Niranjan Y Sardesai

Publications (37)146.99 Total impact

• Article: Human papillomavirus therapeutic vaccines: targeting viral antigens as immunotherapy for precancerous disease and cancer.

  Matthew P Morrow, Jian Yan, Niranjan Y Sardesai
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  ABSTRACT: Infections with oncogenic HPV types have the potential to lead to the induction of several types of cancer, notably cervical, vulvar, anal, and head and neck cancer. While prophylactic vaccines are currently available and show high efficacy against the establishment of HPV infection, low rates of initiation and lower rates of completion of the vaccination regimen, as well as the lack of an opportunity to be vaccinated prior to infection, has lead to the development of a patient population for whom no immune-based therapy for infection is available. In the current review the authors examine clinical approaches to HPV-targeted immune therapies, the bulk of which target the regulatory proteins E6 and E7 that are constitutively expressed in HPV-associated cancer cells. Early studies demonstrate a correlation between induction of T-cell responses and clearance of HPV-associated precancerous lesions. The clinical data corroborates these findings and highlight the importance of Th1 skewing. Improvements in our understanding of tumor immunology and development of more potent Th1-directed vaccine platforms make it feasible to foresee a HPV therapeutic vaccine in the coming years.
  Expert Review of Vaccines 03/2013; 12(3):271-83. · 4.25 Impact Factor
• Article: Nonstructural Protein 2 (nsP2) of Chikungunya Virus (CHIKV) Enhances Protective Immunity Mediated by a CHIKV Envelope Protein Expressing DNA Vaccine.

  Huihui Bao, Aarti A Ramanathan, Omkar Kawalakar, Senthil G Sundaram, Colleen Tingey, Charoran B Bian, Nagarajan Muruganandam, Paluru Vijayachari, Niranjan Y Sardesai, David B Weiner, Kenneth E Ugen, Karuppiah Muthumani
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  ABSTRACT: Abstract Chikungunya virus (CHIKV) is an important emerging mosquito-borne alphavirus, indigenous to tropical Africa and Asia. It can cause epidemic fever and acute illness characterized by fever and arthralgias. The epidemic cycle of this infection is similar to dengue and urban yellow fever viral infections. The generation of an efficient vaccine against CHIKV is necessary to prevent and/or control the disease manifestations of the infection. In this report, we studied immune response against a CHIKV-envelope DNA vaccine (pEnv) and the role of the CHIKV nonstructural gene 2 (nsP2) as an adjuvant for the induction of protective immune responses in a relevant mouse challenge model. When injected with the CHIKV pEnv alone, 70% of the immunized mice survived CHIKV challenge, whereas when co-injected with pEnv+pnsP2, 90% of the mice survived viral challenge. Mice also exhibited a delayed onset signs of illness, and a marked decrease in morbidity, suggesting a nsP2 mediated adjuvant effect. Co-injection of the pnsP2 adjuvant with pEnv also qualitatively and quantitatively increased antigen specific neutralizing antibody responses compared to vaccination with pEnv alone. In sum, these novel data imply that the addition of nsP2 to the pEnv vaccine enhances anti-CHIKV-Env immune responses and maybe useful to include in future CHIKV clinical vaccination strategies.
  Viral immunology 02/2013; 26(1):75-83. · 1.78 Impact Factor
• Article: DNA and virus particle vaccination protects against acquisition and confers control of viremia upon heterologous simian immunodeficiency virus challenge.

  Vainav Patel, Rashmi Jalah, Viraj Kulkarni, Antonio Valentin, Margherita Rosati, Candido Alicea, Agneta von Gegerfelt, Wensheng Huang, Yongjun Guan, Brandon F Keele, [......], Georgia D Tomaras, Rama R Amara, Harriet L Robinson, Welkin Johnson, Kate E Broderick, Niranjan Y Sardesai, David J Venzon, Vanessa M Hirsch, Barbara K Felber, George N Pavlakis
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  ABSTRACT: We have previously shown that macaques vaccinated with DNA vectors expressing SIVmac239 antigens developed potent immune responses able to reduce viremia upon high-dose SIVmac251 challenge. To further improve vaccine-induced immunity and protection, we combined the SIVmac239 DNA vaccine with protein immunization using inactivated SIVmac239 viral particles as protein source. Twenty-six weeks after the last vaccination, the animals were challenged intrarectally at weekly intervals with a titrated dose of the heterologous SIVsmE660. Two of DNA-protein coimmunized macaques did not become infected after 14 challenges, but all controls were infected by 11 challenges. Vaccinated macaques showed modest protection from SIVsmE660 acquisition compared with naïve controls (P = 0.050; stratified for TRIM5α genotype). Vaccinees had significantly lower peak (1.6 log, P = 0.0048) and chronic phase viremia (P = 0.044), with 73% of the vaccinees suppressing viral replication to levels below assay detection during the 40-wk follow-up. Vaccine-induced immune responses associated significantly with virus control: binding antibody titers and the presence of rectal IgG to SIVsmE660 Env correlated with delayed SIVsmE660 acquisition; SIV-specific cytotoxic T cells, prechallenge CD4(+) effector memory, and postchallenge CD8(+) transitional memory cells correlated with control of viremia. Thus, SIVmac239 DNA and protein-based vaccine protocols were able to achieve high, persistent, broad, and effective cellular and humoral immune responses able to delay heterologous SIVsmE660 infection and to provide long-term control of viremia. These studies support a role of DNA and protein-based vaccines for development of an efficacious HIV/AIDS vaccine.
  Proceedings of the National Academy of Sciences 01/2013; · 9.68 Impact Factor
• Article: The p40 subunit of IL-12 promotes stabilization and export of the p35 subunit: implications for improved IL-12 cytokine production.

