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Herpes simplex research

Herpes simplex research includes all medical research that attempts to prevent, treat, or cure herpes, as well as fundamental research about the nature of herpes. Examples of particular herpes research include drug development, vaccines and genome editing. HSV-1 and HSV-2 are commonly thought of as oral and genital herpes respectively, but other members in the herpes family include chickenpox (varicella/zoster), cytomegalovirus, and Epstein-Barr virus. There are many more virus members that infect animals other than humans, some of which cause disease in companion animals (cats, dogs, horses)[1][2][3] or have economic impacts in the agriculture industry (e.g., pigs, cows, sheep, chicken, oysters).[4][5][6]

Vaccine research

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Various vaccine candidates have been developed, the first ones in the 1920s, but none has been successful to date.[7][8]

Due to the genetic similarity of both herpes simplex virus types (HSV-1 and HSV-2), the development of a prophylactic-therapeutic vaccine that proves effective against one type of the virus would likely prove effective for the other virus type, or at least provide most of the necessary fundamentals.[citation needed] As of 2020, several vaccine candidates are in different stages of clinical trials, see list below.

An ideal herpes vaccine should induce immune responses adequate to prevent infection. Short of this ideal, a candidate vaccine might be considered successful if it (a) mitigates primary clinical episodes, (b) prevents colonization of the ganglia, (c) helps reduce the frequency or severity of recurrences, and (d) reduces viral shedding in actively infected or asymptomatic individuals.[9] The fact that a live-attenuated vaccine induced better protection from HSV infection and symptoms is not new, because live-attenuated vaccines account for most of the successful vaccines in use today. However, governmental and corporate bodies seem to support the more recent and safer but possibly less effective approaches such as glycoprotein- and DNA-based vaccines.

Advocacy

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Due to the current stigma of the Herpes Simplex Virus, the topic of a cure has always been considered a "taboo" whilst some also consider the symptoms to be mild that a cure or a vaccine is not needed. However, in April 2020, a Subreddit group, r/HerpesCureResearch was formed to advocate for cure research and better treatment of HSV. The "Herpes Cure Research" has grown to 20k members and has raised funds for Fred Hutch's genome editing treatment and UPenn's mRNA vaccine research as well as forming a Herpes Cure Advocacy group in which the group is raising awareness on the health complications associated with HSV. [10]

Vaccine design

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Vaccine-elicited protection against HSV is challenging to achieve due to the ability of herpesviruses to evade many aspects of the mammalian immune response. As a general principle, the effectiveness of a HSV vaccine design is often inversely proportional to its safety. Subunit vaccines, which consist of individual or small groups of viral antigens, remove all risk of complications resulting from the production of vaccine-associated infectious viral particles but are limited in the degree and scope of immunity that can be produced in vaccinated individuals. Inactivated vaccines, which consist of intact viral particles, dramatically increase the repertoire of viral antigens that engender the immune response but like subunit vaccines are generally constrained to producing humoral immunity. Like inactivated vaccines, replication-defective vaccines expose the immune system to a diverse swath of HSV antigens but can produce both cellular and humoral immunity because they retain the ability to enter cells by HSV-induced membrane fusion. However, replication-defective HSV vaccines are challenging to produce at scale and offer limited immunization due to the lack of vaccine amplification. Live-attenuated vaccines are highly efficacious, potentially eliciting both cell-mediated and humoral immunity against structural and non-structural viral proteins, but their ability to replicate can result in vaccine-related illness particularly in immunocompromised individuals. Whereas subunit vaccines have proven effective against some viruses, immunity produced by subunit HSV vaccines have failed to protect humans from acquiring genital herpes in several clinical trials. In contrast, the success of the live-attenuated chickenpox vaccine demonstrates that an appropriately live-attenuated α-herpesvirus may be used to safely control human disease. The challenge of achieving vaccines that are both safe and effective has led to two opposing approaches in HSV vaccine development: increasing the efficacy of subunit vaccines (primarily by improving adjuvant formulations), and increasing the safety of live-attenuated vaccines (including the development of "non-invasive" vaccines).

Vaccine candidates

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The chart below is an attempt to list all known proposed HSV and varicella zoster vaccines and their characteristics. Please update with any missing information on vaccines only.

Vaccine Company & Lead Researcher Vaccine Type Trial Status and Results
Anteris HSV-2 therapeutic vaccine / COR-1 Anteris Technologies (formerly Admedus)

Ian Frazer

DNA vaccine Phase IIa , likely discontinued[11]
Monoclonal Antibody Therapy / HDIT101 Heidelberg ImmunoTheraputics GmbH

Claudia Kunz, PhD

monoclonal antibodies Phase II[12]
Study of HDIT101 versus Valaciclovir.
Nov 2019 – Sep 2021
UB-621 United BioPharma

(Taiwanese Company with a branch in the US.) N/A

anti-HSV antibody Phase II[13]
Receives US FDA Approval for UB-621 Phase 2 Trial in Recurrent Genital Herpes Patients (2019-06/11).
Jun 2020 – Jun 2021
GSK3943104A[14] GSK Phase I-II[15]
BNT163 BioNTech mRNA Phase I[16]
Started Phase 1 Clinical Trial
dl5-29 / ACAM-529 / HSV-529 Sanofi Pasteur

David Knipe[17]

HSV-2 replication-defective vaccine with UL5 and UL29 deleted Phase I–II[18][19]
HSV529 vaccine was safe and elicited neutralizing antibody and modest CD4+ T-cell responses in HSV-seronegative vaccinees.[20]
Dec 2019 – May 2023
VC2 Louisiana State University

Gus Kousoulas

Live-attenuated HSV vaccine with small deletions in UL20 and UL53 Preclinical
The VC2 vaccine prevents HSV infection of neuronal axons and establishment of latency in animal models such as mice, guinea pig and rhesus monkeys.[21][22][23]
R2 Thyreos Inc[24]

Gregory Smith, Gary Pickard, Ekaterina Heldwein

Live-attenuated HSV vaccine mutated in R2 coding region of UL37 Preclinical
A single-dose vaccine effective in mice and rats against multiple neuroinvasive herpes viruses including HSV.[25]
HSV-2 ΔgD-2 Albert Einstein College of Medicine / X-Vax Technology (Pre-clinical)[26]

William Jacobs Jr & Betsy Harold

Live-attenuated HSV-2 vaccine with US6 (gD) deleted Preclinical
Combats HSV-1 & HSV-2 in mice.[27] Mice who were HSV-1 positive showed strong protection from HSV-2.[28]
HSV-2 mRNA Trivalent Vaccine[29] Perelman School of Medicine at the University of Pennsylvania

Kevin P. Egan, Harvey Friedman, Sita Awasthi

HSV-2 mRNA trivalent vaccine (containing gC2, gD2, gE2) Preclinical
the mRNA vaccine prevented death and genital disease in 54/54 (100%) mice infected with HSV-1 and 20/20 (100%) with HSV-2, and prevented infection of the dorsal root ganglia in 29/30 (97%) mice infected with HSV-1 and 10/10 (100%) with HSV-2[30] (update 27 July 2020)
m-RNA-1608[31] Moderna mRNA Preclinical
G103[32] Sanofi Pasteur, Immune Design HSV-2 subunit trivalent vaccine (containing gD, pUL19, pUL25) Phase I–II[18][19]
Prophylactic immunization completely protected against lethal intravaginal HSV-2 infection in mice.[33]
GV2207[34] GenVec ? Preclinical[34]
NE-HSV2[35] BlueWillow[36] ? Preclinical
TBA[37] Profectus BioSciences DNA vaccine Discovery
Immunogenicity in small animals.
HSV-2 ICP0‾ HSV-2 0ΔNLS / Theravax[38] Rational Vaccines RVx

William Halford[39]

Live-attenuated vaccine Terminated
Company under criminal investigation by the FDA[40] and being sued by trial participants.[41] Effective for most patients[42] in a small clinical trial (17/20) but with severe side-effects for some (3/20).[43]
Vitaherpavac & Herpovax Vitafarma,[44] Russia Inactivated HSV-1 and HSV-2 vaccine[45] Phase IV[46]
Appears to be for treatment of existing patients.

Live-attenuated non-invasive vaccines

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A recent development in live-attenuated HSV vaccine design is the production of replicative vaccines that are ablated for nervous system infection. These vaccines infect the respiratory mucosa where their replication and localized spread provoke a robust immune response. The safety of these vaccines is based on their inability to invade the nervous system and establish life-long latent infections, as opposed to a general attenuation. Unlike other live-attenuated designs, these vaccines are cleared from the body once the immune response from vaccination has matured. In principle, by avoiding attenuation of HSV replication in the mucosa while removing the capacity to infect the nervous system, non-invasive vaccines have the potential to break the safety-efficacy dilemma by producing the strongest possible immune response while maintaining a high degree of safety.

