HIV vaccine development explained

An HIV vaccine is a potential vaccine that could be either a preventive vaccine or a therapeutic vaccine, which means it would either protect individuals from being infected with HIV or treat HIV-infected individuals.

It is thought that an HIV vaccine could either induce an immune response against HIV (active vaccination approach) or consist of preformed antibodies against HIV (passive vaccination approach).[1]

Two active vaccine regimens, studied in the RV 144 and Imbokodo trials, showed they can prevent HIV in some individuals.

However, the protection was in relatively few individuals, and was not long lasting. For these reasons, no HIV vaccines have been licensed for the market yet.

Difficulties in development

In 1984, after it was confirmed that HIV caused AIDS, the United States Health and Human Services Secretary Margaret Heckler declared that a vaccine would be available within two years.[2] However, priming the adaptive immune system to recognize the viral envelope proteins did not prevent HIV acquisition.

Many factors make the development of an HIV vaccine different from other classic vaccines (as of 1996):[3]

HIV structure

The epitopes of the viral envelope are more variable than those of many other viruses. Furthermore, the functionally important epitopes of the gp120 protein are masked by glycosylation, trimerisation and receptor-induced conformational changes making it difficult to block with neutralizing antibodies.

The ineffectiveness of previously developed vaccines primarily stems from two related factors:

The difficulties in stimulating a reliable antibody response has led to the attempts to develop a vaccine that stimulates a response by cytotoxic T-lymphocytes.[4] [5]

Another response to the challenge has been to create a single peptide that contains the least variable components of all the known HIV strains.[6]

It had been observed that a few, but not all, HIV-infected individuals naturally produce broadly neutralizing antibodies (BNAbs) which keep the virus suppressed, and these people remain asymptomatic for decades. Since the 2010s a core candidate is VRC01 and similar BNAbs, as they have been found in multiple unrelated people.[7] These antibodies mimic CD4 and compete for the conserved CD4 binding site. These antibodies all share a germline origin in the VH chain, where only a few human alleles of the IVIG1-2 gene are able to produce such an antibody.[8] Env is a protein on the HIV surface that enables to infect cells. Env extends from the surface of the HIV virus particle. The spike-shaped protein is "trimeric" — with 3 identical molecules, each with a cap-like region called glycoprotein 120 (gp120) and a stem called glycoprotein 41 (gp41) that anchors Env in the viral membrane. Only the functional portions of Env remain constant, but these are generally hidden from the immune system by the molecule's structure. X-ray analyses and low-resolution electron microscopy have revealed the overall architecture and some critical features of Env. But higher resolution imaging of the overall protein structure has been elusive because of its complex, delicate structure. Three new papers use stabilized forms of Env to gain a clearer picture of the intact trimer. An NCI research team led by Dr. Sriram Subramaniam used cryo-electron microscopy to examine the Env structure. The study appeared on October 23, 2013, in Nature Structural and Molecular Biology.[9]

Animal model

The typical animal model for vaccine research is the monkey, often the macaque. Monkeys can be infected with SIV or the chimeric SHIV for research purposes. However, the well-proven route of trying to induce neutralizing antibodies by vaccination has stalled because of the great difficulty in stimulating antibodies that neutralise heterologous primary HIV isolates.[10] Some vaccines based on the virus envelope have protected chimpanzees or macaques from homologous virus challenge,[11] but in clinical trials, humans who were immunised with similar constructs became infected after later exposure to HIV-1.[12]

There are some differences between SIV and HIV that may introduce challenges in the use of an animal model. The animal model can be extremely useful but at times controversial.[13]

There is a new animal model strongly resembling that of HIV in humans. Generalized immune activation as a direct result of activated CD4+ T cell killing - performed in mice allows new ways of testing HIV behaviour.[14] [15]

NIAID-funded SIV research has shown that challenging monkeys with a cytomegalovirus (CMV)-based SIV vaccine results in containment of virus. Typically, virus replication and dissemination occurs within days after infection, whereas vaccine-induced T cell activation and recruitment to sites of viral replication take weeks. Researchers hypothesized that vaccines designed to maintain activated effector memory T cells might impair viral replication at its earliest stage.