  Rashmi Jalah, Margherita Rosati, Brunda Ganneru, Guy R Pilkington, Antonio Valentin, Viraj Kulkarni, Cristina Bergamaschi, Bhabadeb Chowdhury, Gen-Mu Zhang, Rachel Kelly Beach, Candido Alicea, Kate E Broderick, Niranjan Y Sardesai, George N Pavlakis, Barbara K Felber
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  ABSTRACT: IL-12 is a 70 kDa heterodimeric cytokine composed of the p35 and p40 subunits. To maximize cytokine production from plasmid DNA, molecular steps controlling IL-12p70 biosynthesis at the posttranscriptional and posttranslational levels were investigated. We show that the combination of RNA/codon-optimized gene sequences and fine-tuning of the relative expression levels of the two subunits within a cell resulted in increased production of the IL-12p70 heterodimer. We found that the p40 subunit plays a critical role in enhancing the stability, intracellular trafficking and export of the p35 subunit. This posttranslational regulation mediated by the p40 subunit is conserved in mammals. Based on these findings, dual gene expression vectors were generated producing an optimal ratio of the two subunits, resulting in a ~1 log increase in human, rhesus and murine IL-12p70 production compared to vectors expressing the wild type sequences. Such optimized DNA plasmids also produced significantly higher levels of systemic bioactive IL-12 upon in vivo DNA delivery in mice compared to plasmids expressing the wild type sequences. A single therapeutic injection of an optimized murine IL-12 DNA plasmid showed significantly more potent control of tumor development in the B16 melanoma cancer model in mice. Therefore, the improved IL-12p70 DNA vectors have promising potential for in vivo use as molecular vaccine adjuvants and in cancer immunotherapy.
  Journal of Biological Chemistry 01/2013; · 4.77 Impact Factor
• Article: HIV-1 p24(gag) Derived Conserved Element DNA Vaccine Increases the Breadth of Immune Response in Mice.

  Viraj Kulkarni, Margherita Rosati, Antonio Valentin, Brunda Ganneru, Ashish K Singh, Jian Yan, Morgane Rolland, Candido Alicea, Rachel Kelly Beach, Gen-Mu Zhang, Sylvie Le Gall, Kate E Broderick, Niranjan Y Sardesai, David Heckerman, Beatriz Mothe, Christian Brander, David B Weiner, James I Mullins, George N Pavlakis, Barbara K Felber
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  ABSTRACT: Viral diversity is considered a major impediment to the development of an effective HIV-1 vaccine. Despite this diversity, certain protein segments are nearly invariant across the known HIV-1 Group M sequences. We developed immunogens based on the highly conserved elements from the p24(gag) region according to two principles: the immunogen must (i) include strictly conserved elements of the virus that cannot mutate readily, and (ii) exclude both HIV regions capable of mutating without limiting virus viability, and also immunodominant epitopes located in variable regions. We engineered two HIV-1 p24(gag) DNA immunogens that express 7 highly Conserved Elements (CE) of 12-24 amino acids in length and differ by only 1 amino acid in each CE ('toggle site'), together covering >99% of the HIV-1 Group M sequences. Altering intracellular trafficking of the immunogens changed protein localization, stability, and also the nature of elicited immune responses. Immunization of C57BL/6 mice with p55(gag) DNA induced poor, CD4(+) mediated cellular responses, to only 2 of the 7 CE; in contrast, vaccination with p24CE DNA induced cross-clade reactive, robust T cell responses to 4 of the 7 CE. The responses were multifunctional and composed of both CD4(+) and CD8(+) T cells with mature cytotoxic phenotype. These findings provide a method to increase immune response to universally conserved Gag epitopes, using the p24CE immunogen. p24CE DNA vaccination induced humoral immune responses similar in magnitude to those induced by p55(gag), which recognize the virus encoded p24(gag) protein. The inclusion of DNA immunogens composed of conserved elements is a promising vaccine strategy to induce broader immunity by CD4(+) and CD8(+) T cells to additional regions of Gag compared to vaccination with p55(gag) DNA, achieving maximal cross-clade reactive cellular and humoral responses.
  PLoS ONE 01/2013; 8(3):e60245. · 4.09 Impact Factor
• Article: IL-12 DNA as molecular vaccine adjuvant increases the cytotoxic T cell responses and breadth of humoral immune responses in SIV DNA vaccinated macaques.

