Difference between revisions of "Talimogene Laherparepvec: A groundbreaking viral therapy for late stage melanoma"

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[[Image:tvectable1.png|thumb|400px|right|<b> Figure 3:</b> Image of the results from the Phase II and III T-VEC studies. The results shown include the number of patients, the stage of their melanoma, the objective response rates and overall survival. The objective response rates are a measure of the amount of patients who experienced a predetermined tumor size reduction. The durable response rates are a measurement of the length of patients response rates. Stage IIIc melanoma cannot be removed by surgery but remains localized to the original tumor. Stage IVa melanoma has begun to spread away from the original tumor, and stages IVb/c have spread to areas like the nervous and respiratory systems.  [[#References|[9]]] [https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4519012/pdf/nihms709872.pdf]]
 
[[Image:tvectable1.png|thumb|400px|right|<b> Figure 3:</b> Image of the results from the Phase II and III T-VEC studies. The results shown include the number of patients, the stage of their melanoma, the objective response rates and overall survival. The objective response rates are a measure of the amount of patients who experienced a predetermined tumor size reduction. The durable response rates are a measurement of the length of patients response rates. Stage IIIc melanoma cannot be removed by surgery but remains localized to the original tumor. Stage IVa melanoma has begun to spread away from the original tumor, and stages IVb/c have spread to areas like the nervous and respiratory systems.  [[#References|[9]]] [https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4519012/pdf/nihms709872.pdf]]
  
==Section 2==
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==Development and mechanism of Talimogene Laherparepvec==
Include some current research, with at least one figure showing data.<br>
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BioVex Inc., the inventors of T-VEC, were purchased by the company Amgen in 2011 for around $1-billion dollars to develop their breakthrough treatment for melanoma [[#References|[4]]]. The BioVex group created T-VEC by genetically engineering human herpes virus 1 (HSV-1) to decrease its pathogenicity for healthy human cells while increasing the viruses ability to attack and kill tumor cells (Figure 1) [[#References|[4]]]. The strain of HSV-1 used as a starting block for T-VEC was JS1 which exhibited a greater ability to kill cancer cells in comparison to other natural and engineered strains of herpes virus (Figure 1)[[#References|[5]]]. The JS1 strain of HSV-1 was genetically engineered by having its copies of the genes containing neurovirulence factors ICP34.5 and ICP47 deleted (Figure 1)[[#References|[5]]]. Neurovirulence factors give HSV-1the ability to cause disease in the human nervous system and the removal of those genes improves the safety of the virus. The removal of ICP34.5 specifically lowered the strains neurotoxicity while the removal of ICP47 is associated with an increase of the viruses ability to replicate with in cancer cells, killing them in the process [[#References|[5]]]. The deletion of ICP47 is also associated with the upregulation of the gene US11 which increases the viruses ability to replicate within tumors and lyse them [[#References|[6]]]. Finally, the gene for granulocyte macrophage colony-stimulating factor (GM-CSF) was inserted to replace the two deleted neurovirulence factors to help increase immune response through the promotion of dendritic cells [[#References|[6]]]. Dendritic cells are a part of the adaptive immune system and help signal immune responses by creating antigens that will signal the presence of cancerous cells to the human body. GM-CSF increases the ability of T-VEC to treat distal tumors not directly injected with the virus [[#References|[7]]]. The increased expression of US11 helps increase the tumor specific replication of viruses [7]. None of the alterations done by the BioVex group made T-VEC resistant to common antiviral drugs available such as acylclovir, which can be used to treat HSV-1 [5]. This gives doctors the ability to treat for a viral infection if something were to go wrong with T-VEC in a patient.
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The mechanism of T-VEC is to selectively replicate within tumor cells and lyse them (Figure 2)[[#References|[4]]]. Once the virus lyses a tumor cell many viral particles and tumor antigens will be released into the surrounding tumor and inducing a strong immune response against the tumor by signaling to the adaptive immune system which can fight cancerous cells (Figure 2)[[#References|[5]]]. As the virus directly kills and lyses cancer cells, it spreads itself even further into the tumor by releasing copies of its self-made within the cancer cells, increasing its own effectiveness [[#References|[5]]]. The reason viruses can selectively enter cancerous cells is because they have mutated so much that they have lost their antiviral defense mechanisms [[#References|[4]]].
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Revision as of 14:55, 26 April 2018

This is a curated page. Report corrections to Microbewiki.

