Plant-made therapeutics: an emerging platform in South Africa

The field of plant-made therapeutics in South Africa is well established in the form of exploitation of the country's considerable natural plant diversity, both in the use of native plants in traditional herbal medicines over many centuries, and in the more modern extraction of pharmacologically-active compounds from plants, including those known to traditional healers. In recent years, this has been added to by the use of plants for the stable or transient expression of pharmaceutically-important compounds, largely protein-based biologics and vaccines. South Africa has a well-developed plant biotechnology community, as well as a comprehensive legislative framework for the regulation of the exploitation of local botanic resources, and of genetically-modified organisms. The review explores the investigation of both conventional and recombinant plants for pharmaceutical use in South Africa, as well as describing the relevant legislative and regulatory frameworks. Potential opportunities for national projects, as well as factors limiting biopharming in South Africa are discussed.     

Post-genomic vaccine development

For over a century, vaccines were developed according to Pasteur's principles of isolating, inactivating and injecting the causative agent of an infectious disease. The availability of a complete microbial genome sequence in 1995 marked the beginning of a genomic era that has allowed scientists to change the paradigm and approach vaccine development starting from genomic information, a process named reverse vaccinology. This can be considered as one of the most powerful examples of how genomic information can be used to develop therapeutic interventions, which were difficult or impossible to tackle with conventional approaches. As the genomic era progressed, it became apparent that multi-strain genome analysis is fundamental to the design of universal vaccines. In the post-genomic era, the next challenge of the vaccine biologist will be the merging of the vaccinology with structural biology.     

Current development of COVID-19 diagnostics,vaccines and therapeutics

A novel coronavirus, designated as SARS-CoV-2, first emerged in Wuhan City, Hubei Province, China, in late December 2019. The rapidly increasing number of cases has caused worldwide panic. In this review, we describe some currently applied diagnostic approaches, as well as therapeutics and vaccines, to prevent, treat and control further outbreaks of SARS-CoV-2 infection.     

轮状病毒疫苗研究现状

轮状病毒自上世纪70年代初发现至今,仍是婴幼儿病毒性腹泻最主要的病原体。每年约60万婴幼儿因轮状病毒感染导致严重脱水死亡。轮状病毒疫苗从上世纪90年代初开始研制,至今已有三种疫苗用于预防轮状病毒感染。这三种疫苗均为减毒活疫苗:其中包括单一血清型Rotarix、罗特威和重组5价疫苗RotaTeq。它们已在全球多国使用,有些国家已将其纳入免疫规划。疫苗的使用使人群轮状病毒感染下降,特别是死亡率明显减少。但也出现了一些问题,因此除了减毒活疫苗,也有一些实验室研究其他形式的疫苗,例如重组疫苗、灭活疫苗等。本文主要介绍轮状病毒疫苗的研究现状,为我国轮状病毒疫苗的研究、使用和推广提供一定理论依据。     

Vaccination against filarial nematodes with irradiated larvae provides long-term protection against the third larval stage but not against subsequent life cycle stages

Sustainable control of human filariasis would benefit enormously from the development of an effective vaccine. The ability to vaccinate experimental animals, with reductions in worm burden of over 70%, suggests this aim is possible. However, in experimental vaccinations the challenge is usually administered 2 weeks after the immunisation phase and thus the protection obtained is likely to be biased by persisting inflammation. Using the murine model Litomosoides sigmodontis, we increased the time between immunisation with irradiated larvae and challenge with fully infective L3 to 5 months. Significant protection was achieved (54-58%) and the reduced worm burden was observed by 10 days p.i. The developmental stage targeted was the L3, since no nematodes died once they reached the pleural cavity of vaccinated mice, as has been previously shown in short-term protocols. However, larval developmental rate was faster in vaccinated than in primary-infected mice. Immunological assessments were made prior to challenge and then from 6 h to 34 days post-challenge. Samples were taken from the subcutaneous tissue where the larvae were inoculated, the lymph nodes through which they migrate and the pleural cavity in which they establish. Eosinophils were still present although scarce in the subcutaneous tissue of vaccinated mice before challenge. Cytokine and specific antibody production of vaccinated and challenged mice were L3-specific and Th2-biased and greatly exceeded the response of primary-infected mice. The heightened Th2 response may explain the faster development of the filarial worms in vaccinated mice. Thus, long-term vaccination protocols generated a strong memory response that led to significant but incomplete protection that was limited to the infective larval stage suggesting alternative vaccination strategies are needed.     