  Rashmi Jalah, Vainav Patel, Viraj Kulkarni, Margherita Rosati, Candido Alicea, Brunda Ganneru, Agneta von Gegerfelt, Wensheng Huang, Yongjun Guan, Kate E Broderick, Niranjan Y Sardesai, Celia Labranche, David C Montefiori, George N Pavlakis, Barbara K Felber
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  ABSTRACT: Intramuscular injection of macaques with an IL-12 expression plasmid (0.1 or 0.4 mg DNA/animal) optimized for high level of expression and delivered using in vivo electroporation, resulted in the detection of systemic IL-12 cytokine in the plasma. Peak levels obtained by day 4-5 post injection were paralleled by a rapid increase of IFN-γ, indicating bioactivity of the IL-12 cytokine. Both plasma IL-12 and IFN-γ levels were reduced to basal levels by day 14, indicating a short presence of elevated levels of the bioactive IL-12. The effect of IL-12 as adjuvant together with an SIVmac239 DNA vaccine was further examined comparing two groups of rhesus macaques vaccinated in the presence or absence of IL-12 DNA. The IL-12 DNA-adjuvanted group developed significantly higher SIV-specific cellular immune responses, including IFN-γ (+) Granzyme B (+) T cells, demonstrating increased levels of vaccine-induced T cells with cytotoxic potential, and this difference persisted for 6 mo after the last vaccination. Coinjection of IL-12 DNA led to increases in Gag-specific CD4 (+) and CD4 (+) CD8 (+) double-positive memory T cell subsets, whereas the Env-specific increases were mainly mediated by the CD8 (+) and CD4 (+) CD8 (+) double-positive memory T cell subsets. The IL-12 DNA-adjuvanted vaccine group developed higher binding antibody titers to Gag and mac251 Env, and showed higher and more durable neutralizing antibodies to heterologous SIVsmE660. Therefore, co-delivery of IL-12 DNA with the SIV DNA vaccine enhanced the magnitude and breadth of immune responses in immunized rhesus macaques, and supports the inclusion of IL-12 DNA as vaccine adjuvant.
  Human vaccines & immunotherapeutics. 11/2012; 8(11).
• Article: Vaccination with synthetic constructs expressing cytomegalovirus immunogens is highly T cell immunogenic in mice.

  Devon J Shedlock, Kendra T Talbott, Stephan J Wu, Christine M Wilson, Karuppiah Muthumani, Jean D Boyer, Niranjan Y Sardesai, Sita Awasthi, David B Weiner
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  ABSTRACT: There is no licensed vaccine or cure for human cytomegalovirus (CMV), a ubiquitous β-herpesvirus infecting 60-95% of adults worldwide. Infection can cause congenital abnormalities, result in severe disease in immunocompromised patients, and is a major impediment during successful organ transplantation. In addition, it has been associated with numerous inflammatory diseases and cancers, as well as being implicated in the development of essential hypertension, a major risk factor for heart disease. To date, limited data regarding the identification of immunogenic viral targets has frustrated CMV vaccine development. Based upon promising clinical data suggesting an important role for T cells in protecting against disease in the transplantation setting, we designed a novel panel of highly-optimized synthetic vaccines encoding major CMV proteins and evaluated their immune potential in murine studies. Vaccination induced robust CD8+ and CD4+ T cells of great epitopic breadth as extensively analyzed using a novel modified T cell assay described herein. Together with improved levels of CMV-specific T cells as driven by a vaccine, further immune evaluation of each target is warranted. The present model provides an important tool for guiding future immunization strategies against CMV.
  Human vaccines & immunotherapeutics. 11/2012; 8(11).
• Article: Immunotherapy Against HPV16/18 Generates Potent TH1 and Cytotoxic Cellular Immune Responses.