Classification

Baltimore classification: dsDNA
Family: Herpesviridae
Virion: Enveloped
Capsid symmetry: Icosahedral
Replication site: Nucleus and cytoplasm

Overview of Melanoma and effective treatment options

Melanoma, one of the most dangerous forms of skin cancer, can occur when skin cells are exposed to UV radiation from the sun without protection [1]. When skin cells are frequently exposed to UV radiation, pigment producing cells called melanocytes can accumulate mutations within their DNA, and sometimes these mutations can cause them to turn cancerous [1]. Cancerous cells divide unchecked by normal cell signaling and multiply into tumors on the skin [1]. Melanoma can occur anywhere on the human epidermis including the head, neck, hips, back, and even the eye [2]. The reason melanoma is considered to be dangerous is that it frequently becomes metastatic, which means that it spreads to areas around the human body different from where it originated, and when cancer spreads it becomes extremely difficult to treat [2]. One of the most common ways to see if someone has melanoma is to check their body for moles. The moles are often discolored, change in size and shape over time, and are asymmetrical [2]. Melanoma can be staged in 5 different categories, 0-IV, with the earlier stages being the easiest to treat while the later stages are the most difficult to treat especially if the cancer has spread throughout the human body. In general, there are five different way of treating melanoma. The five most common techniques used are chemotherapy, surgery, immunotherapy, radiation therapy, and targeted therapy [2]. All of these treatments have positives and negatives associated with them, but this page will focus on one novel microbial based treatment for melanoma that falls within the immunotherapy category. One of the reasons to choose immunotherapy over other forms of treatment is that a variety of cancers can be treated because the immune system is being improved through the treatment [3]. Treatments such as radiation and chemotherapy are relatively ineffective against melanoma making immunotherapy one of the only viable options for patients with this illness [3]. Another benefit to immunotherapy is that its treatments have been shown to last longer in comparison to other therapies because the immune system is trained to recognize what cancer cells look like to eliminate them and inhibit tumor growth [3]. Immunotherapy is a more precise way to treat cancer than other common therapies such as chemo and radiation therapy which use radiation and toxic drugs that can be effective during treatment but cause extensive damage to normal human cells [3]. One of the most recent breakthroughs in immunotherapy was the development of the first Oncolytic virus called Talimogene Laherparepvec (T-VEC).





By Alex Fazioli


Figure 1: Transmission Electron Micrograph of a Herpes Simple Virus Particle by Jay C. Brown of the University of Virginia. [http://darwin.bio.uci.edu/~faculty/wagner/hsv2f.html.


Figure 2: Image of the local and systemic effects of T-VEC. The local impact of T-VEC includes replication within cancer cells and release of virus particles upon cell lysis. The systemic impact of T-VEC includes the release of tumor specific antigens and the activation of Dendritic cells by GM-CSF. [9][https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4519012/pdf/nihms709872.pdf
Figure 3: Image of the results from the Phase II and III T-VEC studies. The results shown include the number of patients, the stage of their melanoma, the objective response rates and overall survival. The objective response rates are a measure of the amount of patients who experienced a predetermined tumor size reduction. The durable response rates are a measurement of the length of patients response rates. Stage IIIc melanoma cannot be removed by surgery but remains localized to the original tumor. Stage IVa melanoma has begun to spread away from the original tumor, and stages IVb/c have spread to areas like the nervous and respiratory systems. [9] [https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4519012/pdf/nihms709872.pdf