The VC2 non-invasive vaccine was developed by Dr. Gus Kousoulas at Louisiana State University. VC2 encodes two attenuating mutations that together reduce HSV entry into neurons. The establishment of latency is prevented in animal models such as mice, guinea pig, and rhesus monkeys.[21][22][23]

The R2 non-invasive vaccine was developed by Drs. Gregory Smith (Northwestern University Feinberg School of Medicine), Patricia Sollars & Gary Pickard (University of Nebraska-Lincoln), and Ekaterina Heldwein (Tufts University School of Medicine). R2 vaccines retain native replication in epithelial cells but are incapable of retrograde axonal transport and invasion of the nervous system.[25] A single dose of the R2 vaccine passively introduced on mucosal tissues protects the nervous system from future infections and affords protection against lethal encephalitic infections in mice and rats. This vaccine strategy is noted for its effectiveness against both veterinary and clinical neuroinvasive herpesviruses.[47] Thyreos Inc was founded to develop a herpesvirus vaccine platform based on the R2 design with targeted applications in human health, companion animal health, and livestock productivity.

Live-attenuated HSV-2 vaccine

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Dr. William Halford at the Southern Illinois University (SIU) School of Medicine tested a live-attenuated HSV-2 ICP0∆NLS vaccine in 2016, before his death in June, 2017.[48][49][50] Vaccine attenuation is achieved by a mutation in ICP0 (ICP0∆NLS) that increases the vaccine strain's sensitivity to interferon responses and limits its replication. Already proven as safe and effective in rodents and eliciting 10 to 100 times greater protection against genital herpes than a glycoprotein D subunit vaccine, Halford's vaccine was tested outside of the United States, in St. Kitts in 20 human volunteers. All 20 of the participants self-reported an improvement in symptoms, but only 17 received and completed all three dosages.[51] Blot tests showed a clear antibody response, which cannot be instigated by a placebo effect. However, the human trial was conducted without approval from the FDA or from the SIU Institutional Review Board.[1]

Replication-defective HSV-2 vaccine

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Principle of HSV529

David M. Knipe, a professor at Harvard Medical School has developed dl5-29. The dl5-29 vaccine is also known under the name ACAM-529[52] or HSV-529, a replication-defective vaccine that has proved successful in preventing both HSV-2 and HSV-1 infections and in combating the virus in already-infected hosts, in animal models.[53] The HSV-529 is a leading vaccine candidate which has been investigated in numerous research publications, and is endorsed by many researchers in the field (i.a. Lynda A. Morrison and Jeffrey Cohen).[54] The vaccine induces strong HSV-2-specific antibody and T-cell responses, protects against challenge with a wild-type HSV-2 virus, reduces the severity of recurrent disease, and provides cross-protection against HSV-1.[55] The ongoing trials would prove if a durable immune response in humans is to be successfully achieved or if the vaccine is too over attenuated to do the same. The vaccine was being researched and developed by Sanofi Pasteur.[56]

On 28 April 2022, Sanofi announced it had discontinued a trial evaluating four HSV-2 vaccines.[57] The pipeline section of the Sanofi website no longer lists any HSV vaccine candidate in active development.[58]

DNA-based vaccine

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Professor Ian Frazer developed an experimental vaccine with his team at Coridon, a biotechnology company he founded in 2000.[59] The company, now known under the name Admedus Vaccines, is researching DNA technology for vaccines with prophylactic and therapeutic potential. What's different about this vaccine is the way that response is being created. Instead of introducing a weakened version of the herpes virus or protein subunit, this vaccine uses a small section of DNA to produce T-cells and stimulate the immune response.[60] The new vaccine candidate is designed to prevent new infections, and to treat those who already have the infection. In February 2014, it was announced that Frazer's vaccine against genital herpes passed human safety trials in a trial of 20 Australians.[61] In October 2014, Admedus announced success in creating a positive T-cell response in 95% of participants.[62] Further research is required to determine if the vaccine can prevent transmission. In July 2014, Admedus increased its stake in Frazer's vaccines by 16.2%. In addition, $18.4 million was posted as funds raised towards Phase II vaccine testing and research.[63]

The HSV-2 Phase II trial began in April 2015.[64] Interim results were published on March 4, 2016, and based on the results of a scheduled, blinded, pooled analysis of data from the first 20 patients to receive at least three vaccinations in the randomised, placebo controlled Phase II study with the following results:

  • No safety issues have been noted in this cohort of patients. The data remains blinded to protect the integrity of the trial.
  • Study participants had a marked decrease in viral lesions (outbreaks) with a drop of over 90% in the monthly rate versus baseline.
  • The average number of days HSV-2 was detected in patients was reduced versus baseline.

On 19 October 2016, Admedus released interim results from the ongoing HSV-2 Phase IIa study. The unblinded data demonstrated a 58% reduction in viral shedding compared to baseline and a reduction in outbreaks of 52% post vaccination and 81% overall reduction post-booster.[65]

On 1 June 2020, Admedus announced it had changed its name to Anteris Technologies Ltd., and would become a "dedicated structural heart company".[66] No vaccines are listed in the company's most recent research report[67] and the vaccine is likely discontinued.

Other vaccine exploration

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Vitaherpavac - In patients with monotonously recurrent genital herpes infection and history of failure of standard vaccination, anti-relapse efficacy of Vitaherpavac vaccine was demonstrated after allergometry-based tailored choice of vaccine administration regimen. The used approach was associated with lower antigenic load and sensitization, more than three-fold increase in relapse-free period in 85% of treated patients and improvement of Th1-dependent immunity. The Russian vaccine Vitagerpavak — the only polyvalent vaccine in the world for treatment of the chronic gerpesvirusny infection (CGI) І and ІІ types. It is developed in scientific research institute of virology of D.I. Ivanovsky of the Russian Academy of Medical Science. More than 15 years are applied in the Russian Federation.[68]

A study from the Albert Einstein College of Medicine, where glycoprotein D (gD-2) was deleted from the herpes cell, showed positive results when tested in mice.[69] Researchers deleted gD-2 from the herpes virus, which is responsible for herpes microbes entering in and out of cells. The vaccine is still in early stages of development and more research needs to be conducted before receiving FDA approval for clinical trials.[70]

Research conducted by the NanoBio Corporation indicates that an enhanced protection from HSV-2 is a result of mucosal immunity which can be elicited by their intranasal nanoemulsion vaccine. NanoBio published results showing efficiency in studies conducted in both the prophylactic and the therapeutic guinea pig model. This included preventing infection and viral latency in 92% of animals vaccinated and a reduction in recurrent legions by 64% and viral shedding by 53%. NanoBio hopes to raise funds in 2016 to enter into Phase I clinical testing.[71]

Profectus BioSciences intends to use its PBS Vax therapeutic vaccine technology to engineer a vaccine for HSV-2.[72] The vaccine is in early development and much is unknown about its viability.

Biomedical Research Models, a Worcester-based biopharmaceutical company has been awarded a fund for the development of a novel vaccine platform to combat mucosally transmitted pathogens such as HSV-2.[73]

The company Tomegavax (recently acquired by Vir Biotechnology) is researching to utilize cytomegalovirus vectors in the development of a therapeutic vaccine against herpes simplex virus 2 (HSV-2), the causative agent of genital herpes. It has been awarded a grant by the NIH for this purpose.[74]

Redbiotec, a privately held Swiss biopharmaceutical company, based in Zurich as a spin-off of the ETH Zurich, is focusing on the development of a therapeutic vaccine against HSV-2. Redbiotec's preclinical vaccine shows over 90% of lesion score (vs. approx. 50% for GEN-003 of Genocea) in early findings.[75]

Sanofi Pasteur and the clinical-stage immunotherapy company Immune Design have entered a broad collaboration, which will explore the potential of various combinations of agents against HSV-2, including an adjuvanted trivalent vaccine candidate G103, consisting of recombinantly-expressed viral proteins.[76]

Discontinued vaccines

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Below is a list of vaccines that are no longer being pursued.