  Mark L Bagarazzi, Jian Yan, Matthew P Morrow, Xuefei Shen, R Lamar Parker, Jessica C Lee, Mary Giffear, Panyupa Pankhong, Amir S Khan, Kate E Broderick, Christine Knott, Feng Lin, Jean D Boyer, Ruxandra Draghia-Akli, C Jo White, J Joseph Kim, David B Weiner, Niranjan Y Sardesai
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  ABSTRACT: Despite the development of highly effective prophylactic vaccines against human papillomavirus (HPV) serotypes 16 and 18, prevention of cervical dysplasia and cancer in women infected with high-risk HPV serotypes remains an unmet medical need. We report encouraging phase 1 safety, tolerability, and immunogenicity results for a therapeutic HPV16/18 candidate vaccine, VGX-3100, delivered by in vivo electroporation (EP). Eighteen women previously treated for cervical intraepithelial neoplasia grade 2 or 3 (CIN2/3) received a three-dose (intramuscular) regimen of highly engineered plasmid DNA encoding HPV16 and HPV18 E6/E7 antigens followed by EP in a dose escalation study (0.3, 1, and 3 mg per plasmid). Immunization was well tolerated with reports of mild injection site reactions and no study-related serious or grade 3 and 4 adverse events. No dose-limiting toxicity was noted, and pain was assessed by visual analog scale, with average scores decreasing from 6.2/10 to 1.4 within 10 min. Average peak interferon-γ enzyme-linked immunospot magnitudes were highest in the 3 mg cohort in comparison to the 0.3 and 1 mg cohorts, suggesting a trend toward a dose effect. Flow cytometric analysis revealed the induction of HPV-specific CD8(+) T cells that efficiently loaded granzyme B and perforin and exhibited full cytolytic functionality in all cohorts. These data indicate that VGX-3100 is capable of driving robust immune responses to antigens from high-risk HPV serotypes and could contribute to elimination of HPV-infected cells and subsequent regression of the dysplastic process.
  Science translational medicine 10/2012; 4(155):155ra138. · 7.80 Impact Factor
• Article: Optimization of electroporation-enhanced intradermal delivery of DNA vaccine using a minimally invasive surface device.

  Feng Lin, Xuefei Shen, Gleb Kichaev, Janess M Mendoza, Maria Yang, Philip Armendi, Jian Yan, Gary P Kobinger, Alexander Juanito Bello, Amir Khan, Kate Elizabeth Broderick, Niranjan Y Sardesai
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  ABSTRACT: In vivo electroporation (EP) is an efficient non-viral method for enhancing DNA vaccine delivery and immunogenicity in animals and humans. Intradermal (i.d.) delivery of DNA vaccines is an attractive strategy due to the immunocompentancy of skin tissue. We have previously reported a minimally invasive surface i.d. EP device for delivery of prophylactic DNA vaccines. Robust antibody responses could be induced following vaccine delivery via surface EP in several tested animal models. Here we further investigated the optimal EP parameters for efficient delivery of DNA vaccines with a specific emphasis on eliciting cellular immunity in addition to robust humoral responses. In a mouse model using applied voltages of 10 to 100 volts (V), transgene expression of GFP and luciferase increased significantly when voltages as low as 10V were used as compared to DNA injection only. Tissue damage to skin was undetectable using applied voltages of 20V and below. However, inflammation and bruising became apparent at voltages above 40V. Delivery of DNA vaccines encoding influenza virus H5 hemaglutinin (H5HA) and nucleoprotein (NP) of influenza H1N1 at applied voltages of 10 to 100V elicited robust and sustained antibody responses. Additionally, low voltage (5-10V) EP elicited higher and more sustained cellular immune response when compared to the higher voltage (above 20V) EP groups after two immunizations. This data confirms that low voltage EP using the surface EP (SEP) device is capable of efficient delivery of DNA vaccines into the skin while establishing that these parameters are sufficient to elicit both robust and sustainable humoral as well as cellular immune responses without tissue damage. The SEP device functioning at these parameters may have important clinical applications for delivery of prophylactic DNA vaccines against diseases such as HIV, malaria and tuberculosis that require both cellular and humoral immune responses for protection.
  Human gene therapy methods. 06/2012;
• Article: Optimization of electroporation-enhanced intradermal delivery of DNA vaccine using a minimally invasive surface device.

  Feng Lin, Xuefei Shen, Gleb Kichaev, Janess M Mendoza, Maria Yang, Philip Armendi, Jian Yan, Gary P Kobinger, Alexander Bello, Amir S Khan, Kate E Broderick, Niranjan Y Sardesai
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  ABSTRACT: In vivo electroporation (EP) is an efficient nonviral method for enhancing DNA vaccine delivery and immunogenicity in animals and humans. Intradermal delivery of DNA vaccines is an attractive strategy because of the immunocompetence of skin tissue. We have previously reported a minimally invasive surface intradermal EP (SEP) device for delivery of prophylactic DNA vaccines. Robust antibody responses were induced after vaccine delivery via surface EP in several tested animal models. Here we further investigated the optimal EP parameters for efficient delivery of DNA vaccines, with a specific emphasis on eliciting cellular immunity in addition to robust humoral responses. In a mouse model, using applied voltages of 10-100 V, transgene expression of green fluorescent protein and luciferase reporter genes increased significantly when voltages as low as 10 V were used as compared with DNA injection only. Tissue damage to skin was undetectable when voltages of 20 V and less were applied. However, inflammation and bruising became apparent at voltages above 40 V. Delivery of DNA vaccines encoding influenza virus H5 hemagglutinin (H5HA) and nucleoprotein (NP) of influenza H1N1 at applied voltages of 10-100 V elicited robust and sustained antibody responses. In addition, low-voltage (less than 20 V) EP elicited higher and more sustained cellular immune responses when compared with the higher voltage (above 20 V) EP groups after two immunizations. The data confirm that low-voltage EP, using the SEP device, is capable of efficient delivery of DNA vaccines into the skin, and establishes that these parameters are sufficient to elicit both robust and sustainable humoral as well as cellular immune responses without tissue damage. The SEP device, functioning within these parameters, may have important clinical applications for delivery of prophylactic DNA vaccines against diseases such as HIV infection, malaria, and tuberculosis that require both cellular and humoral immune responses for protection.
  Human gene therapy methods. 06/2012; 23(3):157-68.
• Article: Intradermal DNA vaccination enhanced by low-current electroporation improves antigen expression and induces robust cellular and humoral immune responses.