Development and mechanism of Talimogene Laherparepvec

BioVex Inc., the inventors of T-VEC, were purchased by the company Amgen in 2011 for around $1-billion dollars to develop their breakthrough treatment for melanoma [4]. The BioVex group created T-VEC by genetically engineering human herpes virus 1 (HSV-1) to decrease its pathogenicity for healthy human cells while increasing the viruses ability to attack and kill tumor cells (Figure 1) [4]. The strain of HSV-1 used as a starting block for T-VEC was JS1 which exhibited a greater ability to kill cancer cells in comparison to other natural and engineered strains of herpes virus (Figure 1)[5]. The JS1 strain of HSV-1 was genetically engineered by having its copies of the genes containing neurovirulence factors ICP34.5 and ICP47 deleted (Figure 1)[5]. Neurovirulence factors give HSV-1the ability to cause disease in the human nervous system and the removal of those genes improves the safety of the virus. The removal of ICP34.5 specifically lowered the strains neurotoxicity while the removal of ICP47 is associated with an increase of the viruses ability to replicate with in cancer cells, killing them in the process [5]. The deletion of ICP47 is also associated with the upregulation of the gene US11 which increases the viruses ability to replicate within tumors and lyse them [6]. Finally, the gene for granulocyte macrophage colony-stimulating factor (GM-CSF) was inserted to replace the two deleted neurovirulence factors to help increase immune response through the promotion of dendritic cells [6]. Dendritic cells are a part of the adaptive immune system and help signal immune responses by creating antigens that will signal the presence of cancerous cells to the human body. GM-CSF increases the ability of T-VEC to treat distal tumors not directly injected with the virus [7]. The increased expression of US11 helps increase the tumor specific replication of viruses [7]. None of the alterations done by the BioVex group made T-VEC resistant to common antiviral drugs available such as acylclovir, which can be used to treat HSV-1 [5]. This gives doctors the ability to treat for a viral infection if something were to go wrong with T-VEC in a patient. The mechanism of T-VEC is to selectively replicate within tumor cells and lyse them (Figure 2)[4]. Once the virus lyses a tumor cell many viral particles and tumor antigens will be released into the surrounding tumor and inducing a strong immune response against the tumor by signaling to the adaptive immune system which can fight cancerous cells (Figure 2)[5]. As the virus directly kills and lyses cancer cells, it spreads itself even further into the tumor by releasing copies of its self-made within the cancer cells, increasing its own effectiveness [5]. The reason viruses can selectively enter cancerous cells is because they have mutated so much that they have lost their antiviral defense mechanisms [4].

Section 3

Include some current research, with at least one figure showing data.

Section 4

Conclusion

References


[1]Skin Cancer Foundation. Retrieved April 17, 2018, from https://www.skincancer.org/skin-cancer-information/melanoma

[2]Melanoma Treatment (PDQ®)-Patient Version. Retrieved April 18, 2018, from https://www.cancer.gov/types/skin/patient/melanoma-treatment-pdq

[3]Benefits of Cancer Immunotherapy. Retrieved April 24, 2018, from https://cancerresearch.org/immunotherapy/why-immunotherapy

[4] Dolgin, E. (2015). Oncolytic viruses get a boost with first FDA-approval recommendation. Nature Reviews Drug Discovery, 14(6), 369-371. doi:10.1038/nrd4643

[5] Pol, J., Kroemer, G., & Galluzzi, L. (2016). First oncolytic virus approved for melanoma immunotherapy. Oncoimmuneology, 5(1), e1115641 (3 pages)

[6]Liu, B. L., Robinson, M., Han, Z., Branston, R. H., English, C., Reay, P., & ... Coffin, R. S. (2003). ICP34.5 deleted herpes simplex virus with enhanced oncolytic, immune stimulating, and anti-tumour properties. Gene Therapy, 10(4), 292.

[7] Hu, J. C., Coffin, R. S., Davis, C. J., Graham, N. J., Groves, N., Guest, P. J., ... & Medley, L. C. (2006). A phase I study of OncoVEXGM-CSF, a second-generation oncolytic herpes simplex virus expressing granulocyte macrophage colony-stimulating factor. Clinical cancer research, 12(22), 6737-6747.


[8] Senzer, N. N., Kaufman, H. L., Amatruda, T., Nemunaitis, M., Reid, T., Daniels, G., ... & Goldsweig, H. (2009). Phase II clinical trial of a granulocyte-macrophage colony-stimulating factor-encoding, second-generation oncolytic herpesvirus in patients with unresectable metastatic melanoma. Journal of Clinical Oncology, 27(34), 5763-5771.

[9] Korn, E. L., Liu, P. Y., Lee, S. J., Chapman, J. A. W., Niedzwiecki, D., Suman, V. J., ... & Parulekar, W. (2008). Meta-analysis of phase II cooperative group trials in metastatic stage IV melanoma to determine progression-free and overall survival benchmarks for future phase II trials. Journal of Clinical Oncology, 26(4), 527-534.

[10] Johnson, D. B., Puzanov, I., & Kelley, M. C. (2015). Talimogene laherparepvec (T-VEC) for the treatment of advanced melanoma. Immunotherapy, 7(6), 611-619.

[11] Puzanov, I., Milhem, M. M., Minor, D., Hamid, O., Li, A., Chen, L., ... & Kaufman, H. L. (2016). Talimogene laherparepvec in combination with ipilimumab in previously untreated, unresectable stage IIIB-IV melanoma. Journal of Clinical Oncology, 34(22), 2619-2626.





Authored for BIOL 238 Microbiology, taught by Joan Slonczewski, 2018, Kenyon College.