Vaccine Organization Vaccine Type Reason Final Results
Herpevac, Simplirix GlaxoSmithKline Prophylactic, Sub Unit gD2t with alum/MPL adjuvant AS04[77][78] Failed in Phase III clinical trial[79] No statistically significant results found[80] No effect regarding HSV-2 was achieved, partial protection against HSV-1 confirmed[81]
Unnamed[82] PaxVax Recombinant Vector Vaccine[83] Discontinued in pre-clinical stage, no longer appears in company's pipeline[84] N/A
ImmunoVEX HSV2 vaccine Amgen, BioVex Live, Attenuated, defective in immune evasion[85] Discontinued in Phase I stage, no longer appears in company's pipeline[86] N/A
Gen-003 Genocea Sub Unit gD2/ICP4 with Matrix M2 adjuvant Discontinued after Phase II stage 58% Reduction in Viral Shedding, 69% Reduction in Outbreaks. Spending on vaccine has ceased.[87]
AuRx Herpes Vaccine AuRx[88] Recombinant Vector Vaccine[89] Inactive N/A
DISC vaccine[90] Cantab Pharmaceuticals Live, Attenuated HSV vaccine with gH deleted Discontinued in Phase I stage No clinical or virological benefit was shown
Unnamed[91] Mymetics ? Discontinued in pre-clinical stage, no longer appears in company's pipeline N/A
HerpV Agenus Peptide vaccine/QS-21 adjuvant Discontinued after Phase II stage[92] N/A
VCL-HB01[93] Vical DNA vaccine: gD2+UL46/Vaxfectin adjuvant Discontinued after Phase II stage Trial did not show positive outcome.[94]

Detailed Information on discontinued vaccines

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One vaccine that was under trial was Herpevac, a vaccine against HSV-2. The National Institutes of Health (NIH) in the United States conducted phase III trials of Herpevac.[95] In 2010, it was reported that, after 8 years of study in more than 8,000 women in the United States and Canada, there was no sign of positive results against the sexually transmitted disease caused by HSV-2[80] (and this despite earlier favorable interim reports[95]).

PaxVax, a specialty vaccine company, partnered with Spector Lab at the UC San Diego Department of Cellular and Molecular Medicine regarding the development of a genital herpes viral vector vaccine. The vaccine was in the pre-clinical stage.[96] The vaccine is no longer listed on their website as a present endeavour and has likely been discontinued.[84]

A private company called BioVex began Phase I clinical trials for ImmunoVEX, another proposed vaccine, in March 2010.[97] The company had commenced clinical testing in the UK with its vaccine candidate for the prevention and potentially the treatment of genital herpes. The biopharmaceutical company Amgen bought BioVex[98] and their proposed ImmunoVEX vaccine appears to have been discontinued, furthermore it has been removed from the company's research pipeline.[86]

A live, attenuated vaccine (which was proven very effective in clinical trials in Mexico) by the company AuRx has failed to proceed to a Phase III trial in the year 2006, due to financial reasons. The AuRx therapy was shown to be safe and decrease the occurrence of lesions by 86% after one year.[99]

Mymetics is developing a pre-clinical preventative vaccine for HSV 1 and 2 using its virosome technology.[91] There has not been any recent announcement by the company regarding their vaccine, which seems to have been taken off from the company's research product pipeline.

HerpV, a genital herpes vaccine candidate manufactured by the company Agenus, announced Phase II clinical trial results in June 2014. Results showed up to a 75% reduction in viral load and a weak reduction in viral shedding by 14%.[100] These results were achieved after a series of vaccinations and a booster dose after six months, signalling the vaccine may take time to become effective. Further testing results are to show if the vaccine is a viable candidate against genital herpes.[101] There has not been any recent announcement by Agenus regarding the vaccine HerpV, which seems to have been taken off from the company's research product pipeline.[102]

Genocea Biosciences has developed GEN-003, a first-in-class protein subunit T cell-enabled therapeutic vaccine, or immunotherapy, designed to reduce the duration and severity of clinical symptoms associated with moderate-to-severe HSV-2, and to control transmission of the infection. GEN-003 includes the antigens ICP4 and gD2, as well as the proprietary adjuvant Matrix-M. GEN-003 had concluded Phase IIa clinical trials. In December 2015, Genocea announced interim data showing a 58% decrease in viral shedding and a 69% decrease in genital lesions. They also showed one of the doses stopped outbreaks for at least 6 months.[103] GEN-003 was undergoing a Phase IIb clinical trial in the United States. Genocea has announced it would shift their strategic efforts to cancer vaccines while at the same time heavily cutting down on research and development of GEN-003 vaccine against genital herpes.[104] Being unable to secure funding or partnering with another company, Genocea's further vaccine development remains to be determined.

Vical had been awarded grant funding from the National Institute of Allergy and Infectious Diseases division of the NIH to develop a plasmid DNA-based vaccine to inhibit recurring lesions in patients latently infected with herpes simplex virus type 2 (HSV-2). The plasmid DNA encoding the HSV-2 antigens was formulated with Vaxfectin, Vical's proprietary cationic lipid adjuvant. Vical is concluding Phase I clinical trials, while reporting data showing the vaccine candidate failed to meet the primary endpoint.[105] The San Diego-based company was forced to concede that their herpes strategy had misfired, with their vaccine failing to perform as well as a placebo.[106] However, that seemed to may have changed, since 20 June 2016, when Vical released phase I/II results at ASM.[107] Their vaccine (named VCL-HB01) was involved in a Phase II clinical trial. The recent trial, similarly to a past trial again missed the primary endpoint and therefore the company is discontinuing the vaccine and moving to other pipeline products.[94]

Genome editing

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Another area of research for HSV treatment or a potential cure is the use of genome editing. It is thought that by cleaving the DNA of HSV that infects neurons, thereby causing destruction or mutational inactivation of the HSV DNA, the virus can be greatly treated or even cured.[108]

Notable research

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The Jerome Lab run by Keith R. Jerome at the Fred Hutchinson Cancer Research Center has looked at using zinc finger nuclease as well as endonuclease to prevent HSV from replicating. Most recently Jerome and his lab were able to demonstrate cleavage of latent HSV in a living organism, which is vital to disabling the virus.[109] On August 18, 2020, the team led by Jerome and Martine Aubert published a paper in Nature Communications showing that, through a series of incremental improvements on their original method, they had destroyed up to 95% of herpes virus lurking in certain nerve clusters of mice, with 3 years of work expected before clinical trials are considered.[110]

Editas Medicine, that previously collaborated with the Cullen Lab,[111] are researching CRISPR-Cas9 for its use in Herpes Simplex Keratitis.

Researchers at Temple University have been researching how to disrupt HSV from replicating that could eventually lead to a cure.[112][113] Some members of research team at Temple University have also joined forces to create Excision BioTherapeutics. The company intends to begin clinical trials in 2022.[114]

Researchers at the University Medical Center Utrecht, using the CRISPR-Cas9 system, have showed promising results in clearing HSV-1 infection by simultaneously targeting multiple essential vital genes in vitro.[115] The researchers are now looking at targeting latent HSV-1 genomes and are investigating in vivo model systems to assess the potential therapeutic application.[116]

In 2021, scientists in China described a CRISPR-Cas9 genome editing approach which could be used to treat HSV-1 in corneal stroma: injection of engineered lentiviruses into the affected anatomical regions for transient editing without inducing off-target edits.[117][118]

Herpes simplex pharmaceutical drugs

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Johnston, Gottlieb & Wald 2016 published an overview of the state of research.[119]

Pharmaceutical drugs

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Since the introduction of the nucleoside analogs decades ago, treatment of herpes simplex virus (HSV) infections has not seen much innovation, except for the development of their respective prodrugs (Aciclovir, Famciclovir, Valacilovir..). Drawbacks such as poor bioavailability or limited effectiveness of these drugs require further research effort of new pharmaceutical drugs against the herpes simplex disease. The inhibitors of the Helicase-primase complex of HSV represent a very innovative approach to the treatment of herpesvirus disease.[120]

Pharmaceutical Drug Company Lead Researcher Type Status
Aciclovir patents expired Schaeffer & B. Elion nucleic acid analogue In Production
Valaciclovir patents expired ? nucleic acid analogue In Production
Famciclovir patents expired ? nucleic acid analogue In Production
Pritelivir AiCuris Anti-infective Cures AG ? helicase-primase inhibitor Phase III[121]
Amenamevir Astellas Pharma Inc Kiyomitsu Katsumata[122] helicase-primase inhibitor In Production
BX795 ? Deepak Shukla kinase inhibitor Preclinical
SADBE Squarex, LLC[123] Hugh McTavish, PhD, JD Topical immunological adjuvant Phase II[124]
Docosanol GlaxoSmithKline, Avanir ? Topical cell entry inhibitor[125] In Production