Vaccine protocols optimization: In silico experiences

Vaccines represent a special class of drugs, capable of stimulating immune system responses against pathogens and tumors. Vaccine development is a lengthy process that includes expensive laboratory experiments in order to assess safety and effectiveness. As the efficacy of a vaccine was demonstrated by biological/chemical investigations and pre-clinical studies, then a major problem is represented by the search for an optimal vaccination dosage. Optimality here assumes the meaning of assuring a high degree of efficacy and safety (lack of toxic or side effects). In lack of quantitative methods, this is usually achieved by a consensus technique, a public statement on a particular aspect of medical knowledge available at the time it was written, and that is generally agreed upon as the evidence-based, state-of-the-art (or state-of-science) knowledge by a representative group of experts in that area. In this article, we focus on the difficult problem of the search for an optimal vaccination dosage in the field of tumor immunology, that is a major issue in biomedical research. This, indeed, represents a first step toward a personalized medicine approach.     

Development of leading first-generation vaccines against SARS-CoV-2

SARS-CoV-2 has infected more than 167 million individuals globally. Highly effective and safe vaccines are required to accelerate the development of herd immunity to end the pandemic. This review focuses on vaccines that are being developed at unprecedented speed globally and are completing late phase clinical trials to meet this urgent need.     

Gene gun application in the generation of effector T cells for adoptive immunotherapy

We utilized the gene gun to transfect subcutaneous D5 melanoma and MT-901 mammary carcinoma tumors in situ with a granulocyte/macrophage-colony-stimulating factor (GM-CSF) plasmid complexed to gold particles. There was diminished tumor growth following bombardment with GM-CSF plasmid, which was apparent only during the period of administration. Transgenic GM-CSF was produced by the skin overlying the tumors and not by the tumors themselves. GM-CSF plasmid bombardment resulted in increased cell yields within tumor-draining lymph nodes (TDLN) with at least a 12-fold increase in the percentage of dendritic cells (8.9%) compared to controls (0.7%). Secondarily activated TDLN cells from animals transfected with GM-CSF demonstrated enhanced cytokine release (interferon γ, GM-CSF and interleukin-10) in response to tumor stimulator cells compared to controls, and had an increased capacity to mediate tumor regression in adoptive immunotherapy. There was a small, but detectable, non-specific immune adjuvant effect observed with gold particle bombardment alone, which was less than with GM-CSF plasmid. The adjuvant effect of GM-CSF plasmid required peri-tumoral transgene expression since gene bombardment away from the tumor was ineffective. Received: 27 April 1999 / Accepted: 27 August 1999     

Dendritic cell biology and cancer therapy

Dendritic cells (DCs) are natures best antigen-presenting cells. They possess attributes that allow them to effectively fulfill the requirements for priming/activating T cells and mediating tumor-specific immune responses. In this review, emphasis is placed on those aspects of DC biology that best illustrate their usefulness in immunotherapy of cancer. Culture, maturation, and polarization conditions for human DC are discussed, as are strategies for antigen-loading of DCs and for their delivery to patients with cancer. A concise recommendation for monitoring of DC-based vaccination trails is provided.This work was presented at the first Cancer Immunology and Immunotherapy Summer School, 8–13 September 2003, Ionian Village, Bartholomeio, Peloponnese, Greece.