Your search keyword '"Chang Ling Sia"' showing total 8 results

1. Table S3 from Exosome Surface Display of IL12 Results in Tumor-Retained Pharmacology with Superior Potency and Limited Systemic Exposure Compared with Recombinant IL12

Author

Sriram Sathyanarayanan, Douglas E. Williams, Kyriakos D. Economides, Scott Estes, Leonid Gaidukov, Michael Doherty, Jorge Sanchez-Salazar, Christine McCoy, Andrew Grube, Adam Boutin, Bryan Choi, Su Chul Jang, Kevin Dooley, Ke Xu, Tong Zi, Gauri Mahimkar, Sonya Haupt, Katherine Kirwin, Chang Ling Sia, and Nuruddeen D. Lewis

Abstract

Reagents and antibodies

Published

2023

2. Data from Exosome Surface Display of IL12 Results in Tumor-Retained Pharmacology with Superior Potency and Limited Systemic Exposure Compared with Recombinant IL12

Author

Sriram Sathyanarayanan, Douglas E. Williams, Kyriakos D. Economides, Scott Estes, Leonid Gaidukov, Michael Doherty, Jorge Sanchez-Salazar, Christine McCoy, Andrew Grube, Adam Boutin, Bryan Choi, Su Chul Jang, Kevin Dooley, Ke Xu, Tong Zi, Gauri Mahimkar, Sonya Haupt, Katherine Kirwin, Chang Ling Sia, and Nuruddeen D. Lewis

Abstract

The promise of IL12 as a cancer treatment has yet to be fulfilled with multiple tested approaches being limited by unwanted systemic exposure and unpredictable pharmacology. To address these limitations, we generated exoIL12, a novel, engineered exosome therapeutic that displays functional IL12 on the surface of an exosome. IL12 exosomal surface expression was achieved via fusion to the abundant exosomal surface protein PTGFRN resulting in equivalent potency in vitro to recombinant IL12 (rIL12) as demonstrated by IFNγ production. Following intratumoral injection, exoIL12 exhibited prolonged tumor retention and greater antitumor activity than rIL12. Moreover, exoIL12 was significantly more potent than rIL12 in tumor growth inhibition. In the MC38 model, complete responses were observed in 63% of mice treated with exoIL12; in contrast, rIL12 resulted in 0% complete responses at an equivalent IL12 dose. This correlated with dose-dependent increases in tumor antigen–specific CD8+ T cells. Rechallenge studies of exoIL12 complete responder mice showed no tumor regrowth, and depletion of CD8+ T cells completely abrogated antitumor activity of exoIL12. Following intratumoral administration, exoIL12 exhibited 10-fold higher intratumoral exposure than rIL12 and prolonged IFNγ production up to 48 hours. Retained local pharmacology of exoIL12 was further confirmed using subcutaneous injections in nonhuman primates. This work demonstrates that tumor-restricted pharmacology of exoIL12 results in superior in vivo efficacy and immune memory without systemic IL12 exposure and related toxicity. ExoIL12 is a novel cancer therapeutic candidate that overcomes key limitations of rIL12 and thereby creates a therapeutic window for this potent cytokine.

Published

2023

3. Supplementary Table 1 from Exosome Surface Display of IL12 Results in Tumor-Retained Pharmacology with Superior Potency and Limited Systemic Exposure Compared with Recombinant IL12

Author

Sriram Sathyanarayanan, Douglas E. Williams, Kyriakos D. Economides, Scott Estes, Leonid Gaidukov, Michael Doherty, Jorge Sanchez-Salazar, Christine McCoy, Andrew Grube, Adam Boutin, Bryan Choi, Su Chul Jang, Kevin Dooley, Ke Xu, Tong Zi, Gauri Mahimkar, Sonya Haupt, Katherine Kirwin, Chang Ling Sia, and Nuruddeen D. Lewis

Abstract

Mean Cytokine Values in Cynomolgus Plasma After Subcutaneous Dosing

Published

2023

4. Supplementary Data Table 2 from Exosome Surface Display of IL12 Results in Tumor-Retained Pharmacology with Superior Potency and Limited Systemic Exposure Compared with Recombinant IL12

Author

Sriram Sathyanarayanan, Douglas E. Williams, Kyriakos D. Economides, Scott Estes, Leonid Gaidukov, Michael Doherty, Jorge Sanchez-Salazar, Christine McCoy, Andrew Grube, Adam Boutin, Bryan Choi, Su Chul Jang, Kevin Dooley, Ke Xu, Tong Zi, Gauri Mahimkar, Sonya Haupt, Katherine Kirwin, Chang Ling Sia, and Nuruddeen D. Lewis