Notable progress

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Researchers have made a Hammerhead ribozyme that targets and cleaves the mRNA of essential genes in HSV-1. The hammerhead, which targets the mRNA of the UL20 gene, greatly reduced the level of HSV-1 ocular infection in rabbits, and reduced the viral yield in vivo.[126] The gene-targeting approach uses a specially designed RNA enzyme to inhibit strains of the herpes simplex virus. The enzyme disables a gene responsible for producing a protein involved in the maturation and release of viral particles in an infected cell. The technique appears to be effective in experiments with mice and rabbits, but further research is required before it can be attempted in people infected with herpes.[127]

In 2016, researchers showed that the genome editing technology known as CRISPR/Cas can be used to limit viral replication in multiple strains of herpesviruses, in some cases even eliminating the infection altogether.[128] The researchers tested three different strains of herpesviruses: Epstein-Barr virus, the cause of mononucleosis and some cancers; Herpes simplex viruses (HSV-1) and (HSV-2), which cause cold sores and genital herpes respectively; and human cytomegalovirus, which causes congenital herpes. The results indicated that CRISPR can be used to eliminate replication in all three strains of the virus, but that the technology was so far only successful in actually eradicating Epstein-Barr virus. The authors think this may be because the Epstein-Barr virus genome is located in dividing cells that are easily accessible to CRISPR. Comparatively, the HSV-1 genome targeted by CRISPR is located in closed-off, non-replicating neurons, which makes reaching the genome much more challenging.[129]

Another possibility to eradicate the HSV-1 variant is being pursued by a team at Duke University. By figuring out how to switch all copies of the virus in the host from latency to their active stage at the same time, rather than the way the virus copies normally stagger their activity stage, leaving some dormant somewhere at all times, it is thought that immune system could kill the entire infected cell population, since they can no longer hide in the nerve cells. This is a potentially risky approach especially for patients with widespread infections as there is the possibility of significant tissue damage from the immune response. One class of drugs called antagomir could trigger reactivation. These are chemically engineered oligonucleotides or short segments of RNA, that can be made to mirror their target genetic material, namely herpes microRNAs. They could be engineered to attach and thus 'silence' the microRNA, thus rendering the virus incapable of keeping latent in their host.[130] Professor Cullen believes a drug could be developed to block the microRNA whose job it is to suppress HSV-1 into latency.[131]

Oncolytic

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Herpes has been used in research with HeLa cells to determine its ability to assist in the treatment of malignant tumors. A study conducted using suicide gene transfer by a cytotoxic approach examined a way to eradicate malignant tumors.[132] Gene therapy is based on the cytotoxic genes that directly or indirectly kill tumor cells regardless of its gene expression. In this case the study uses the transfer of the Herpes simplex virus type I thymidine kinase (HSVtk) as the cytotoxic gene. Hela cells were used in these studies because they have very little ability to communicate through gap junctions.[133] The Hela cells involved were grown in a monolayer culture and then infected with the HSV virus. The HSV mRNA was chosen because it is known to share characteristics with normal eukaryotic mRNA.[134]

The HSVtk expression results in the phosphorylation of drug nucleoside analogues; in this case the drug ganciclovir, an antiviral medication used to treat and prevent cytomegaloviruses, converts it into the nucleoside analogue triphosphates. Once granciclovir is phosphorylated through HSV-tk it is then incorporating DNA strands when the cancer cells are multiplying.[133] The nucleotide from the ganciclovir is what inhibits the DNA polymerization and the replication process. This causes the cell to die via apoptosis.[132]

Apoptosis is regulated with the help of miRNAs, which are small non-coding RNAs that negatively regulate gene expression.[135] These miRNAs play a critical role in developing the timing, differentiation and death of cells. The miRNAs effect on apoptosis has affected cancer development by the regulation of cell proliferation, as well as cell transformation. Avoidance of apoptosis is critical for the success of malignant tumors, and one way for miRNAs to possibly influence cancer development is to regulate apoptosis. In order to support this claim, Hela cells were used for the experiment discussed.

The cytotoxic drug used, ganciclovir, is capable of destroying via apoptosis transduced cells and non-transduced cells from the cellular gap junction. This technique is known as the "bystander effect," which has suggested to scientists that the effect of some therapeutic agents may be enhanced by diffusion through gap junctional intercellular communication (GJIC) or cell coupling. GJIC is an important function in the maintaining of tissue homeostasis and it is a critical factor in balance of cells dying and surviving.

When Hela cells were transfected with the HSV-tk gene, and were then put in a culture with nontransfected cells, only the HSV-tk transfected Hela cells were killed by the granciclovir, leaving the nonviral cells unharmed.[133] The Hela cells were transfected with the encoding for the gap junction protein connexin 43 (Cx43) to provide a channel that permits ions and other molecules to move between neighboring cells. Both Hela cells with the HSV-tk and without the HSV-tk were destroyed. This result has led to the evidence needed to state that the bystander effect in the HSV-tk gene therapy is possibly due to the Cx-mediated GJIC.

Other research

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Amino acids (Arginine, Lysine) - Cold sores

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Research from 1964 into amino acid requirements of herpes simplex virus in human cells indicated that "...the lack of arginine or histidine, and possibly the presence of lysine, would interfere markedly with virus synthesis", but concludes that "no ready explanation is available for any of these observations".[136]

Further medical evidence indicates that "absorbing more arginine may indirectly cause cold sores by disrupting the body's balance of arginine and another amino acid called lysine."[137][138]

Further reviews conclude that "lysine's efficacy for herpes labialis may lie more in prevention than treatment." and that "the use of lysine for decreasing the severity or duration of outbreaks" is not supported, while further research is needed.[139]

Essential oils

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HSV is found to be susceptible to many essential oils and their constituents, however there is concern with the cutaneous use of essential oils is the degree of skin and mucous membrane irritation.[140][141][142]

Further reading

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  • Diefenbach, R. J., & Fraefel, C. (Eds.). (2019). Herpes simplex virus: Methods and protocols (2nd ed.). New York, NY: Humana Press.[143]
  • Merten, O.-W., & Al-Rubeai, M. (Eds.). (2016). Viral vectors for gene therapy: Methods and protocols. New York, NY: Humana Press.[144]
  • Mindel, A. (2011). Herpes Simplex Virus. London, England: Springer.[145]
  • Brown, P. (1997). Herpes Simplex Virus Protocols (1998th ed.; S. M. Brown & A. R. MacLean, Eds.). New York, NY: Humana Press.[146]
  • Studahl, M., Cinque, P., & Bergstrom, T. (Eds.). (2005). Herpes Simplex Viruses. Boca Raton, FL: CRC Press.[147]