  Natalie A Hutnick, Devin J F Myles, Bernadette Ferraro, Colleen Lucke, Feng Lin, Jian Yan, Kate E Broderick, Amir S Khan, Niranjian Y Sardesai, David B Weiner
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  ABSTRACT: Abstract DNA represents an ideal vaccine platform for HIV and many infectious diseases because of its safety, stability, and ease of manufacture. However, the immunogenicity of DNA vaccines has traditionally been low compared with viral vectors, recombinant protein, and live attenuated vaccines. The immunogenicity of DNA vaccines has been significantly enhanced by delivery with in vivo electroporation. Further improvements now allow electroporation to be performed in the dermis, which could potentially improve patient tolerability and may further enhance immunogenicity. In this study we examined how the current of intradermal vaccination impacts antigen expression, inflammation, and the induction of both humoral and cellular immunity in guinea pigs and nonhuman primates. We observed that a lower (0.1 A) current reduced inflammation and improved antigen expression compared with a 0.2 A current. The improved antigen expression resulted in a trend toward higher cellular immune responses but no impact on HIV- and influenza-specific binding titers. This study highlights the need for optimization of electroporation conditions in vivo in order to balance enhanced plasmid transfection with a loss of expression due to tissue inflammation and necrosis. These results suggest that a lower, 0.1-A current may not only improve patient tolerability but also improve immunogenicity.
  Human gene therapy 05/2012; 23(9):943-50. · 4.20 Impact Factor
• Article: Induction of robust cellular immunity against HPV6 and HPV11 in mice by DNA vaccine encoding for E6/E7 antigen.

  Thomas H Shin, Panyupa Pankhong, Jian Yan, Amir S Khan, Niranjan Y Sardesai, David B Weiner
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  ABSTRACT: Due to the strong relationship between the Human Papillomavirus (HPV) "high-risk" subtypes and cervical cancers, most HPV-related studies have been focusing on the "high-risk" HPV subtypes 16 and 18. However, it has been suggested that the "low-risk" subtypes of HPV, HPV6 and HPV11, are the major cause of recurrent respiratory papillomatosis and genital warts. In addition, HPV 6 and 11 are also associated with otolaryngologic malignancies, carcinoma of the lung, tonsil, larynx and low-grade cervical lesions. Therefore, development of HPV therapeutic vaccines targeting on subtypes 6 and 11 E6 or E7 are in great need. In this report, we describe two novel engineered DNA vaccines that encode HPV 6 and 11 consensus E6/E7 fusion proteins (p6E6E7 and p11E6E7) by utilizing a multi-phase strategy. Briefly, after generating consensus sequences, several modifications were performed to increase the expression of both constructs, including codon/RNA optimization, addition of a Kozak sequence and a highly efficient leader sequence. An endoproteolytic cleavage site was also introduced between E6 and E7 protein for proper protein folding and for better CTL processing. The expressions of both constructs were confirmed by western blot analysis and immunofluorescence assay. Vaccination with these DNA vaccines could elicit robust cellular immune responses. The epitope mapping assay was performed to further characterize the cellular immune responses induced by p6E6E7 and p11E6E7. The HPV 6 and 11 E6 or E7-specific immunodominant and subdominant epitopes were verified, respectively. The intracellular cytokine staining revealed that the magnitude of IFN-γ and TNF-α secretion in antigen-specific CD8(+) cells was significantly enhanced, indicating that the immune responses elicited by p6E6E7 and p11E6E7 was heavily skewed toward driving CD8(+) T cells. Such DNA immunogens are interesting candidates for further studies on HPV 6 and 11-associated diseases.
  Human vaccines & immunotherapeutics. 04/2012; 8(4):470-8.
• Article: An optimized SIV DNA vaccine can serve as a boost for Ad5 and provide partial protection from a high-dose SIVmac251 challenge.