Specific vaccines may also need specialized animal models. For example, vaccines designed to produce VRC01-type antibodies require human-like VH alleles to be present. For organisms like mice, the human allele must be inserted into their genome to produce a useful mimic.[16] Murines are also experimental animals in AIDS and also murine AIDS and human AIDS are similar. Immunological analysis and genetic studies reveal resistant gene(s) in the H-2 complex of mice, an indication that genetic differences in mice could modify features of HIV disease. The defective murine leukemia virus is the major etiologic agent of MAIDS, which seems to be able to induce disease in the absence of virus replication. Target cell proliferation and oligoclonal expansion are induced by the virus, which suggests repressed immunity seen in mice thus referred to as paraneoplastic syndrome. This is further supported by the good response(s) of MAIDS mice to antineoplastic agents. This animal model is useful in demonstrating the emergence of novel hypotheses about AIDS, including the roles of defective HIV and HIV replication in the progression of the disease, and also the importance of identifying the HIV targeted cells in vivo.[17]

Clinical trials

Several vaccine candidates are in varying phases of clinical trials.

Phase I

Most initial approaches have focused on the HIV envelope protein. At least thirteen different gp120 and gp160 envelope candidates have been evaluated, in the US predominantly through the AIDS Vaccine Evaluation Group. Most research focused on gp120 rather than gp41/gp160, as the latter is generally more difficult to produce and did not initially offer any clear advantage over gp120 forms. Overall, they have been safe and immunogenic in diverse populations, have induced neutralizing antibody in nearly 100% recipients, but rarely induced CD8+ cytotoxic T lymphocytes (CTL). Mammalian derived envelope preparations have been better inducers of neutralizing antibody than candidates produced in yeast and bacteria. Although the vaccination process involved many repeated "booster" injections, it was challenging to induce and maintain the high anti-gp120 antibody titers necessary to have any hope of neutralizing an HIV exposure.

The availability of several recombinant canarypox vectors has provided interesting results that may prove to be generalizable to other viral vectors. Increasing the complexity of the canarypox vectors by including more genes/epitopes has increased the percent of volunteers that have detectable CTL to a greater extent than did increase the dose of the viral vector. CTLs from volunteers were able to kill peripheral blood mononuclear cells infected with primary isolates of HIV, suggesting that induced CTLs could have biological significance. Besides, cells from at least some volunteers were able to kill cells infected with HIV from other clades, though the pattern of recognition was not uniform among volunteers. The canarypox vector is the first candidate HIV vaccine that has induced cross-clade functional CTL responses. The first phase I trial of the candidate vaccine in Africa was launched early in 1999 with Ugandan volunteers. The study determined the extent to which Ugandan volunteers have CTL that are active against the subtypes of HIV prevalent in Uganda, A and D. In 2015, a Phase I trial called HVTN 100 in South Africa tested the combination of a canarypox vector ALVAC and a gp120 protein adapted for the subtype C HIV common in sub-Saharan Africa, with the MF59 adjuvant. Those who received the vaccine regimen produced strong immune responses early on and the regimen was safe.[18]

Other strategies that have progressed to phase I trials in uninfected persons include peptides, lipopeptides, DNA, an attenuated Salmonella vector, p24, etc. Specifically, candidate vaccines that induce one or more of the following are being sought:

In 2011, researchers in National Biotech Centre in Madrid unveiled data from the Phase I clinical trial of their new vaccine, MVA-B. The vaccine induced an immunological response in 92% of the healthy subjects.[20]

