Pieranna Chiarella

Electroporation of skeletal muscle induces danger signal release and antigen-presenting cell recruitment independently of DNA vaccine administration.

Background: Plasmid DNA vaccination combined with electroporation (EP) provides a promising approach for the prevention of infectious diseases and for cancer immunotherapy. This technology has been described as being effective in activating humoural and cellular immune response in the host as well as in enhancing expression of the encoded antigen. Several reports showed EP has adjuvant-like properties when combined with plasmid DNA injection although the effect in the absence of DNA has not been investigated. Objective: The aim of this study is to clarify whether the application of EP alone to the skeletal muscle is able to recruit and trigger cells involved in antigen presentation and immune response. Methods: Mouse skeletal muscle treated by EP were observed and processed for clinical, histological and immunohistochemistry analysis at different time points. Results: We demonstrate that EP induces transient morphological changes in the muscle with early production of endogenous cytokines responsible for signalling danger at the local level. Moreover, it causes the recruitment of inflammatory cells independently of the DNA injection and the activation of a danger pro-inflammatory pathway, resulting in T-lymphocyte migration. Conclusions: Our data indicate EP by itself is able to recruit and trigger cells involved in antigen presentation and immune response; hence, the idea that EP has adjuvant-like properties owing to a moderate tissue injury and generation of a pro-inflammatory context with cytokine release that enhances the immune response. We suggest EP may be of practical use in clinical protocols, contributing to the development of DNA vaccination strategies.

Mouse monoclonal antibodies in biological research : strategies for high-throughput production

Mouse monoclonal antibodies have become key components in basic research as well as in the clinical laboratory. Being invaluable tools in many biological assays, they continue to be the primary choice in the research field, although the conventional technology used for hybridoma generation and screening is a still lengthy, time-consuming and low-throughput process. With the advent of genetic immunisation and the application of automation and microarray to the traditional biological assays, the monoclonal antibody field has been revolutionised. Here, we will briefly review the most relevant strategies which have made the manufacture of murine monoclonal antibodies a faster and high-throughput technology.

Application of Electroporation in DNA Vaccination Protocols

Vaccination is historically one of the most important methods for preventing infectious diseases in humans and animals. Due to recent advances in understanding the biology of the immune system, a more rational design of vaccines and vaccination strategies such as those based on gene transfer have been proposed. In particular, naked DNA vaccination is emerging as a promising approach for introducing foreign antigens into the host, inducing protective immunity against infectious diseases and malignant tumours. Plasmid DNA vaccines offer several advantages in comparison to traditional vaccines such as safety, tolerability and feasibility in manufacture. Nevertheless, because of their poor immunogenicity, plasmid DNA vaccines need further implementation. Recent data suggest electroporation as useful strategy to improve DNA-based vaccination protocols, being able to stimulate both the humoural and cellular immune responses. In pre-clinical trials, electroporation is successfully used in prime-boost combination protocols and its efficacy and tolerability has been demonstrated in Phase I clinical trials. Since these initial results appear promising, in the next future we will assist to further developments of naked DNA vaccination associated to the electroporation technology. This approach not only provides the basis for human studies but also a practical application to veterinary medicine.

Adjuvants in vaccines and for immunisation: current trends

Vaccines represent one of the most successful strategies in medical science. From the mechanistic perspective, vaccination works by manipulating the immune response through selecting, activating and expanding the memory of B and T cells. To determine the magnitude and quality of immune response, suitable vaccine adjuvants are required; therefore, much effort is going into finding new, effective and non-toxic adjuvant formulations focussed on the activation of key immune targets for inducing a long-term, potent and safe immune response. Significant research is being done in this area, to develop new classes of vaccines for use not only against infectious diseases, but also in the treatment of autoimmune disorders, allergies, chronic inflammatory diseases and cancer. Here the authors review and classify some of the main vaccine adjuvants on the basis of their immunomodulating properties on the immune system.

Ryanodine receptors are expressed and functionally active in mouse spermatogenic cells and their inhibition interferes with spermatogonial differentiation

Ryanodine receptors (RyRs) are intracellular calcium release channels that are highly expressed in striated muscle and neurons but are also detected in several non-excitable cells. We have studied the expression of the three RyR isoforms in male germ cells at different stages of maturation by western blot and RT-PCR. RyR1 was expressed in spermatogonia, pachytene spermatocytes and round spermatids whereas RyR2 was found only in 5- to 10-day-old testis but not in germ cells. RyR3 was not revealed at the protein level, although its mRNA was detected in mixed populations of germ cells. Caffeine, a known agonist of RyRs, was able to induce release of Ca2+ from intracellular stores in spermatogonia, pachytene spermatocytes and round spermatids, but not spermatozoa. Treatment with high doses of ryanodine, which are known to block RyR channel activity, reduced spermatogonial proliferation and induced meiosis in in vitro organ cultures of testis from 7-day-old mice. In conclusion, the results presented here indicate that RyRs are present in germ cells and that calcium mobilization through RyR channels could participate to the regulation of male germ maturation.

