to generate potent antitumor immune responses. However, tumor cells develop different immunosuppressive mechanisms that limit the effectiveness of an anticancer immune response. Therefore, therapeutic vaccine treatment alone is usually not sufficient to generate tumor regression or survival improvement, especially in the advanced disease scenario in which most clinical studies have been conducted. Combining cancer vaccines with different anticancer therapies such as chemotherapy, radiotherapy and other immunotherapeutic agents has had different levels of success. However, the combination of cancer vaccines with different mechanisms of action has not been explored in clinical trials. To address this issue, the current review summarizes the main clinical and immunological results obtained with two different therapeutic vaccines used in advanced non-small-cell lung cancer patients, inducing an immune response against epidermal growth factor (CIMAvax-EGF) and NGcGM3 ganglioside (racotumomab). We also discuss preliminary findings obtained in a trial of combination of these two vaccines and future challenges with these therapies.     

Glycopeptide-functionalized gold nanoparticles for antibody induction against the tumor associated mucin-1 glycoprotein

We report the preparation of gold nanoparticle (AuNP)-based vaccine candidates against the tumor-associated form of the mucin-1 (MUC1) glycoprotein. Chimeric peptides, consisting of a glycopeptide sequence derived from MUC1 and the T-cell epitope P30 sequence were immobilized on PEGylated AuNPs and the ability to induce selective antibodies in vivo was investigated. After immunization, mice showed significant MHC-II mediated immune responses and their antisera recognized human MCF-7 breast cancer cells. Nanoparticles designed according to this report may become key players in the development of anticancer vaccines.     

Unveiling the anticancer and antimycobacterial potentials of bioengineered gold nanoparticles

Synthesis of gold nanoparticles was carried out using Pongammia pinnata (pongam) leaf extract and their anticancer and antimycobacterial activities were studied. Gold nanoparticle formation was confirmed by UV–vis, XRD and HR-TEM. The anticancer efficacies of the biogenic gold nanoparticles were analyzed using cytotoxicity, cell morphology analysis, oxidative DNA damage, apoptosis detection and toxicity studies. Biogenic gold nanoparticles inhibited breast cancer cell line (MCF-7) proliferation with an efficacy of IC₅₀ of 1.85 μg/mL. The antimycobacterial potential of the biogenic gold nanoparticles was screened against M. tuberculosis by Luciferase Reporter Phage (LRP) assay. The gold nanoparticles showed inhibition against sensitive M. tuberculosis with the minimum inhibitory concentration (MIC) of 10 μg/mL whereas no inhibition was found against the rifampicin resistant M. tuberculosis.     

Proteomic characterization of the cytotoxic mechanism of gold (III) porphyrin 1a, a potential anticancer drug

There has been increasing interest in the potential applications of gold (III) complexes as anticancer drugs with higher cytotoxicity and fewer side effects than existing metal anticancer drugs. Our previous findings demonstrated that gold (III) porphyrin 1a preferentially induced apoptosis in a cancer cell line (SUNE1). In this study, we identified differentially expressed proteins related to the drug's cytotoxic action by comparing the protein alterations induced by gold (III) porphyrin 1a and cisplatin treatments. Several clusters of altered proteins were identified, including cellular structure and stress-related chaperone proteins, proteins involved in reactive oxygen species and enzyme proteins, translation factors, proteins that mediate cell proliferation or differentiation, and proteins participating in the internal degradation systems. Our results indicated that multiple factors leading to apoptosis were involved in drug cytotoxicity in SUNE1 cells. The balance between pro-apoptotic and anti-apoptotic signals determined the final fate of cancer cells.     

The results of using direct solid-phase immunoenzyme analysis for assessing the specific activity of rabies vaccines

The effectiveness of the solid-phase enzyme immunoassay (EIA) in the determination of the specific activity of rabies vaccines is evaluated in comparison with that of the protective test in mice. Inactivated tissue-culture, concentrated tissue-culture and purified cerebral tissue vaccines for human use were studied. The methods for performing two EIA variants and evaluating the results are described. The average level of correlation between the results of EIA and the protective test for vaccines of different groups was revealed (0.546), the highest correlation index being obtained for tissue-culture vaccines: 0.753. On the basis of the data obtained in this study the expediency of using EIA for the determination of the specific activity of rabies vaccines has been substantiated.     