In 2016, results were published of the first Phase I human clinical trial of a killed whole-HIV-1 vaccine, SAV001. HIV used in the vaccine was chemically and physically deadened through radiation. The trial, conducted in Canada in 2012, demonstrated a good safety profile and elicited antibodies to HIV-1.[21] According to Dr. Chil-Yong Kang of Western University's Schulich School of Medicine & Dentistry in Canada, the developer of this vaccine, antibodies against gp120 and p24 increased to 8-fold and 64-fold, respectively after vaccination.[22]

The VRC01 line of research produced an "eOD-GT8" antigen which specifically exposes the CD4 binding site for immunization, refined over time to expose less of the other sites.[23] As it turns out that most (but not all)[8] humans do have the required alleles, the problem shifted to the method of delivery. In 2021, after promising results in tests with mice and primates, scientists announced that they plan to conduct a Phase 1 trial of an mRNA vaccine against HIV if a further developed (via their 'env–gag VLP mRNA platform' which contains eOD-GT8) vaccine is confirmed safe and effective.[24] [25] On January 17, 2022 IAVI and Moderna launched a phase I trial of a HIV vaccine with mRNA technology.[26] On March 14, 2022 the National Institutes of Health reported that it had launched a "clinical trial of three mRNA HIV vaccines". The phase one trial is expected to conclude July 2023.

Phase II

Preventive HIV vaccines

Therapeutic HIV vaccines

Biosantech developed a therapeutic vaccine called Tat Oyi, which targets the tat protein of HIV. It was tested in France in a double-blind Phase I/II trial with 48 HIV-positive patients who had reached viral suppression on Highly Active Antiretroviral Therapy and then stopped antiretrovirals after getting the intradermal Tat Oyi vaccine.[38]

Phase III

Preventive HIV vaccines

There have been no passive preventive HIV vaccines to reach Phase III yet, but some active preventive HIV vaccine candidates have entered Phase III.

Therapeutic HIV vaccines

No therapeutic HIV vaccine candidates have reached phase 3 testing yet.

Economics

A July 2012 report of the HIV Vaccines & Microbicides Resource Tracking Working Group estimates that $845 million was invested in HIV vaccine research in 2011.[44]

Economic issues with developing an HIV vaccine include the need for advance purchase commitment (or advance market commitments) because after an AIDS vaccine has been developed, governments and NGOs may be able to bid the price down to marginal cost.[45]

Classification of possible vaccines

Theoretically, any possible HIV vaccine must inhibit or stop the HIV virion replication cycle.[46] The targets of a vaccine could be the following stages of the HIV virion cycle:

Therefore, the following list comprises the current possible approaches for an HIV vaccine:

Filtering virions from blood (Stage I)

Approaches to catching the virion (Stage I-III, VI, VII)

Approaches to destroying or damaging the virion or its parts (Stage I-VII)

Here, "damage" means inhibiting or stopping the ability of virion to process any of the Phase II-VII. Here are the different classification of methods:

Blocking replication (Stage V)

Biological, chemical or physical approaches to inhibit the process of phases

Inhibiting the functionality of infected cells (Stage VI-VII)

Inhibiting the life functions of infected cells:

Future work

There have been reports that HIV patients coinfected with GB virus C (GBV-C), also called hepatitis G virus, can survive longer than those without GBV-C, but the patients may be different in other ways. GBV-C is potentially useful in the future development of an HIV vaccine.[51]

Live attenuated vaccines are highly successful against polio, rotavirus and measles, but have not been tested against HIV in humans. Reversion to live virus has been a theoretical safety concern that has to date prevented clinical development of a live attenuated HIV-1 vaccine. Scientists are researching novel strategies to develop a non-virulent live attenuated HIV-1 vaccine. For example, a genetically modified form of HIV has been created in which the virus's codons (a sequence of three nucleotides that form genetic code) are manipulated to rely on an unnatural amino acid for proper protein translation, which allows it to replicate. Because this amino acid is foreign to the human body, the virus cannot reproduce.[52] Recent evidence suggests using universal CAR NK cells against HIV[53] [54]

See also

External links

Notes and References

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