Abstract

Fold-change Cytokine Values in Cynomolgus Plasma After Subcutaneous Dosing

Published

2023

5. Supplementary Figure from Exosome Surface Display of IL12 Results in Tumor-Retained Pharmacology with Superior Potency and Limited Systemic Exposure Compared with Recombinant IL12

Author

Sriram Sathyanarayanan, Douglas E. Williams, Kyriakos D. Economides, Scott Estes, Leonid Gaidukov, Michael Doherty, Jorge Sanchez-Salazar, Christine McCoy, Andrew Grube, Adam Boutin, Bryan Choi, Su Chul Jang, Kevin Dooley, Ke Xu, Tong Zi, Gauri Mahimkar, Sonya Haupt, Katherine Kirwin, Chang Ling Sia, and Nuruddeen D. Lewis

Abstract

Figures S1 through S6

Published

2023

6. 20201229pdtedSupplementaryFigures.pdf from Exosome Surface Display of IL12 Results in Tumor-Retained Pharmacology with Superior Potency and Limited Systemic Exposure Compared with Recombinant IL12

Author

Sriram Sathyanarayanan, Douglas E. Williams, Kyriakos D. Economides, Scott Estes, Leonid Gaidukov, Michael Doherty, Jorge Sanchez-Salazar, Christine McCoy, Andrew Grube, Adam Boutin, Bryan Choi, Su Chul Jang, Kevin Dooley, Ke Xu, Tong Zi, Gauri Mahimkar, Sonya Haupt, Katherine Kirwin, Chang Ling Sia, and Nuruddeen D. Lewis

Abstract

20201229pdtedSupplementaryFigures.pdf from Exosome Surface Display of IL12 Results in Tumor-Retained Pharmacology with Superior Potency and Limited Systemic Exposure Compared with Recombinant IL12

Published

2023

7. Abstract 2150: engEx: A novel exosome engineering platform enabling targeted transfer of pharmacological molecules

Author

Kevin Dooley, Ke Xu, Sonya Haupt, Nuruddeen Lewis, Rane Harrison, Shelly Martin, Christine McCoy, Chang Ling Sia, Su Chul Jang, Katherine Kirwin, Russell McConnell, Bryan Choi, Adam T. Boutin, Damian Houde, Jorge Sanchez-Salazar, Agata Villiger-Oberbek, Kyriakos D. Economides, John D. Kulman, and Sriram Sathyanarayanan

Subjects

Cancer Research, Oncology

Abstract

Exosomes are natural and abundant nanoscale vesicles for intercellular communication, capable of transferring biological instructions between neighboring and distant cell types. Translational research efforts have focused on exploiting this communication mechanism to deliver exogenous pharmacologic payloads to treat a variety of diseases including cancer. Functionalization of the exosome surface with proteins and peptides is an important strategy to maximize the potential of exosomes as therapeutics. Comparative proteomic analysis (LC/MS) of stringently purified exosomes led to the identification of several highly enriched and unique proteins, including a transmembrane glycoprotein (Protein X, PrX), belonging to the immunoglobulin superfamily. Stable expression of PrX in a producer cell line resulted in a 200-fold increase of PrX on the secreted exosomes. Protein X was extensively characterized and the minimum structural requirements for exosome enrichment were determined. With our engExTM platform, we developed precision engineered exosome therapeutics using PrX as a scaffold to enable high-density exosome surface display of an array of structurally and biologically diverse proteins, including enzymes, antibodies, type I cytokines, and TNF superfamily members. These proteins were genetically fused to PrX and overexpressed in a producer cell. Significantly higher transgene expression on secreted exosomes was achieved compared to conventional scaffolds, including the tetraspanins CD9/CD63/CD81 and LAMP2B. Oligomerization of PrX coupled with avidity effects inherent in exosome surface display resulted in a clear activity advantage compared to free protein. Protein X-mediated display of CD40L on exosomes resulted in a 20-fold potency increase in B cell activation over recombinant CD40L. Furthermore, expression of CD40L redirected exosome uptake from phagocytic antigen presenting cells (APCs) to B cells, demonstrating exosome surface modifications can alter cellular tropism. We also evaluated the functionality of IL-12 tethered to the exosome surface and demonstrated superior tumor retention compared to free cytokine, resulting in robust anti-tumor activity in anti-PD-1 refractory B16F10 tumor models. These results demonstrate the potential of the engExTM platform to generate novel exosome therapeutics. Citation Format: Kevin Dooley, Ke Xu, Sonya Haupt, Nuruddeen Lewis, Rane Harrison, Shelly Martin, Christine McCoy, Chang Ling Sia, Su Chul Jang, Katherine Kirwin, Russell McConnell, Bryan Choi, Adam T. Boutin, Damian Houde, Jorge Sanchez-Salazar, Agata Villiger-Oberbek, Kyriakos D. Economides, John D. Kulman, Sriram Sathyanarayanan. engEx: A novel exosome engineering platform enabling targeted transfer of pharmacological molecules [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2019; 2019 Mar 29-Apr 3; Atlanta, GA. Philadelphia (PA): AACR; Cancer Res 2019;79(13 Suppl):Abstract nr 2150.