Accelerated immune response to DNA vaccines

DNA vaccines offer considerable promise for improvement over conventional vaccines. For the crucial step of delivering DNA vaccines intracellularly, electroporation (EP) has proven to be highly effective. This method has yielded powerful humoral and cellular responses in various species, including nonhuman primates. In an attempt to further improve DNA vaccination we used micron-size gold particles (which do not bind or adsorb DNA) as a particulate adjuvant which was coinjected with DNA intramuscularly into mice, followed by EP of the target site. The presence of gold particles accelerated the antibody response significantly. Maximum titers against hepatitis B surface antigen (HBsAg) were reached after one boost in 6 weeks, whereas 8 weeks were required without particles. These immunizations were effective in protecting mice against tumor challenge with cancer cells expressing HBsAg as a surrogate cancer antigen. Computer modeling of electric fields and gene expression studies indicate that gold particles do not stimulate EP and subsequent antigen expression. The particles may act as an attractant for immune cells, especially antigen presenting cells. We conclude that particulate adjuvants combined with DNA vaccine delivery by EP reduces the immune response time and may increase vaccine efficacy. This method may become valuable for developing prophylactic as well as therapeutic vaccines. The rapid response may be of particular interest in countering bio-terrorism.     

Immunocytochemical characterization of viruses and antigenic macromolecules in viral vaccines

Gold immunolabeling combined with negative staining (GINS) provides a valuable immunocytochemical approach that allows a direct ultrastructural definition of all viral vaccine constituents that share common antigenic features with pathogenic viral particles. These results have implications for the development of viral vaccines since it has been demonstrated that incomplete viral particles such as natural empty capsides and Rotavirus-like particles lacking the infective genome are potential candidates for the production of neutralizing antibodies. Furthermore comparative results of the application of GINS to either inactivated vaccines or unfixed samples provide direct evidence that even after inactivation specific antigenic sites are still available for gold immunolabeling.     

Superior antimalarial immunity after vaccination with late liver stage-arresting genetically attenuated parasites

While subunit vaccines have shown partial efficacy in clinical trials, radiation-attenuated sporozoites (RAS) remain the "gold standard" for sterilizing protection against Plasmodium infection in human vaccinees. The variability in immunogenicity and replication introduced by the extensive, random DNA damage necessary to generate RAS could be overcome by genetically attenuated parasites (GAP) designed via gene deletion to arrest at defined points during liver-stage development. Here, we demonstrate the principle that late liver stage-arresting GAP induce larger and broader CD8 T cell responses that provide superior protection in inbred and outbred mice compared to RAS or early-arresting GAP immunizations. Late liver stage-arresting GAP also engender high levels of cross-stage and cross-species protection and complete protection when administered by translationally relevant intradermal or subcutaneous routes. Collectively, our results underscore the potential utility of late liver stage-arresting GAP as broadly protective next-generation live-attenuated malaria vaccines and support their potential as a powerful model for identifying antigens to generate cross-stage protection.     

Immunogenicity and Cross Protective Ability of the Central VP2 Amino Acids of Infectious Pancreatic Necrosis Virus in Atlantic Salmon (Salmo salar L.)

Infectious pancreatic necrosis virus (IPNV) is a member of the family Birnaviridae that has been linked to high mortalities in juvenile salmonids and postsmolt stages of Atlantic salmon (Salmo salar L.) after transfer to seawater. IPN vaccines have been available for a long time but their efficacy has been variable. The reason for the varying immune response to these vaccines has not well defined and studies on the importance of using vaccine trains homologous to the virulent field strain has not been conclusive. In this study we prepared one vaccine identical to the virulent Norwegian Sp strain NVI-015 (NCBI: 379740) (T₂₁₇A₂₂₁T₂₄₇ of VP2) and three other vaccine strains developed using the same genomic backbone altered by reverse genetics at three residues yielding variants, T₂₁₇T₂₂₁T₂₄₇, P₂₁₇A₂₂₁A₂₄₇, P₂₁₇T₂₂₁A₂₄₇. These 4 strains, differing in these three positions only, were used as inactivated, oil-adjuvanted vaccines while two strains, T₂₁₇A₂₂₁T₂₄₇ and P₂₁₇T₂₂₁A₂₄₇, were used as live vaccines. The results show that these three residues of the VP2 capsid play a key role for immunogenicity of IPNV vaccines. The virulent strain for inactivated vaccines elicited the highest level of virus neutralization (VN) titers and ELISA antibodies. Interestingly, differences in immunogenicity were not reflected in differences in post challenge survival percentages (PCSP) for oil-adjuvanted, inactivated vaccines but clearly so for live vaccines (TAT and PTA). Further post challenge viral carrier state correlated inversely with VN titers at challenge for inactivated vaccines and prevalence of pathology in target organs inversely correlated with protection for live vaccines. Overall, our findings show that a few residues localized on the VP2-capsid are important for immunogenicity of IPNV vaccines.     