References

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  1. ^ Gaskell, Rosalind; Dawson, Susan; Radford, Alan; Thiry, Etienne (March 2007). "Feline herpesvirus". Veterinary Research. 38 (2): 337–354. doi:10.1051/vetres:2006063. ISSN 0928-4249. PMID 17296160.
  2. ^ Decaro, Nicola; Martella, Vito; Buonavoglia, Canio (July 2008). "Canine Adenoviruses and Herpesvirus". Veterinary Clinics of North America: Small Animal Practice. 38 (4): 799–814. doi:10.1016/j.cvsm.2008.02.006. PMC 7114865. PMID 18501279.
  3. ^ Altan, Eda; Li, Yanpeng; Sabino-Santos Jr, Gilberto; Sawaswong, Vorthon; Barnum, Samantha; Pusterla, Nicola; Deng, Xutao; Delwart, Eric (2019-10-14). "Viruses in Horses with Neurologic and Respiratory Diseases". Viruses. 11 (10): 942. doi:10.3390/v11100942. ISSN 1999-4915. PMC 6832430. PMID 31614994.
  4. ^ "Marek's Disease in Chickens". Penn State Extension. Retrieved 2021-06-01.
  5. ^ Dias Queiroz-Castro, Vanessa Lopes; Santos, Marcus Rebouças; Augusto de Azevedo-Júnior, Marcos; Paulino da Costa, Eduardo; Pereira Alves, Saullo Vinicius; Nascimento Silva, Laura Morais; Dohanik, Virgínia Teles; Silva-Júnior, Abelardo (January 2021). "Bovine alphaherpesvirus 1 (BHV1) infection in testes and epididymis from bulls from a slaughterhouse". Theriogenology. 159: 1–6. doi:10.1016/j.theriogenology.2020.10.001. PMID 33113438. S2CID 225106858.
  6. ^ Nandi, S.; Kumar, Manoj; Manohar, M.; Chauhan, R. S. (June 2009). "Bovine herpes virus infections in cattle". Animal Health Research Reviews. 10 (1): 85–98. doi:10.1017/S1466252309990028. PMID 19558751. S2CID 30766513.
  7. ^ Chentoufi AA, Kritzer E, Yu DM, Nesburn AB, Benmohamed L (2012). "Towards a rational design of an asymptomatic clinical herpes vaccine: the old, the new, and the unknown". Clinical & Developmental Immunology. 2012: 1–16. doi:10.1155/2012/187585. PMC 3324142. PMID 22548113.
  8. ^ Egan, Kevin; Hook, Lauren M.; LaTourette, Philip; Desmond, Angela; Awasthi, Sita; Friedman, Harvey M. (June 2020). "Vaccines to prevent genital herpes". Translational Research. 220: 138–152. doi:10.1016/j.trsl.2020.03.004. PMC 7293938. PMID 32272093.
  9. ^ Whitley RJ, Roizman B (July 2002). "Herpes simplex viruses: is a vaccine tenable?". The Journal of Clinical Investigation. 110 (2): 145–51. doi:10.1172/JCI16126. PMC 151069. PMID 12122103.
  10. ^ "The Reddit Group Helping to Fund Herpes Vaccine Research".
  11. ^ Kim, Hyeon-Cheol (2020-07-27). "Vaccines against Genital Herpes: Where Are We?". Vaccines. 8 (3): 420. doi:10.3390/vaccines8030420. PMC 7566015. PMID 32727077.
  12. ^ "Monoclonal Antibody Therapy Against Chronic Herpes Simplex Virus 2 Infection (MATCH-2)". ClinicalTrials.gov. 2019-12-04. Retrieved 2020-03-27.
  13. ^ "A Phase 2 Trial to Evaluate the Safety and Efficacy of UB-621". ClinicalTrials.gov. 2020-03-25. Retrieved 2020-03-27.
  14. ^ "Pipeline | GSK". www.gsk.com. Retrieved 2022-12-30.
  15. ^ GlaxoSmithKline (2022-11-02). "A Phase I/II, Observer-blind, Randomised, Placebo-controlled, Multi-country Study to Evaluate Reactogenicity, Safety, Immune Response, and Efficacy of an HSV Vaccine in Healthy Participants Aged 18-40 Years or in Participants Aged 18-60 Years With Recurrent HSV-2 Genital Herpes". {{cite journal}}: Cite journal requires |journal= (help)
  16. ^ "BioNTech Starts Phase 1 Clinical Trial for Prophylactic Herpes Simplex Virus-2 Vaccine Candidate BNT163". investors.biontech.de. 2022-12-21. Retrieved 2023-03-13.
  17. ^ "Knipe Lab | Harvard Medical School". knipelab.med.harvard.edu. Retrieved 2016-08-02.
  18. ^ a b "Safety and Efficacy of 4 Investigational HSV 2 Vaccines in Adults With Recurrent Genital Herpes Caused by HSV 2 (HSV15)". ClinicalTrials.gov. Retrieved 2020-04-28.
  19. ^ a b "The Next HSV-529 Live Attenuated Therapeutic Vaccine Clinical Trial Has Begun". honeycomb.click. 15 January 2020. Retrieved 2020-04-28.
  20. ^ Dropulic, Lesia K (2019-09-15). "A Randomized, Double-Blinded, Placebo-Controlled, Phase 1 Study of a Replication-Defective Herpes Simplex Virus (HSV) Type 2 Vaccine, HSV529, in Adults With or Without HSV Infection". The Journal of Infectious Diseases. 220 (6): 990–1000. doi:10.1093/infdis/jiz225. PMC 6688060. PMID 31058977.
  21. ^ a b Stanfield BA, Stahl J, Chouljenko VN, Subramanian R, Charles AS, Saied AA, Walker JD, Kousoulas KG (2014). "A single intramuscular vaccination of mice with the HSV-1 VC2 virus with mutations in the glycoprotein K and the membrane protein UL20 confers full protection against lethal intravaginal challenge with virulent HSV-1 and HSV-2 strains". PLOS ONE. 9 (10): e109890. Bibcode:2014PLoSO...9j9890S. doi:10.1371/journal.pone.0109890. PMC 4211657. PMID 25350288.
  22. ^ a b Stanfield BA, Pahar B, Chouljenko VN, Veazey R, Kousoulas KG (January 2017). "Vaccination of rhesus macaques with the live-attenuated HSV-1 vaccine VC2 stimulates the proliferation of mucosal T cells and germinal center responses resulting in sustained production of highly neutralizing antibodies". Vaccine. 35 (4): 536–543. doi:10.1016/j.vaccine.2016.12.018. PMID 28017425.
  23. ^ a b Stanfield BA, Rider PJ, Caskey J, Del Piero F, Kousoulas KG (May 2018). "Intramuscular vaccination of guinea pigs with the live-attenuated human herpes simplex vaccine VC2 stimulates a transcriptional profile of vaginal Th17 and regulatory Tr1 responses". Vaccine. 36 (20): 2842–2849. doi:10.1016/j.vaccine.2018.03.075. PMID 29655629.
  24. ^ "Herpes Virus Mutant Points Towards New Vaccine Strategy". news.feinberg.northwestern.edu. 18 December 2017. Retrieved 2018-08-13.
  25. ^ a b Richards AL, Sollars PJ, Pitts JD, Stults AM, Heldwein EE, Pickard GE, Smith GA (December 2017). "The pUL37 tegument protein guides alpha-herpesvirus retrograde axonal transport to promote neuroinvasion". PLOS Pathogens. 13 (12): e1006741. doi:10.1371/journal.ppat.1006741. PMC 5749899. PMID 29216315.
  26. ^ "Pipeline" (PDF). X-Vax. Retrieved 19 August 2021.
  27. ^ Petro CD, Weinrick B, Khajoueinejad N, Burn C, Sellers R, Jacobs WR, Herold BC (August 2016). "HSV-2 ΔgD elicits FcγR-effector antibodies that protect against clinical isolates". JCI Insight. 1 (12). doi:10.1172/jci.insight.88529. PMC 4985247. PMID 27536733.
  28. ^ Burn Aschner, Clare; Knipe, David M.; Herold, Betsy C. (7 May 2020). "Model of vaccine efficacy against HSV-2 superinfection of HSV-1 seropositive mice demonstrates protection by antibodies mediating cellular cytotoxicity". npj Vaccines. 5 (1): 35. doi:10.1038/s41541-020-0184-7. PMC 7206093. PMID 32411398.
  29. ^ Awasthi S, Hook LM, Pardi N, Wang F, Myles A, Cancro MP, Cohen GH, Weissman D, Friedman HM, et al. (20 Sep 2019). "Nucleoside-modified mRNA Encoding HSV-2 Glycoproteins C, D, E Prevents Clinical and Subclinical Genital Herpes". Science Immunology. 4 (39): eaaw7083. doi:10.1126/sciimmunol.aaw7083. PMC 6822172. PMID 31541030.
  30. ^ Egan KP, Hook LM, Naughton A, Pardi N, Awasthi S, Cohen GH, Weissman D, Friedman HM (27 July 2020). "An HSV-2 nucleoside-modified mRNA genital herpes vaccine containing glycoproteins gC, gD, and gE protects mice against HSV-1 genital lesions and latent infection". PLOS Pathogens. 16 (7): e1008795. doi:10.1371/journal.ppat.1008795. PMC 7410331. PMID 32716975.
