Malaria vaccine

malaria-infected mosquitoes in a screened cup which will infect a volunteer in a malaria clinical trial

Malaria vaccines are an area of intensive research. Emergence of artemisinin and multi-drug resistant strains of especially P. falciparum are driving research. Current approaches are focusing on recombinant protein and attenuated whole organism vaccines. Various vaccines have reached the state of clinical trials; most demonstrated insufficient immunogenicity. There is no practical or effective vaccine that has been introduced into clinical practice.

Context

The global burden of P. falciparum malaria increased through the 1990s due to drug-resistant parasites and insecticide-resistant mosquitoes; this is illustrated by re-emergence of the disease in areas that had been previously malaria-free. The first decade of the 21st century has seen reduction. Though the reasons are not entirely clear, improving socioeconomic indices, deployment of artemisinin-combination drugs and insecticide-treated bednets are all likely to have contributed. Early evidence of resistance to artemisinins, the most important class of antimalarials, is now confirmed in the region of the Cambodia/Thailand border, Colombia, and Guinea. Chloroquine, the most effective anti-malarial ever developed, deployed since the 1930s, is now ineffective against P. falciparum and only marginally effective against P. vivax. It is agreed that eradication is not possible with current tools and that research and development of a cost-effective deployable vaccine among other measures, will be needed to facilitate eradication. There has been a great increase in funding for such research in the 21st century. In the genus plasmodium, there are five parasites that cause different types of malaria and each of the plasmodium exist in differently in some part of the world. CitationAccording to White et al., “Five species of the genus Plasmodium cause all malarial infections in human beings. Most cases are caused by either Plasmodium falciparum or Plasmodium vivax, but human infections can also be caused by Plasmodium ovale, Plasmodium malaria.

Vaccines are often the most cost-effective tools for public health. They have historically contributed to a reduction in the spread and burden of infectious diseases and have played the major part in previous elimination campaigns for smallpox and the ongoing polio and measles initiatives. Yet no effective vaccine for malaria has so far been developed. Despite this, researchers remain hopeful. Optimism is justified for several reasons, the first of these being that individuals who are exposed to the parasite in endemic countries develop acquired immunity against disease and death. Such immunity does not however prevent malarial infection; immune individuals often harbour asymptomatic parasites in their blood. Additionally, research shows that if immunoglobulin is taken from immune adults, purified and then given to individuals who have no protective immunity, some protection can be gained. In addition to this, clinical and animal studies have shown that experimental vaccination has some degree of success when using attenuated sporozites and using the RTS,S/AS01 malaria vaccine candidate.

Considerations

The task of developing a preventive vaccine for malaria is a complex process. There are a number of considerations to be made concerning what strategy a potential vaccine should adopt.

Parasite diversity

P. falciparum has demonstrated the capability, through the development of multiple drug-resistant parasites, for evolutionary change. The Plasmodium species has a very high rate of replication, much higher than that actually needed to ensure transmission in the parasite’s life cycle. This enables pharmaceutical treatments that are effective at reducing the reproduction rate, but not halting it, to exert a high selection pressure, thus favoring the development of resistance. The process of evolutionary change is one of the key considerations necessary when considering potential vaccine candidates. The development of resistance could cause a significant reduction in efficacy of any potential vaccine thus rendering useless a carefully developed and effective treatment.

Choosing to address the symptom or the source

The parasite induces two main response types from the human immune system. These are anti-parasitic immunity and anti-toxic immunity.

Taking this information into consideration an ideal vaccine candidate would attempt to generate a more substantial cell-mediated and antibody response on parasite presentation. This would have the benefit of increasing the rate of parasite clearance, thus reducing the experienced symptoms and providing a level of consistent future immunity against the parasite.

Potential targets

See also: PFSPZ vaccine
Potential vaccine targets in the malaria lifecycle. (Doolan and Hoffman)
Parasite stage Target
Sporozoite Hepatocyte invasion; direct anti-sporozite
Hepatozoite Direct anti-hepatozoite.
Asexual erythrocytic Anti-host erythrocyte, antibodies blocking invasion; anti receptor ligand, anti-soluble toxin
Gametocytes Anti-gametocyte. Anti-host erythrocyte, antibodies blocking fertilisation, antibodies blocking egress from the mosquito midgut.

By their very nature, protozoa are more complex organisms than bacteria and viruses, with more complicated structures and life cycles. This presents problems in vaccine development but also increases the number of potential targets for a vaccine. These have been summarised into the life cycle stage and the antibodies that could potentially elicit an immune response.