Novel ELISA method as exploratory tool to assess immunity induced by radiated attenuated sporozoites to decipher protective immunity

Background

Whole parasite vaccines provide a unique opportunity for dissecting immune mechanisms and identify antigens that are targeted by immune responses which have the potential to mediate sterile protection against malaria infections. The radiation attenuated sporozoite (PfSPZ) vaccine has been considered the gold standard for malaria vaccines because of its unparalleled efficacy. The immunogenicity of this and other vaccines continues to be evaluated by using recombinant proteins or peptides of known sporozoite antigens. This approach, however, has significant limitations by relying solely on a limited number of known pathogen-associated immune epitopes. Using the full range of antigens expressed by the sporozoite will enable the comprehensive immune-profiling of humoral immune responses induced by whole parasite vaccines. To address this challenge, a novel ELISA based on sporozoites was developed.

Results

The SPZ-ELISA method described in this report can be performed with either freshly dissected sporozoites or with cryopreserved sporozoite lysates. The use of a fixative for reproducible coating is not required. The SPZ-ELISA was first validated using monoclonal antibodies specific for CSP and TRAP and then used for the characterization of immune sera from radiation attenuated sporozoite vaccinees.

Conclusion

Applying this simple and highly reproducible approach to assess immune responses induced by malaria vaccines, both recombinant and whole parasite vaccines, (1) will help in the evaluation of immune responses induced by antigenically complex malaria vaccines such as the irradiated SPZ-vaccine, (2) will facilitate and accelerate the identification of immune correlates of protection, and (3) can also be a valuable assessment tool for antigen discovery as well as down-selection of vaccine formulations and, thereby, guide vaccine design.

     

Enzymatic large-scale synthesis of MUC6-Tn glycoconjugates for antitumor vaccination

In cancer, mucins are aberrantly O-glycosylated, and consequently, they express tumor-associated antigens such as the Tn determinant (alpha-GalNAc-O-Ser/Thr). As compared with normal tissues, they also exhibit a different pattern of expression. In particular, MUC6, which is normally expressed only in gastric tissues, has been detected in intestinal, pulmonary, colorectal, and breast carcinomas. Recently, we have shown that the MCF7 breast cancer cell line expresses MUC6-Tn glycoproteins in vivo. Cancer-associated mucins show antigenic differences from normal mucins, and as such, they may be used as potential targets for immunotherapy. To develop anticancer vaccines based on the Tn antigen, we prepared several MUC6-Tn glycoconjugates. To this end, we performed the GalNAc enzymatic transfer to two recombinant MUC6 proteins expressed in Escherichia coli, using UDP-N-acetylgalactosamine: polypeptide N-acetylgalactosaminyltransferases (ppGalNAc-Ts), which catalyze in vivo the Tn antigen synthesis. We used either a mixture of ppGalNAc-Ts from MCF7 breast cancer cell extracts or a recombinant ppGalNAc-T1. In both cases, we achieved the synthesis of MUC6-Tn glycoconjugates at a semi-preparative scale (mg amounts). These glycoproteins displayed a high level of Tn antigens, although the overall density depends on both enzyme source and protein acceptor. These MUC6-Tn glycoconjugates were recognized by two anti-Tn monoclonal antibodies that are specific to human cancer cells. Moreover, the MUC6-Tn glycoconjugate glycosylated using MCF7 extracts as the ppGalNAc-T source was able to induce immunoglobulin G (IgG) antibodies that recognized a human tumor cell line. In conclusion, the large-scaled production of MUC6 with tumor-relevant glycoforms holds considerable promise for developing effective anticancer vaccines, and further studies of their immunological properties are warranted.     