  Natalie A Hutnick, Devin J F Myles, Lauren Hirao, Veronica L Scott, Bernadette Ferraro, Amir S Khan, Mark G Lewis, Christopher J Miller, Andrew J Bett, Danilo Casimiro, Niranjan Y Sardesai, J Joseph Kim, John Shiver, David B Weiner
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  ABSTRACT: One limitation in the development of an improved cellular response needed for an effective HIV-vaccine is the inability to induce robust effector T-cells capable of suppressing a heterologous challenge. To improve cellular immune responses, we examined the ability of an optimized DNA vaccine to boost the cellular immune responses induced by a highly immunogenic Ad5 prime. Five Chinese rhesus macaques received pVax encoding consensus (con) gag/pol/env intramuscularly (IM) with electroporation followed by the Merck Ad5 gag/pol/nef vaccine. A second group of five animals were vaccinated with Merck Ad5 gag/pol/nef followed by pVax gag/pol/env. One year following vaccination, Ad5-prime DNA-boosted monkeys and four unvaccinated controls received an intrarectal challenge with 1000 ID50 SIV(mac)251. The quality and magnitude of the T-cell response was analyzed by ELISpot and polyfunctional flow cytometry. We observed that an Ad5-prime DNA-boost resulted in significantly elevated SIV-specific T-cell responses even compared with animals receiving a DNA-prime Ad5-boost. Ad5 prime DNA boosted animals were capable of suppressing a pathogenic SIV(mac)251 challenge. Peak control correlated with the expansion of HLA-DR(+) CD8(+) T-cells two weeks post-infection. These data illustrate that high optimization of a DNA vaccine can drive of immune responses primed by a robust vector system. This previously unachievable feature of these newly optimized DNAs warrants future studies of this strategy that may circumvent issues of serology associated with viral vector prime-boost systems.
  Vaccine 03/2012; 30(21):3202-8. · 3.77 Impact Factor
• Article: Influenza A vaccines using linear expression cassettes delivered via electroporation afford full protection against challenge in a mouse model.

  Xuefei Shen, Jonas Söderholm, Feng Lin, Gary Kobinger, Alexander Bello, Derek A Gregg, Kate E Broderick, Niranjan Y Sardesai
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  ABSTRACT: Alternative DNA vaccine constructs such as fully synthetic linear expressing cassettes (LECs) offer the advantage of accelerated manufacturing techniques as well as the lack of both antibiotic resistance genes and bacterial contaminants. The speed of manufacture makes LEC technology a possible future vaccination strategy for pandemic influenza outbreaks. Previously, we reported on a novel concept of DNA delivery to dermal tissue by a minimally invasive electroporation (EP) surface device powered using low voltage parameters. This device allows electroporation without penetration of electrodes into the skin. In addition to enhancing the delivery of traditional plasmid DNA vaccines, this device may also offer a safe, tolerable and efficient method to administer LECs. To assess immunogenicity and efficacy of EP-enhanced LEC delivery in mice, we designed and tested two influenza antigens in the form of LEC constructs delivered using the newly developed surface dermal EP device. Strong CTL and antibody responses were induced by the LEC versions of the DNA vaccine. When challenged with A/Canada/AB/RV1532/2009 viruses, mice immunized with LEC encoding the M2 and NP antigens recovered faster than naïve or mice immunized ID without EP. Mice immunized with equal-molar doses of LEC encoding the M2 and NP antigens demonstrated 100% survival following a lethal (100× LD50) challenge of the heterologuos and highly pathogenic H5N1 influenza virus (A/Vietnam/1203/04). These results suggest that influenza DNA vaccines based on LEC technology combined with the surface delivery platform are capable of fully protecting mice in a lethal challenge and the LEC based DNA constructs may serve as viable vaccine candidates.
  Vaccine 03/2012; · 3.77 Impact Factor
• Article: Optimized in vivo transfer of small interfering RNA targeting dermal tissue using in vivo surface electroporation.

  Kate E Broderick, Amy Chan, Feng Lin, Xuefei Shen, Gleb Kichaev, Amir S Khan, Justin Aubin, Tracy S Zimmermann, Niranjan Y Sardesai
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  ABSTRACT: Electroporation (EP) of mammalian tissue is a technique that has been used successfully in the clinic for the delivery of genetic-based vaccines in the form of DNA plasmids. There is great interest in platforms which efficiently deliver RNA molecules such as messenger RNA and small interfering RNA (siRNA) to mammalian tissue. However, the in vivo delivery of RNA enhanced by EP has not been extensively characterized. This paper details the optimization of electrical parameters for a novel low-voltage EP method to deliver oligonucleotides (both DNA and RNA) to dermal tissue in vivo. Initially, the electrical parameters were optimized for dermal delivery of plasmid DNA encoding green fluorescent protein (GFP) using this novel surface dermal EP device. While all investigated parameters resulted in visible transfection, voltage parameters in the 10 V range elicited the most robust signal. The parameters optimized for DNA, were then assessed for translation of successful electrotransfer of siRNA into dermal tissue. Robust tagged-siRNA transfection in skin was detected. We then assessed whether these parameters translated to successful transfer of siRNA resulting in gene knockdown in vivo. Using a reporter gene construct encoding GFP and tagged siRNA targeting the GFP message, we show simultaneous transfection of the siRNA to the skin via EP and the concomitant knockdown of the reporter gene signal. The siRNA delivery was accomplished with no evidence of injection site inflammation or local tissue damage. The minimally invasive low-voltage EP method is thus capable of efficiently delivering both DNA and RNA molecules to dermal tissue in a tolerable manner.
  Molecular therapy. Nucleic acids. 01/2012; 1:e11.
• Article: Hepatitis C virus NS3/NS4A DNA vaccine induces multiepitope T cell responses in rhesus macaques mimicking human immune responses [corrected].