  31. ^ "Moderna Expands Its mRNA Pipeline with Three New Development Programs". investors.modernatx.com. Retrieved 2022-02-21.
  32. ^ "Immune Design Pipeline". Immune Design. Archived from the original on 23 April 2017. Retrieved 22 April 2017.
  33. ^ Odegard JM, Flynn PA, Campbell DJ, Robbins SH, Dong L, Wang K, Ter Meulen J, Cohen JI, Koelle DM (January 2016). "A novel HSV-2 subunit vaccine induces GLA-dependent CD4 and CD8 T cell responses and protective immunity in mice and guinea pigs". Vaccine. 34 (1): 101–9. doi:10.1016/j.vaccine.2015.10.137. PMC 6322202. PMID 26571309.
  34. ^ a b "GV2207 – HSV-2 Immunotherapeutic :: GenVec, Inc. (GNVC)". www.genvec.com. Retrieved 2016-08-16.
  35. ^ "Nanobio - HSV-2 Vaccine". Archived from the original on 18 August 2016. Retrieved 2 August 2016.
  36. ^ "Ann Arbor's NanoBio Changes Name to BlueWillow as Focus Shifts to Vaccines". DBusiness Magazine. 2018-05-08. Retrieved 2022-12-30.
  37. ^ "PBS Vax™ Therapeutic Vaccines". profectusbiosciences.com. Archived from the original on 23 May 2019. Retrieved 15 August 2016.
  38. ^ "Introducing RVx". 2016-03-12. Archived from the original on 2016-10-19. Retrieved 2016-08-02.
  39. ^ "Herpes Vaccine Research". Herpes Vaccine Research. Archived from the original on 2016-08-25. Retrieved 2016-08-02.
  40. ^ Marissa, Taylor (2018-04-12). "FDA Launches Criminal Investigation Into Unauthorized Herpes Vaccine Research".
  41. ^ "FDA Launches Criminal Investigation Into Unauthorized Herpes Vaccine Research". khn.org. 23 April 2018. Retrieved 2018-05-21.
  42. ^ "Rational Vaccines: A case study in pharma deregulation - MedCity News". medcitynews.com. March 2017. Retrieved 26 September 2017.
  43. ^ Schaffer, Amanda (2018-05-01). "The Dying Scientist and His Rogue Vaccine Trial". Wired.
  44. ^ "Vitaherpavac vaccine". Firma Vitafarma. Retrieved 2020-02-06.
  45. ^ Barkhaleva, O. A.; Ladyzhenskaia, I. P.; Vorob'Eva, M. S.; Shalunova, N. V.; Podcherniaeva, R. Ia.; Mikhaĭlova, G. R.; Khorosheva, T. V.; Barinskiĭ, I. F. (2009). "Vitaherpavac is the first Russian herpes simplex virus vaccine obtained on the Vero B continuous cell line". Voprosy Virusologii. 54 (5): 33–7. PMID 19882901.
  46. ^ "Vitagerpavac". Firma Vitafarma (in Russian). Retrieved 2020-02-06.
  47. ^ "Herpes Virus Mutant Points Towards New Vaccine Strategy". 18 December 2017.
  48. ^ Halford WP, Püschel R, Gershburg E, Wilber A, Gershburg S, Rakowski B (March 2011). "A live-attenuated HSV-2 ICP0 virus elicits 10 to 100 times greater protection against genital herpes than a glycoprotein D subunit vaccine". PLOS ONE. 6 (3): e17748. Bibcode:2011PLoSO...617748H. doi:10.1371/journal.pone.0017748. PMC 3055896. PMID 21412438.
  49. ^ Halford WP, Geltz J, Gershburg E (2013). "Pan-HSV-2 IgG antibody in vaccinated mice and guinea pigs correlates with protection against herpes simplex virus 2". PLOS ONE. 8 (6): e65523. Bibcode:2013PLoSO...865523H. doi:10.1371/journal.pone.0065523. PMC 3675040. PMID 23755244.
  50. ^ Halford WP, Püschel R, Rakowski B (August 2010). "Herpes simplex virus 2 ICP0 mutant viruses are avirulent and immunogenic: implications for a genital herpes vaccine". PLOS ONE. 5 (8): e12251. Bibcode:2010PLoSO...512251H. doi:10.1371/journal.pone.0012251. PMC 2923193. PMID 20808928.
  51. ^ Bloom J (2018-02-08). "I Met With A Theravax Herpes Vaccine Patient And Here Is What He Said". acsh.org. Retrieved 2018-08-09.
  52. ^ Mundle ST, Hernandez H, Hamberger J, Catalan J, Zhou C, Stegalkina S, Tiffany A, Kleanthous H, Delagrave S, Anderson SF (2013). "High-purity preparation of HSV-2 vaccine candidate ACAM529 is immunogenic and efficacious in vivo". PLOS ONE. 8 (2): e57224. Bibcode:2013PLoSO...857224M. doi:10.1371/journal.pone.0057224. PMC 3582571. PMID 23468943.
  53. ^ van Lint, Allison L.; Torres-Lopez, Ernesto; Knipe, David M. (November 2007). "Immunization with a replication-defective herpes simplex virus 2 mutant reduces herpes simplex virus 1 infection and prevents ocular disease". Virology. 368 (2): 227–231. doi:10.1016/j.virol.2007.08.030. PMC 2099303. PMID 17915278.
  54. ^ "NIH Launches Trial of Investigational Genital Herpes Vaccine". NIAID. Retrieved 17 September 2014.
  55. ^ "Comparative Efficacy and Immunogenicity of Replication-Defective, Recombinant Glycoprotein, and DNA Vaccines for Herpes Simplex Virus 2 Infections in Mice and Guinea Pigs" (PDF). Journal of Virology. Retrieved May 20, 2014.
  56. ^ "Herpes Vaccine Developed at HMS Licensed for Preclinical Trials". March 7, 2008. Archived from the original on March 19, 2012. Retrieved April 6, 2012.
  57. ^ "Press Release: Sanofi continues to deliver strong business EPS growth driven by higher sales and improved margins in Q1". Sanofi.
  58. ^ "Our Pipeline". Retrieved June 18, 2022.
  59. ^ Dutton, Julie L.; Li, Bo; Woo, Wai-Ping; Marshak, Joshua O.; Xu, Yan; Huang, Meei-li; Dong, Lichun; Frazer, Ian H.; Koelle, David M. (3 October 2013). "A Novel DNA Vaccine Technology Conveying Protection against a Lethal Herpes Simplex Viral Challenge in Mice". PLOS ONE. 8 (10): e76407. Bibcode:2013PLoSO...876407D. doi:10.1371/journal.pone.0076407. PMC 3789751. PMID 24098493.
  60. ^ "Potential Cure For Herpes Simplex Virus". HSV Outbreak. Retrieved 19 August 2014.
  61. ^ "Gardasil inventor Professor Ian Frazer's new genital herpes vaccine proves safe in passing first human trials". Retrieved 21 February 2014.
  62. ^ "Admedus vaccine for herpes has success; moves to next clinical trial". Proactive Investors. Retrieved 3 October 2014.
  63. ^ "Admedus increases interest in Prof Ian Frazer's vaccines". Proactive Investors. 2014-07-24. Retrieved 3 September 2014.
  64. ^ "Admedus has high hopes for Herpes vaccine as dosing commences - Proactiveinvestors (AU)". 2015-04-10. Retrieved 2 August 2016.
  65. ^ "ADMEDUS ANNOUNCES POSITIVE UNBLINDED HSV-2 PHASE II INTERIM DATA" (PDF). Admedus.
  66. ^ "Admedus Changes Name to Anteris Technologies Ltd. Provides Corporate and Clinical Development Update". Biospace. June 2020.
  67. ^ "ANTERIS TECHNOLOGIES (ASX: AVR)" (PDF). CTF Assets.
  68. ^ "Витагерпавак". vitagerpavak.ru. Retrieved 2018-11-09.
  69. ^ Petro C, González PA, Cheshenko N, Jandl T, Khajoueinejad N, Bénard A, Sengupta M, Herold BC, Jacobs WR (March 2015). "Herpes simplex type 2 virus deleted in glycoprotein D protects against vaginal, skin and neural disease". eLife. 4. doi:10.7554/eLife.06054. PMC 4352706. PMID 25756612.
  70. ^ "Radical Vaccine Design Effective Against Herpes Virus". HHMI.org. Retrieved 12 March 2015.
  71. ^ "NanoBio's Genital Herpes Vaccine Demonstrates Efficacy In Guinea Pigs As Both A Prophylactic And A Therapeutic Vaccine". NanoBio Corporation. Archived from the original on 4 October 2015. Retrieved 2 October 2015.
  72. ^ "Pipeline for PBS Vax™ Therapeutic Vaccines". Profectus Biosciences. Archived from the original on 23 May 2019. Retrieved 12 December 2015.
  73. ^ "BioMedical Research Models Inc awarded Grant for Mucosal HSV-2 vaccine". Vaccine Nation (Cameron Bisset). Archived from the original on 9 September 2014. Retrieved 13 June 2014.