The epidemiology of malaria varies enormously across the globe, and has led to the belief that it may be necessary to adopt very different vaccine development strategies to target the different populations. A Type 1 vaccine is suggested for those exposed mostly to P. falciparum malaria in sub-Saharan Africa, with the primary objective to reduce the number of severe malaria cases and deaths in infants and children exposed to high transmission rates. The Type 2 vaccine could be thought of as a ‘travellers’ vaccine’, aiming to prevent all cases of clinical symptoms in individuals with no previous exposure. This is another major public health problem, with malaria presenting as one of the most substantial threats to travellers’ health. Problems with the current available pharmaceutical therapies include costs, availability, adverse effects and contraindications, inconvenience and compliance, many of which would be reduced or eliminated entirely if an effective (greater than 85–90%) vaccine was developed.

The life cycle of the malaria parasite is particularly complex, presenting initial developmental problems. Despite the huge number of vaccines available at the current time, there are none that target parasitic infections. The distinct developmental stages involved in the life cycle present numerous opportunities for targeting antigens, thus potentially eliciting an immune response. Theoretically, each developmental stage could have a vaccine developed specifically to target the parasite. Moreover, any vaccine produced would ideally have the ability to be of therapeutic value as well as preventing further transmission and is likely to consist of a combination of antigens from different phases of the parasite’s development. More than 30 of these antigens are currently being researched by teams all over the world in the hope of identifying a combination that can elicit immunity in the inoculated individual. Some of the approaches involve surface expression of the antigen, inhibitory effects of specific antibodies on the life cycle and the protective effects through immunization or passive transfer of antibodies between an immune and a non-immune host. The majority of research into malarial vaccines has focused on the Plasmodium falciparum strain due to the high mortality caused by the parasite and the ease of a carrying out in vitro/in vivo studies. The earliest vaccines attempted to use the parasitic circumsporozoite (CS) protein. This is the most dominant surface antigen of the initial pre-erythrocytic phase. However, problems were encountered due to low efficacy, reactogenicity and low immunogenicity.

Mix of antigenic components

Increasing the potential immunity generated against Plasmodia can be achieved by attempting to target multiple phases in the life cycle. This is additionally beneficial in reducing the possibility of resistant parasites developing. The use of multiple-parasite antigens can therefore have a synergistic or additive effect.

One of the most successful vaccine candidates currently in clinical trials consists of recombinant antigenic proteins to the circumsporozoite protein.[11] (This is discussed in more detail below.)

Delivery system

The selection of an appropriate system is fundamental in all vaccine development, but especially so in the case of malaria. A vaccine targeting several antigens may require delivery to different areas and by different means in order to elicit an effective response. Some adjuvants can direct the vaccine to the specifically targeted cell type—e.g. the use of Hepatitis B virus in the RTS,S vaccine to target infected hepatocytes—but in other cases, particularly when using combined antigenic vaccines, this approach is very complex. Some methods that have been attempted include the use of two vaccines, one directed at generating a blood response and the other a liver-stage response. These two vaccines could then be injected into two different sites, thus enabling the use of a more specific and potentially efficacious delivery system.

To increase, accelerate or modify the development of an immune response to a vaccine candidate it is often necessary to combine the antigenic substance to be delivered with an adjuvant or specialised delivery system. These terms are often used interchangeably in relation to vaccine development; however in most cases a distinction can be made. An adjuvant is typically thought of as a substance used in combination with the antigen to produce a more substantial and robust immune response than that elicited by the antigen alone. This is achieved through three mechanisms: by affecting the antigen delivery and presentation, by inducing the production of immunomodulatory cytokines, and by affecting the antigen presenting cells (APC). Adjuvants can consist of many different materials, from cell microparticles to other particulated delivery systems (e.g. liposomes).

Adjuvants are crucial in affecting the specificity and isotype of the necessary antibodies. They are thought to be able to potentiate the link between the innate and adaptive immune responses. Due to the diverse nature of substances that can potentially have this effect on the immune system, it is difficult to classify adjuvants into specific groups. In most circumstances they consist of easily identifiable components of micro-organisms that are recognised by the innate immune system cells. The role of delivery systems is primarily to direct the chosen adjuvant and antigen into target cells to attempt to increase the efficacy of the vaccine further, therefore acting synergistically with the adjuvant.