人乳头瘤病毒(HPV)58型DNA疫苗免疫原性的初步分析

为了检测HPV 58型不同L1基因的DNA疫苗的免疫原性,以pcDNA3.1为载体分别构建含HFV 58型不同L1基因的DNA疫苗,命名为L1h、L1h△c、L1S、L1SM和L1wt.用免疫印迹法检测各DNA疫苗的体外表达情况;各重组质粒与pcDNA3.1-h58L2和pcDNA3.1-GFP共转染293FT细胞,检测其形成假病毒的能力;并将各DNA疫苗肌肉注射免疫小鼠,利用假病毒中和实验检测中和抗体水平,用ELISPOT检测细胞免疫情况.结果显示,本实验成功构建了五种DNA疫苗,L1h△c的体外表达量最高,L1S和L1SM的表达量次之,L1wt没有表达;重组质粒L1S能够形成假病毒,而其他四种重组质粒均不能形成假病毒.L1S和L1h均可在小鼠体内诱导中和抗体,但L1S诱导的中和抗体的平均滴度为1:6 400,明显高于L1h诱导的中和抗体水平(平均滴度为1:48),而其他疫苗在小鼠体内未产生中和抗体.对五种疫苗均未检测出特异性的细胞免疫反应.结果提示,体外能够组装成假病毒的DNA疫苗在免疫动物后可诱导高滴度的中和抗体,为今后DNA疫苗的筛选提供参考.     

Quantitation of gold labeling and estimation of labeling efficiency with a stereological counting method.

The amount of immunolabeling over a cell compartment of an average cell was estimated by use of an adaptation of the double disector method introduced by Gundersen. The first and last sections of a stack of ultra-thin sections formed a disector in which cell number could be estimated and related to a defined reference volume to give the cell density. Another stack section, selected at random, was immunolabeled and the number of gold particles associated with unit volume reference space (gold "density") estimated in quadrats placed systematically across the section. The ratio of gold density to cell density was used to estimate the number of gold particles lying over a chosen compartment of an average cell, N(gold)/N(cell). Such estimates required neither cell volume nor section thickness measurement and were reproducible. By combining the number of gold particles per cell with estimates of the number of protein antigens per cell, the number of gold particles associated with each antigen could be found (labeling efficiency).     

The synthesis, chemical and biological properties of dichlorido(azpy)gold(III) chloride (azpy=2-(phenylazo)pyridine) and the gold-induced conversion of the azpy ligand to the chloride of the novel tricyclic pyrido[2,1-c][1,2,4]benzotriazin-11-ium cation

A new Au(III) coordination compound with the ligand 2-(phenylazo)pyridine has been synthesized and fully characterized by means of elemental analysis, IR, UV-visible, conductivity measurements, NMR, electrospray ionization (ESI-MS) and inductively coupled plasma optical emission spectrometry (ICP-OES). The chemical stability of the cation in this compound, [Au(azpy)Cl(2)](+) (abbreviated: Au-azpy), was analyzed by means of several physicochemical methods. While stable in the solid state, stability studies performed with the gold compound in solution showed an unexpected and unprecedented reactivity. A cationic organic derivative of 2-(phenylazo)pyridine, (abbreviated: pyrium), was produced from the solution and has been isolated as its chloride salt and characterized by crystal structure determination, elemental analysis, NMR, ESI-MS and conductivity studies in solution. This cyclization reaction is reported for the first time in the case of gold coordination compounds. The Au adduct and the pyrium cation were investigated as potential cytotoxic and anticancer agents, and both show moderate to high cytotoxic properties in cisplatin-sensitive and cisplatin-resistant ovarian carcinoma cell lines, A2780; and cisplatin-sensitive and cisplatin-resistant murine lymphocytic leukemia cell lines, L1210. Significant anticancer activity against the cisplatin resistant cell lines was found for the pyrium salt, ruling out the occurrence of cross resistance phenomena.     

新型冠状病毒肺炎:实验室检测、治疗及疫苗

新型冠状病毒肺炎(2019 novel coronavirus disease,COVID-19),一种由动物来源的新型冠状病毒(severe acute respiratory syndrome coronavirus 2,SRAS-CoV-2)感染所致的疾病在全球范围内急速传播,严重的危害人类的健康.快速、准确的诊...     

De-differentiation-derived mesenchymal stem cells demonstrate selective repression in H19 bioregulatory RNA gene expression

Cellular de-differentiation can induce anticancer activity that makes cells resistant to carcinogenesis, but the molecular mechanism of this phenomenon has not been defined. To determine whether stable molecular changes develop in association with the process of de-differentiation, DNA microarray analyses were performed. These analyses compared control undifferentiated cells with three carcinogenesis-resistant clones of de-differentiated cells that were derived from mature adipocytes. The results of analysis of 6,000 genes and 6,000 ESTs establish that relative to control cells, all three de-differentiation-derived cell clones demonstrate that only one gene shows a consistent difference in expression. The expression of the H19 bioregulatory RNA is repressed an average of >fourfold in all de-differentiated cell clones. Real-time PCR analyses confirm these findings. This suggests that decreased H19 expression may account, at least in part, for the anticancer activity observed in de-differentiated cell clones.