Electroporation in DNA Vaccination Protocols Against Cancer

Since conventional therapeutic approaches in cancer are highly invasive they hardly prolong patient survival for more than few months. Having the ability to stimulate both cellular and humoural immune responses, immunisation with naked plasmid DNA encoding tumour-associated antigens or tumour-specific antigens has recently reported a plethora of advantages, and the improvement of vaccine efficacy has emerged as a goal in the development of DNA vaccination as anti-tumour therapy. Nevertheless, because of their poor immunogenicity when administered as unformulated intramuscular injections, plasmid DNA vaccines need to be improved. Recent data suggest that the DNA vaccine efficacy may significantly be increased by electroporation. This review highlights the recent literature that supports electroporation as an effective strategy to improve DNA-based vaccination protocols, investigating the most relevant studies, recently developed for the applications of DNA vaccine electrotransfer against tumours in pre-clinical and clinical studies.

Strategies for Effective Naked-DNA Vaccination Against Infectious Diseases

To date, vaccination is an active area of investigation for its application to a great variety of human diseases including infections and cancer. In particular, naked-DNA vaccination has arisen as effective strategy in the preventive medicine field with promising future prospects. The ability of plasmid DNA to activate the humoural and the cellular arms of the immune system against the encoded antigen have resulted in intensive study of new strategies aimed at increasing the DNA vaccine immunogenicity. Nevertheless, plasmid-based vaccines emerged as a safer and advantageous alternative with respect to viral vector vaccines. Recent advances in both the immunological and biotechnological research field made it possible to enhance significantly the DNA vaccine potency. Most of these approaches are based on both the discovery of novel delivery systems and the implementation of plasmid constructs, achieved through genetic engineering. In this review, we will describe some of the most relevant patents issued in the last ten years, supporting the progress made in naked-DNA vaccination against infectious diseases.

Antigenic features of protein carriers commonly used in immunisation trials

An aluminium hydroxide adjuvant induced a more elevated and rapid immune responses against short peptides conjugated to the Keyhole Lympet Hemocyanin carrier than immuneasy adjuvant. Furthermore, since carrier proteins may compete with the fused or chemically linked polypeptides in eliciting antigen-specific immune response, we classified the immunogenicity of the most common carrier proteins used in molecular biology for antigen expression and mouse immunisation. The disulfide isomerase protein A gave a carrier with the lowest immunogenicity whilst disulfide isomerase protein C gave the highest immunogenicity and therefore should be avoided as a fusion partner. Using this protein as a model, we identified and located the immunodominant epitopes along its sequence. These results now enable the combination of carrier and immunisation conditions to be optimized.

Production, Novel Assay Development and Clinical Applications of Monoclonal Antibodies

Since the advent of hybridoma technology 35 years ago, research on monoclonal antibodies has developed enormously. Monoclonal antibodies of mouse origin were the first to be produced and continue to be the most popular affinity reagents for investigating the proteome of all organisms. For their adaptability to a variety of biological assays monoclonal antibodies are key tools for basic research as well as for diagnosis and therapy of human diseases. Recently, the expanding demand of high-quality antibodies with better specificities has resulted in a significant improvement in traditional hybridoma production methods. Owing to the ability of these affinity reagents to selectively target tumour cells, cancer has been a major focus of programmes for monoclonal antibody development. This review focuses on patents related to the advances made in the monoclonal antibody manufacture, showing how the traditional production techniques were turned into alternative, faster and more effective methods. Other patents are focussed on new technologies in which monoclonal antibodies are employed for the development of high-performance screening assays. A conclusive series of patents is related to monoclonal antibodies which find application to the diagnosis and the treatment of specific cancer diseases such as haematological malignancies and solid tumours.

Recent Advances in Epitope Design for Immunotherapy of Cancer

Eradication of cancer cells is imperative for a successful treatment of tumours. In addition to the existent chemotherapy or radiation therapy, other novel immunotherapeutic strategies to fight tumours are currently under investigation. One of these is cancer vaccination, an approach aimed at inducing effective immune responses in the host against defined tumour antigens. Among several classes of cancer vaccines, the subunit vaccines based on the single and multi epitope-approach are worthy of note as they offer an exquisite specificity in targeting only tumour cells. In this review we will focus on the significant advances made in the development and use of epitope-based cancer vaccines, reporting a selection of important and recent patents on tumour antigen discovery and epitope design for immunotherapy of cancer.