There is increasing concern that the use of very potent adjuvants could precipitate autoimmune responses, making it imperative that the vaccine is focused on the target cells only. Specific delivery systems can reduce this risk by limiting the potential toxicity and systemic distribution of newly developed adjuvants.

Studies into the efficacy of malaria vaccines developed to date have illustrated that the presence of an adjuvant is key in determining any protection gained against malaria. A large number of natural and synthetic adjuvants have been identified throughout the history of vaccine development. Options identified thus far for use combined with a malaria vaccine include mycobacterial cell walls, liposomes, monophosphoryl lipid A and squalene.

Agents under development

A completely effective vaccine is not yet available for malaria, although several vaccines are under development. SPf66 a synthetic peptide based vaccine developed by Manuel Elkin Patarroyo team in Colombia was tested extensively in endemic areas in the 1990s, but clinical trials showed it to be insufficiently effective, 28% efficacy in South America and minimal or not efficacy in Africa.[12] Other vaccine candidates, targeting the blood-stage of the parasite's life cycle, have also been insufficient on their own.[13] Several potential vaccines targeting the pre-erythrocytic stage are being developed, with RTS,S showing the most promising results so far.,[14][15]

RTS,S

Main article: RTS,S

RTS,S is the most recently developed recombinant vaccine. It consists of the P. falciparum circumsporozoite protein from the pre-erythrocytic stage. The CSP antigen causes the production of antibodies capable of preventing the invasion of hepatocytes and additionally elicits a cellular response enabling the destruction of infected hepatocytes. The CSP vaccine presented problems in trials due to its poor immunogenicity. The RTS,S attempted to avoid these by fusing the protein with a surface antigen from Hepatitis B, hence creating a more potent and immunogenic vaccine. When tested in trials an emulsion of oil in water and the added adjuvants of monophosphoryl A and QS21 (SBAS2), the vaccine gave protective immunity to 7 out of 8 volunteers when challenged with P. falciparum.[16]

RTS,S/AS01 (commercial name: Mosquirix),[17] was engineered using genes from the outer protein of Plasmodium falciparum malaria parasite and a portion of a hepatitis B virus plus a chemical adjuvant to boost the immune system response. Infection is prevented by inducing high antibody titers that block the parasite from infecting the liver.[18] It is being developed by the non-profit PATH Malaria Vaccine Initiative (MVI) and GlaxoSmithKline (GSK) with support from the Bill and Melinda Gates Foundation. In November 2012 a Phase III trial of RTS,S found that it provided modest protection against both clinical and severe malaria in young infants.[15]

As of October 2013, the GlaxoSmithKline (GSK), formulated Malaria vaccine, named RTS,S, is said to have reduced the amount of cases amongst young children by almost 50 percent and among infants by around 25 percent, following the conclusion of an 18-month clinical trial. In a bid to expand the novel vaccine program to accommodate a larger group and guarantee a sustained availability for the general public, the GlaxoSmithKline did submit an application for a marketing license with the European Medicines Agency (EMA) in July 2014.[19] GlaxoSmithKline embarked on this project as a non-profit initiative, with most of its funding coming from the Bill & Melinda Gates Foundation, a major contributor to malaria eradication in Africa. GlaxoSmithKline has been developing the Malaria vaccine for three decades, and now has the backing of the UN’s Swiss-based WHO, saying it will recommend the use of RTS,S for use starting in 2015, providing it gets approval.[20]

PfSPZ Vaccine

See PfSPZ Vaccine.

History

Irradiated mosquitoes

In 1967, it was reported that a level of immunity to the Plasmodium berghei parasite could be given to mice by exposing them to sporozoites that had been irradiated by x-rays.[21] Subsequent human studies in the 1970s showed that humans could be immunized against Plasmodium vivax and Plasmodium falciparum by exposing them to the bites of significant numbers of irradiated mosquitos.[22]

From 1989 to 1999, eleven volunteers recruited from the United States Public Health Service, United States Army, and United States Navy were immunized against Plasmodium falciparum by the bites of 1001 to 2927 mosquitos that had been irradiated with 15,000 rads of gamma rays from a Co-60 or Cs-137 source.[23] This level of radiation being sufficient to attenuate the malaria parasites so that while they could still enter hepatic cells, they could not develop into schizonts or infect red blood cells.[23] Over a span of 42 weeks, 24 of 26 tests on the volunteers showed that they were protected from malaria infection.[24]

References

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  16. Commercial name of RTS,S
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Bibliography

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