Published

2019

8. Abstract 944: exoSTING: An engineered exosome therapeutic that selectively delivers STING agonist to the tumor resident antigen-presenting cells resulting in improved tumor antigen-specific adaptive immune response

Author

Kevin Dooley, Rane A. Harrison, Christine McCoy, Chang Ling Sia, Raymond J. Moniz, Damian Houde, Tong Zi, Scott Estes, Ke Xu, Nikki L. Ross, Raymond W. Bourdeau, Kyriakos D. Economides, Sriram Sathyanarayanan, Agata Villiger-Oberbek, Nuruddeen D. Lewis, Jorge Sanchez-Salazar, William K. Dahlberg, and Su Chul Jang

Subjects

0301 basic medicine, Cancer Research, business.industry, medicine.medical_treatment, Acquired immune system, Exosome, eye diseases, Microvesicles, Tumor antigen, 03 medical and health sciences, Sting, 030104 developmental biology, 0302 clinical medicine, Cytokine, Immune system, Oncology, 030220 oncology & carcinogenesis, Cancer research, medicine, Antigen-presenting cell, business

Abstract

Background: The Stimulator of Interferon Genes (STING) pathway is an attractive target in immuno-oncology. Selective activation of the STING pathway in antigen presenting cells (APCs) is essential for eliciting a potent and specific anti-tumor immune response. STING is ubiquitously expressed in normal cells including T cells and endothelial cells. Direct intra-tumoral administration of a free STING agonist results in activation of the STING pathway in all cells, resulting in loss of viability of immune cells, tissue damage, and systemic immune activation due to vascular leakage. Exosomes are an efficient natural messenger system that delivers macromolecules between cells. Leveraging exosome biology, we have developed a novel engineered exosome therapeutic, exoSTING, to selectively target the STING pathway in tumor resident APCs. Results: exoSTING is composed of exosomes engineered to express high levels of Protein X (PrX), a transmembrane glycoprotein naturally occurring on exosomes, and loaded with a STING agonist. Following intra-tumoral injection in checkpoint refractory B16F10 tumors, exoSTING selectively activates STING in APCs, leading to anti-tumor immunity with greater than 100-fold improvement in potency compared to free STING agonist. The activity of exoSTING is substantially diminished in the PrX knock out exosomes, highlighting the importance of this surface glycoprotein for preferential activation of APCs. In contrast to the free STING agonist, exoSTING is retained within the injected tumor, minimizing systemic exposure. Furthermore, exoSTING administration preserves the viability of T cells and APCs, reduces collateral tissue damage, and does not induce systemic cytokine production, resulting in a broader therapeutic window in contrast to free STING agonist. exoSTING produced an increased systemic tumor-specific T cell response as demonstrated by elimination of non-injected abscopal tumors. The specificity of exoSTING activity was demonstrated using a STING knockout mouse (Tmem173gt/J). T cells and myeloid cells play a critical role in exoSTING mediated anti-tumor immunity, in contrast to NK cells which are not required. exoSTING treatment results in significant induction of PD-L1 expression (P Conclusion: exoSTING is an engineered exosome therapeutic that leverages exosome biology and specifically targets the STING pathway in APCs, resulting in greater potency with preserved viability of T cells and APCs, greater systemic tumor antigen specific immune response, reduced systemic cytokine production, and enhanced efficacy. Citation Format: Su Chul Jang, Raymond J. Moniz, Chang Ling Sia, Rane A. Harrison, Damian Houde, Nikki Ross, Ke Xu, Nuruddeen Lewis, Raymond Bourdeau, Christine McCoy, Tong Zi, Agata Villiger-Oberbek, Scott Estes, Jorge Sanchez-Salazar, Kevin Dooley, William K. Dahlberg, Sriram Sathyanarayanan, Kyriakos D. Economides. exoSTING: An engineered exosome therapeutic that selectively delivers STING agonist to the tumor resident antigen-presenting cells resulting in improved tumor antigen-specific adaptive immune response [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2019; 2019 Mar 29-Apr 3; Atlanta, GA. Philadelphia (PA): AACR; Cancer Res 2019;79(13 Suppl):Abstract nr 944.

Published

2019