  74. ^ "Project Information - NIH RePORTER - NIH Research Portfolio Online Reporting Tools Expenditures and Results". Retrieved 2 August 2016.
  75. ^ "HSV2 therapeutic vaccine program".
  76. ^ "Sanofi Pasteur and Immune Design Enter Broad Collaboration for the Development of a Herpes Simplex Virus Therapy". Archived from the original on 22 October 2014. Retrieved 17 October 2014.
  77. ^ "Status of Vaccine Research and Development of Vaccines for Herpes Simplex Virus" (PDF). Retrieved 30 August 2016.
  78. ^ Sandgren KJ, Bertram K, Cunningham AL (July 2016). "Understanding natural herpes simplex virus immunity to inform next-generation vaccine design". Clinical & Translational Immunology. 5 (7): e94. doi:10.1038/cti.2016.44. PMC 4973325. PMID 27525067.
  79. ^ "QUESTIONS AND ANSWERS The Herpevac Trial for Women". Retrieved 30 August 2016.
  80. ^ a b Cohen J (October 2010). "Immunology. Painful failure of promising genital herpes vaccine". Science. 330 (6002): 304. Bibcode:2010Sci...330..304C. doi:10.1126/science.330.6002.304. PMID 20947733.
  81. ^ Awasthi, Sita; Belshe, Robert B.; Friedman, Harvey M. (15 August 2014). "Better Neutralization of Herpes Simplex Virus Type 1 (HSV-1) Than HSV-2 by Antibody From Recipients of GlaxoSmithKline HSV-2 Glycoprotein D2 Subunit Vaccine". The Journal of Infectious Diseases. 210 (4): 571–575. doi:10.1093/infdis/jiu177. PMC 4172040. PMID 24652496.
  82. ^ "PaxVax Signs R&D Collaboration with UC San Diego to Develop a Vaccine to Prevent Herpes Simplex Virus Infections". paxvax.com. 2014-06-10. Archived from the original on 2016-08-15. Retrieved 15 August 2016.
  83. ^ "About". Archived from the original on 5 January 2017. Retrieved 4 January 2017.
  84. ^ a b "The PaxVax Platform - Product Pipeline". Archived from the original on 8 September 2016. Retrieved 5 September 2016.
  85. ^ Awasthi S, Zumbrun EE, Si H, Wang F, Shaw CE, Cai M, Lubinski JM, Barrett SM, Balliet JW, Flynn JA, Casimiro DR, Bryan JT, Friedman HM (April 2012). "Live attenuated herpes simplex virus 2 glycoprotein E deletion mutant as a vaccine candidate defective in neuronal spread". Journal of Virology. 86 (8): 4586–98. doi:10.1128/JVI.07203-11. PMC 3318599. PMID 22318147.
  86. ^ a b "Amgen Pipeline". Archived from the original on 29 July 2015. Retrieved 2 August 2016.
  87. ^ "Genocea Announces Strategic Shift to Immuno-oncology and the Development of Neoantigen Cancer Vaccines". Genocea. 25 September 2017. Archived from the original on 2017-09-26.{{cite web}}: CS1 maint: unfit URL (link)
  88. ^ "AuRx, Inc". AuRx. Retrieved 4 January 2017.
  89. ^ "AuRx, Inc". AuRx. Retrieved 4 January 2017.
  90. ^ McAllister SC, Schleiss MR (November 2014). "Prospects and perspectives for development of a vaccine against herpes simplex virus infections". Expert Review of Vaccines. 13 (11): 1349–60. doi:10.1586/14760584.2014.932694. PMC 4385587. PMID 25077372.
  91. ^ a b "Mymetics HSV Vaccine Candidate". Mymetics. Archived from the original on 14 May 2016. Retrieved 22 April 2016.
  92. ^ "Biological Efficacy Study of HerpV Vaccine With QS-21 to Treat Subjects With Recurrent Genital Herpes". Retrieved 31 August 2016.
  93. ^ "Vical HSV-2 Therapeutic Vaccine VCL-HB01". Archived from the original on 20 March 2016. Retrieved 18 January 2016.
  94. ^ a b "Vical Reports Phase 2 Trial of HSV-2 Therapeutic Vaccine Did Not Meet Primary Endpoint". Vical.com. Archived from the original on 16 June 2018. Retrieved 16 June 2018.
  95. ^ a b "Herpevac Trial for Women". Archived from the original on 2007-10-20. Retrieved 2008-03-04.
  96. ^ "PaxVax Signs R&D Collaboration with UC San Diego to Develop a Vaccine to Prevent Herpes Simplex Virus Infections - PaxVax - Socially Responsible Vaccines". 2014-06-10. Retrieved 2 August 2016.
  97. ^ "BioVex commences dosing in Phase 1 study of ImmunoVEX live attenuated genital herpes vaccine". 5 March 2010. Retrieved 2 August 2016.
  98. ^ "Amgen completes acquisition of BioVex Group". Boston.com. 4 March 2011. Retrieved 2 August 2016 – via The Boston Globe.
  99. ^ "AuRx, Inc". Retrieved 2 August 2016.
  100. ^ "Agenus Vaccine Shows Significant Reduction in Viral Burden after HerpV Generated Immune Activation". Business Wire. 2014-06-26. Retrieved 10 September 2014.
  101. ^ "Herpes News: Early 2014 Roundup - Just Herpes". 2014-03-07. Retrieved 2 August 2016.
  102. ^ "Pipeline - Agenus". agenusbio.com. Retrieved 26 September 2017.
  103. ^ "Genocea Corporate Overview" (PDF). Genocea. Archived from the original on 11 May 2016. Retrieved 5 March 2016.{{cite web}}: CS1 maint: unfit URL (link)
  104. ^ "Genocea Announces Strategic Shift to Immuno-oncology and the Development of Neoantigen Cancer Vaccines". genocea.com. Archived from the original on 26 September 2017. Retrieved 26 September 2017.{{cite web}}: CS1 maint: unfit URL (link)
  105. ^ "Vical (VICL) Genital Herpes Vaccine Phase 1/2 Missed Primary Endpoint". StreetInsider.com. Retrieved 22 June 2015.
  106. ^ "Vical Reports Top-Line Results From Phase 1/2 Trial of Therapeutic Genital Herpes Vaccine". FierceMarkets. 22 June 2015. Retrieved 23 June 2015.
  107. ^ "Vical's Phase 1/2 Trial Data Presented at ASM 2016 Shows Bivalent Vaccine Imparts Reduction in Genital Herpes Lesions Durable to 9 Months". Globe Newswire (Press release). 2018-06-20. Retrieved 29 June 2018.
  108. ^ Kennedy EM, Cullen BR (January 2017). "Gene Editing: A New Tool for Viral Disease". Annual Review of Medicine. 68 (1): 401–411. doi:10.1146/annurev-med-051215-031129. PMID 27576009.
  109. ^ Aubert M, Madden EA, Loprieno M, DeSilva Feelixge HS, Stensland L, Huang ML, Greninger AL, Roychoudhury P, Niyonzima N, Nguyen T, Magaret A, Galleto R, Stone D, Jerome KR (September 2016). "In vivo disruption of latent HSV by designer endonuclease therapy". JCI Insight. 1 (14). doi:10.1172/jci.insight.88468. PMC 5026126. PMID 27642635.
  110. ^ Engel M (8 September 2016). "Can gene editing cure herpes?". Fred Hutch News Service. Retrieved 7 January 2017.
  111. ^ Kennedy EM, Cullen BR (May 2015). "Bacterial CRISPR/Cas DNA endonucleases: A revolutionary technology that could dramatically impact viral research and treatment". Virology. 479–480: 213–20. doi:10.1016/j.virol.2015.02.024. PMC 4424069. PMID 25759096.
  112. ^ Roehm PC, Shekarabi M, Wollebo HS, Bellizzi A, He L, Salkind J, Khalili K (April 2016). "Inhibition of HSV-1 Replication by Gene Editing Strategy". Scientific Reports. 6: 23146. Bibcode:2016NatSR...623146R. doi:10.1038/srep23146. PMC 4827394. PMID 27064617.
  113. ^ Gordon L (2016-01-26). "Researchers aim to find cure for herpes". The Temple News. Retrieved 8 January 2017.
  114. ^ "Therapeutic and Vaccine Pipeline". Excision BioTherapeutics - Gene Editing Therapeutics. Excision BioTherapeutics. Retrieved 19 January 2017.
  115. ^ van Diemen FR, Kruse EM, Hooykaas MJ, Bruggeling CE, Schürch AC, van Ham PM, Imhof SM, Nijhuis M, Wiertz EJ, Lebbink RJ (June 2016). "CRISPR/Cas9-Mediated Genome Editing of Herpesviruses Limits Productive and Latent Infections". PLOS Pathogens. 12 (6): e1005701. doi:10.1371/journal.ppat.1005701. PMC 4928872. PMID 27362483.