  Krystle A Lang Kuhs, Arielle A Ginsberg, Jian Yan, Roger W Wiseman, Amir S Khan, Niranjan Y Sardesai, David H O'Connor, David B Weiner
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  ABSTRACT: Numerous studies have suggested that an effective hepatitis C virus (HCV) vaccine must induce a strong T helper 1 (Th1) T cell response. While several therapeutic vaccine candidates have shown promise in clinical trials, response rates have been low suggesting that further optimization is important. However, such optimization has been hindered by a lack of a benchmark animal model in which to test vaccine-induced immune responses before clinical evaluation. The goal of this study was to analyze the utility of the rhesus macaque vaccination model in assessing HCV vaccine-induced T cell responses. To test this, we employed the use of a novel HCV genotype 1a/1b consensus DNA vaccine encoding both HCV nonstructural protein 3 (NS3) and nonstructural protein 4A (NS4A) proteins. Following immunization, rhesus macaques mounted HCV-specific responses strikingly similar to those reported in resolving patients, including strong NS3-specific interferon-γ (IFN-γ) responses, robust CD4(+) and CD8(+) T cell proliferation, and induction of polyfunctional T cells. Additionally, fine epitope mapping revealed one animal that mounted a T cell response against a known HCV NS3 human leukocyte antigen A2 (HLA-A2) epitope previously identified in humans. Taken together our findings suggest that the rhesus macaque vaccination model is a useful tool in the evaluation of immune responses induced by HCV immunogens.
  Molecular Therapy 09/2011; 20(3):669-78. · 6.87 Impact Factor
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  Available from: Adrian B Mcdermott

  Article: Enhanced control of pathogenic Simian immunodeficiency virus SIVmac239 replication in macaques immunized with an interleukin-12 plasmid and a DNA prime-viral vector boost vaccine regimen.

  Nicola Winstone, Aaron J Wilson, Gavin Morrow, Cesar Boggiano, Maria J Chiuchiolo, Mary Lopez, Marina Kemelman, Arielle A Ginsberg, Karl Mullen, John W Coleman, [......], Holly Cassamasa, Dawn McBride, Barbara K Felber, George N Pavlakis, Alan Schultz, Michael G Hudgens, C Richter King, Timothy J Zamb, Christopher L Parks, Adrian B McDermott
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  ABSTRACT: DNA priming has previously been shown to elicit augmented immune responses when administered by electroporation (EP) or codelivered with a plasmid encoding interleukin-12 (pIL-12). We hypothesized that the efficacy of a DNA prime and recombinant adenovirus 5 boost vaccination regimen (DNA/rAd5) would be improved when incorporating these vaccination strategies into the DNA priming phase, as determined by pathogenic simian immunodeficiency virus SIVmac239 challenge outcome. The whole SIVmac239 proteome was delivered in 5 separate DNA plasmids (pDNA-SIV) by EP with or without pIL-12, followed by boosting 4 months later with corresponding rAd5-SIV vaccine vectors. Remarkably, after repeated low-dose SIVmac239 mucosal challenge, we demonstrate 2.6 and 4.4 log reductions of the median SIV peak and set point viral loads in rhesus macaques (RMs) that received pDNA-SIV by EP with pIL-12 compared to the median peak and set point viral loads in mock-immunized controls (P < 0.01). In 5 out of 6 infected RMs, strong suppression of viremia was observed, with intermittent "blips" in virus replication. In 2 RMs, we could not detect the presence of SIV RNA in tissue and lymph nodes, even after 13 viral challenges. RMs immunized without pIL-12 demonstrated a typical maximum of 1.5 log reduction in virus load. There was no significant difference in the overall magnitude of SIV-specific antibodies or CD8 T-cell responses between groups; however, pDNA delivery by EP with pIL-12 induced a greater magnitude of SIV-specific CD4 T cells that produced multiple cytokines. This vaccine strategy is relevant for existing vaccine candidates entering clinical evaluation, and this model may provide insights into control of retrovirus replication.
  Journal of Virology 09/2011; 85(18):9578-87. · 5.40 Impact Factor
• Article: Immunogenicity of a novel engineered HIV-1 clade C synthetic consensus-based envelope DNA vaccine.

  Jian Yan, Natasha Corbitt, Panyupa Pankhong, Thomas Shin, Amir Khan, Niranjan Y Sardesai, David B Weiner
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  ABSTRACT: DNA vaccines require significant engineering in order to generate strong CTL responses in both non-human primates and humans. In this study, we designed a clade C env gene (EY3E1-C) to decrease the genetic distances of virus isolates within clade C and focus the induced T cell responses to conserved clade C epitopes. After generating a consensus sequence by analyzing full-length clade C env early transmitter sequences, several modifications were performed to increase the expression of the EY3E1-C, including codon/RNA optimization, addition of Kozak sequence and addition of an IgE leader sequence. We also shortened the V1 and V2 loops to approximate early transmitter isolate sequences and the cytoplasmic tail was truncated to prevent envelope recycling. When studied as a DNA vaccine in Balb/c mice, compared to a primary codon-optimized clade C envelope DNA vaccine (p96ZM651gp140-CD5), this novel construct is up to three times more potent in driving CTL responses. Importantly this construct not only induces stronger cross-reactive cellular responses within clade C, it also induces stronger immune responses against clade B and group M envelope peptide pools than p96ZM651gp140-CD5. Epitope mapping demonstrated that EY3E1-C was able to induce clade C envelope-specific immune responses against 15 peptide pools, clade B envelope-specific immune responses against 19 peptide pools and group M envelope-specific immune responses against 16 peptide pools out of 29, respectively, indicating that a significant increase in the breadth of induced immune responses. The analysis of antibody responses suggested that vaccination of pEY3E1-C could induce a clade C envelope-specific antibody response. The cellular immune responses of pEY3E1-C could be further enhanced when the DNA was delivered by using electroporation (EP). Thus, the synthetic engineered consensus EY3E1-C gene is capable of eliciting stronger and broader CTL responses than primary clade C envelopes. This finding suggests that such synthetic immunogens could be important for examination of their potential as part of an efficient HIV DNA vaccine.
  Vaccine 06/2011; 29(41):7173-81. · 3.77 Impact Factor
• Article: Electroporation delivery of DNA vaccines: prospects for success.

  Niranjan Y Sardesai, David B Weiner
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  ABSTRACT: A number of noteworthy technology advances in DNA vaccines research and development over the past few years have led to the resurgence of this field as a viable vaccine modality. Notably, these include--optimization of DNA constructs; development of new DNA manufacturing processes and formulations; augmentation of immune responses with novel encoded molecular adjuvants; and the improvement in new in vivo delivery strategies including electroporation (EP). Of these, EP mediated delivery has generated considerable enthusiasm and appears to have had a great impact in vaccine immunogenicity and efficacy by increasing antigen delivery upto a 1000 fold over naked DNA delivery alone. This increased delivery has resulted in an improved in vivo immune response magnitude as well as response rates relative to DNA delivery by direct injection alone. Indeed the immune responses and protection from pathogen challenge observed following DNA administration via EP in many cases are comparable or superior to other well studied vaccine platforms including viral vectors and live/attenuated/inactivated virus vaccines. Significantly, the early promise of EP delivery shown in numerous pre-clinical animal models of many different infectious diseases and cancer are now translating into equally enhanced immune responses in human clinical trials making the prospects for this vaccine approach to impact diverse disease targets tangible.
  Current opinion in immunology 06/2011; 23(3):421-9. · 10.88 Impact Factor
• Article: A novel prototype device for electroporation-enhanced DNA vaccine delivery simultaneously to both skin and muscle.

  Feng Lin, Xuefei Shen, Jay R McCoy, Janess M Mendoza, Jian Yan, Steve V Kemmerrer, Amir S Khan, David B Weiner, Kate E Broderick, Niranjan Y Sardesai
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  ABSTRACT: Electroporation (EP) of either muscle or skin has proven to be an efficient method for increasing DNA-based vaccine delivery and immunogenicity in small and large animals. Previous comparative studies in large animals suggest that intramuscular (i.m.) DNA EP delivery appears to favor cellular immunity, while intradermal (i.d.) EP delivery may favor humoral immunity. While current EP devices are primarily designed either for i.m. or i.d. delivery, we developed a novel prototype Dual-Depth Device (DDD) for EP-mediated simultaneous i.d. and i.m. delivery of DNA-based vaccines with an attempt to elicit superior antibody and cellular immune responses. We performed comparisons of DDD EP delivery with standard i.d. EP, standard i.m. EP, and combined delivery of i.d. and i.m. EP at separate sites, for the ability to induce antigen-specific immune responses. In a guinea pig model using a SynCon™ DNA vaccine encoding the influenza virus H5 hemaglutinin (H5HA), vaccination via DDD or combined delivery induced higher antibody titers than via either i.d. or i.m. delivery alone. In a mouse model using a DNA vaccine encoding the nucleoprotein (NP) of influenza H1N1, the resulting trend of antibody responses was similar to that detected in guinea pig study. Importantly, cellular immune responses in the DDD or combined delivery groups were significantly stronger than that in either i.d. or i.m. delivery groups. We conclude that EP-mediated DNA-based vaccine delivery to both skin and muscle is superior to delivery to either tissue alone for induction of antigen-specific antibody and cellular immunity.
  Vaccine 01/2011; 29(39):6771-80. · 3.77 Impact Factor