  116. ^ Kassabian S (4 August 2016). "CRISPR Puts Up a Fight Against Persistent Herpesviruses: A Short Animation". PLOS BLOGS. Retrieved 8 January 2017.[unreliable medical source?]
  117. ^ "Transient editing catches the eye". Nature Biomedical Engineering. 5 (2): 127. February 2021. doi:10.1038/s41551-021-00695-z. PMID 33580230.
  118. ^ Yin, Di; Ling, Sikai; Wang, Dawei; Dai, Yao; Jiang, Hao; Zhou, Xujiao; Paludan, Soren R.; Hong, Jiaxu; Cai, Yujia (11 January 2021). "Targeting herpes simplex virus with CRISPR–Cas9 cures herpetic stromal keratitis in mice". Nature Biotechnology. 39 (5): 567–577. doi:10.1038/s41587-020-00781-8. ISSN 1546-1696. PMC 7611178. PMID 33432198.
  119. ^ Johnston, Christine; Gottlieb, Sami L.; Wald, Anna (June 2016). "Status of vaccine research and development of vaccines for herpes simplex virus". Vaccine. 34 (26): 2948–2952. doi:10.1016/j.vaccine.2015.12.076. PMID 26973067.
  120. ^ Birkmann, Alexander; Hewlett, Guy; Rübsamen-Schaeff, Helga; Zimmermann, Holger (October 2011). "Helicase–Primase Inhibitors as the Potential Next Generation of Highly Active Drugs Against Herpes Simplex Viruses". Future Virology. 6 (10): 1199–1209. doi:10.2217/fvl.11.28.
  121. ^ "AiCuris - R&D Pipeline". www.aicuris.com. Retrieved 2016-09-16.
  122. ^ Katsumata K, Chono K, Sudo K, Shimizu Y, Kontani T, Suzuki H (August 2011). "Effect of ASP2151, a herpesvirus helicase-primase inhibitor, in a guinea pig model of genital herpes". Molecules. 16 (9): 7210–23. doi:10.3390/molecules16097210. PMC 6264763. PMID 21869749.
  123. ^ "Products". 2016-11-10. Archived from the original on 2018-10-11. Retrieved 2018-10-11.
  124. ^ "Double-blind, Vehicle-controlled Study of the Efficacy and Safety of SADBE in Subjects With Recurrent Herpes Labialis - Full Text View - ClinicalTrials.gov". clinicaltrials.gov. 19 February 2018. Retrieved 29 January 2019.
  125. ^ Sadowski LA, Upadhyay R, Greeley ZW, Margulies BJ (June 2021). "Current Drugs to Treat Infections with Herpes Simplex Viruses-1 and -2". Viruses. 13 (7): 1228. doi:10.3390/v13071228. PMC 8310346. PMID 34202050. n-Docosanol is a long-chain, 22-carbon, primary alcohol offered over the counter. It likely inhibits a broad range of enveloped viruses that uncoat at the plasma membrane of target cells. The drug appears to prevent binding and entry of HSVs by interfering directly with the cell surface phospholipids, which are required by the viruses for entry, and stabilizing them. This activity tends to work well against ACV-resistant HSVs and can even act synergistically with other anti-HSV drugs.
  126. ^ Liu, Jia; Tuli, Sonal S.; Bloom, David C.; Schultz, Gregory S.; Ghivizzani, Steve C.; Lewin, Alfred S. (2006). "801. RNA Gene Therapy Targeting Herpes Simplex Virus". Molecular Therapy. 13: S310. doi:10.1016/j.ymthe.2006.08.890.
  127. ^ "University of Florida News –Potential new herpes therapy studied". News.ufl.edu. 2009-02-03. Archived from the original on 2010-06-13. Retrieved 2011-04-12.
  128. ^ Kassabian S (2016-08-04). "CRISPR Puts Up a Fight Against Persistent Herpesviruses: A Short Animation". Speaking of Medicine - PLOS Community Blog. PLOS.org. Retrieved 4 August 2016.[unreliable medical source?]
  129. ^ van Diemen FR (4 August 2016). "Using CRISPR to combat viral infections: a new way to treat herpes?". PLOS Media YouTube Channel. PLOS.org. Retrieved 4 August 2016.
  130. ^ Fox M (2008-07-02). "New approach offers chance to finally kill herpes". Reuters. Retrieved 2011-04-12.
  131. ^ Kingsbury K (2008-07-02). "A Cure for Cold Sores?". Time. Archived from the original on July 3, 2008. Retrieved 2010-05-04.
  132. ^ a b Trepel M, Stoneham CA, Eleftherohorinou H, Mazarakis ND, Pasqualini R, Arap W, Hajitou A (August 2009). "A heterotypic bystander effect for tumor cell killing after adeno-associated virus/phage-mediated, vascular-targeted suicide gene transfer". Molecular Cancer Therapeutics. 8 (8): 2383–91. doi:10.1158/1535-7163.MCT-09-0110. PMC 2871293. PMID 19671758.
  133. ^ a b c Mesnil M, Piccoli C, Tiraby G, Willecke K, Yamasaki H (March 1996). "Bystander killing of cancer cells by herpes simplex virus thymidine kinase gene is mediated by connexins". Proceedings of the National Academy of Sciences of the United States of America. 93 (5): 1831–5. Bibcode:1996PNAS...93.1831M. doi:10.1073/pnas.93.5.1831. PMC 39867. PMID 8700844.
  134. ^ Stringer JR, Holland LE, Swanstrom RI, Pivo K, Wagner EK (March 1977). "Quantitation of herpes simplex virus type 1 RNA in infected HeLa cells". Journal of Virology. 21 (3): 889–901. doi:10.1128/JVI.21.3.889-901.1977. PMC 515626. PMID 191652.
  135. ^ Jovanovic M, Hengartner MO (October 2006). "miRNAs and apoptosis: RNAs to die for". Oncogene. 25 (46): 6176–87. doi:10.1038/sj.onc.1209912. PMID 17028597. S2CID 17202284.
  136. ^ Tankersley, Robert W. (1964-03-01). "Amino Acid Requirements of Herpes Simplex Virus in Human Cells". Journal of Bacteriology. 87 (3): 609–613. doi:10.1128/jb.87.3.609-613.1964. ISSN 0021-9193. PMC 277062. PMID 14127578.
  137. ^ "High-arginine foods: Sources, benefits, and risks". www.medicalnewstoday.com. 2018-10-04. Retrieved 2021-05-27.
  138. ^ "L-Arginine: MedlinePlus Supplements". medlineplus.gov. Retrieved 2021-05-27.
  139. ^ Tomblin, Frankie A. Jr; Lucas, Kristy H. (2001-02-15). "Lysine for management of herpes labialis". American Journal of Health-System Pharmacy. 58 (4): 298–304. doi:10.1093/ajhp/58.4.298. ISSN 1079-2082. PMID 11225166.
  140. ^ Schnitzler, Paul (2019). "Essential Oils for the Treatment of Herpes Simplex Virus Infections". Chemotherapy. 64 (1): 1–7. doi:10.1159/000501062. PMID 31234166. S2CID 195356798.
  141. ^ Astani, Akram; Reichling, Jürgen; Schnitzler, Paul (May 2010). "Comparative study on the antiviral activity of selected monoterpenes derived from essential oils". Phytotherapy Research. 24 (5): 673–679. doi:10.1002/ptr.2955. PMC 7167768. PMID 19653195.
  142. ^ Koch, C.; Reichling, J.; Schneele, J.; Schnitzler, P. (January 2008). "Inhibitory effect of essential oils against herpes simplex virus type 2". Phytomedicine. 15 (1–2): 71–78. doi:10.1016/j.phymed.2007.09.003. PMID 17976968.
  143. ^ Herpes simplex virus: methods and protocols. Russell J. Diefenbach, Cornel Fraefel (2nd ed.). New York. 2020. ISBN 978-1-4939-9814-2. OCLC 1124957988.{{cite book}}: CS1 maint: location missing publisher (link) CS1 maint: others (link)
  144. ^ Merten, Otto-Wilhelm (2016). Viral vectors for gene therapy (Softcover reprint of ed.). [Place of publication not identified]: Humana. ISBN 978-1-4939-5828-3. OCLC 954007942.
  145. ^ Mindel, Adrian (1989). Herpes Simplex Virus. London: Springer London. ISBN 978-1-4471-1683-7. OCLC 853259110.
  146. ^ Herpes simplex virus protocols. S. Moira Brown, Alasdair R. MacLean. Totowa, N.J.: Humana Press. 1998. ISBN 978-1-59259-594-5. OCLC 229911441.{{cite book}}: CS1 maint: others (link)
  147. ^ Herpes simplex viruses. Marie Studahl, Paola Cinque, T. Bergström. Boca Raton: Taylor & Francis. 2006. ISBN 978-0-8247-2731-4. OCLC 61254022.{{cite book}}: CS1 maint: others (link)