Your search keyword '"Sridevi Patchva"' showing total 9 results

1. Characteristics of anti-CD19 CAR T cell infusion products associated with efficacy and toxicity in patients with large B cell lymphomas

Author

Nathan Fowler, Yuanxin Wang, Sattva S. Neelapu, Ruiping Wang, Sreejoyee Ghosh, Linghua Wang, Hans C. Lee, Jason R. Westin, Felipe Samaniego, Shaojun Zhang, Enyu Dai, Haopeng Yang, R. Eric Davis, Sridevi Patchva, Paolo Strati, Ryan Sun, Guangchun Han, Minghao Dang, Luis Fayad, Man Chun John Ma, Qi Zhang, Nahum Puebla-Osorio, Qing Deng, Runzhe Chen, Loretta J. Nastoupil, Jordan Showell, Beth Chasen, Neeraj Jain, Frederick B. Hagemeister, and Michael R. Green

Subjects

0301 basic medicine, T-Lymphocytes, T cell, Cell, Population, Immunotherapy, Adoptive, Article, General Biochemistry, Genetics and Molecular Biology, CD19, 03 medical and health sciences, 0302 clinical medicine, Neoplasms, medicine, Humans, Cytotoxic T cell, education, B cell, education.field_of_study, Receptors, Chimeric Antigen, biology, business.industry, Brain, General Medicine, Chimeric antigen receptor, 030104 developmental biology, medicine.anatomical_structure, 030220 oncology & carcinogenesis, Molecular Response, biology.protein, Cancer research, Immunotherapy, Single-Cell Analysis, business

Abstract

Autologous chimeric antigen receptor (CAR) T cell therapies targeting CD19 have high efficacy in large B cell lymphomas (LBCLs), but long-term remissions are observed in less than half of patients, and treatment-associated adverse events, such as immune effector cell-associated neurotoxicity syndrome (ICANS), are a clinical challenge. We performed single-cell RNA sequencing with capture-based cell identification on autologous axicabtagene ciloleucel (axi-cel) anti-CD19 CAR T cell infusion products to identify transcriptomic features associated with efficacy and toxicity in 24 patients with LBCL. Patients who achieved a complete response by positron emission tomography/computed tomography at their 3-month follow-up had three-fold higher frequencies of CD8 T cells expressing memory signatures than patients with partial response or progressive disease. Molecular response measured by cell-free DNA sequencing at day 7 after infusion was significantly associated with clinical response (P = 0.008), and a signature of CD8 T cell exhaustion was associated (q = 2.8 × 10−149) with a poor molecular response. Furthermore, a rare cell population with monocyte-like transcriptional features was associated (P = 0.0002) with high-grade ICANS. Our results suggest that heterogeneity in the cellular and molecular features of CAR T cell infusion products contributes to variation in efficacy and toxicity after axi-cel therapy in LBCL, and that day 7 molecular response might serve as an early predictor of CAR T cell efficacy. Single-cell transcriptomics reveals that the heterogeneity of anti-CD19 CAR T cell infusion products contributes to variability in clinical response, early molecular response and development of immune effector cell-associated neurotoxicity syndrome in patients with large B cell lymphomas.

Published

2020

2. Upsides and Downsides of Reactive Oxygen Species for Cancer: The Roles of Reactive Oxygen Species in Tumorigenesis, Prevention, and Therapy

Author

Wonil Koh, Byoungduck Park, Subash C. Gupta, David Hevia, Bharat B. Aggarwal, and Sridevi Patchva

Subjects

Physiology, Clinical Biochemistry, Inflammation, medicine.disease_cause, Radiation Tolerance, Biochemistry, Neoplasms, medicine, Humans, PTEN, Molecular Biology, Transcription factor, General Environmental Science, chemistry.chemical_classification, Clinical Trials as Topic, Reactive oxygen species, biology, Cancer, Cell Biology, Forum Review Articles, medicine.disease, Cell Transformation, Neoplastic, chemistry, Drug Resistance, Neoplasm, Immunology, STAT protein, biology.protein, Cancer research, General Earth and Planetary Sciences, Tumor necrosis factor alpha, medicine.symptom, Reactive Oxygen Species, Carcinogenesis

Abstract

Significance: Extensive research during the last quarter century has revealed that reactive oxygen species (ROS) produced in the body, primarily by the mitochondria, play a major role in various cell-signaling pathways. Most risk factors associated with chronic diseases (e.g., cancer), such as stress, tobacco, environmental pollutants, radiation, viral infection, diet, and bacterial infection, interact with cells through the generation of ROS. Recent Advances: ROS, in turn, activate various transcription factors (e.g., nuclear factor kappa-light-chain-enhancer of activated B cells [NF-κB], activator protein-1, hypoxia-inducible factor-1α, and signal transducer and activator of transcription 3), resulting in the expression of proteins that control inflammation, cellular transformation, tumor cell survival, tumor cell proliferation and invasion, angiogenesis, and metastasis. Paradoxically, ROS also control the expression of various tumor suppressor genes (p53, Rb, and PTEN). Similarly, γ-radiation and various chemotherapeutic agents used to treat cancer mediate their effects through the production of ROS. Interestingly, ROS have also been implicated in the chemopreventive and anti-tumor action of nutraceuticals derived from fruits, vegetables, spices, and other natural products used in traditional medicine. Critical Issues: These statements suggest both “upside” (cancer-suppressing) and “downside” (cancer-promoting) actions of the ROS. Thus, similar to tumor necrosis factor-α, inflammation, and NF-κB, ROS act as a double-edged sword. This paradox provides a great challenge for researchers whose aim is to exploit ROS stress for the development of cancer therapies. Future Directions: The various mechanisms by which ROS mediate paradoxical effects are discussed in this article. The outstanding questions and future directions raised by our current understanding are discussed. Antioxid. Redox Signal. 16, 1295–1322.

Published

2012

3. Discovery of curcumin, a component of golden spice, and its miraculous biological activities

Author

Subash C. Gupta, Sridevi Patchva, Bharat B. Aggarwal, and Wonil Koh

Subjects

Pharmacology, biology, Physiology, Cell adhesion molecule, business.industry, Kinase, Drug resistance, biology.organism_classification, chemistry.chemical_compound, chemistry, Physiology (medical), Curcumin, Medicine, Animal studies, Curcuma, Receptor, business, Transcription factor

Abstract

1. Curcumin is the active ingredient of the dietary spice turmeric and has been consumed for medicinal purposes for thousands of years. Modern science has shown that curcumin modulates various signalling molecules, including inflammatory molecules, transcription factors, enzymes, protein kinases, protein reductases, carrier proteins, cell survival proteins, drug resistance proteins, adhesion molecules, growth factors, receptors, cell cycle regulatory proteins, chemokines, DNA, RNA and metal ions. 2. Because of this polyphenol's potential to modulate multiple signalling molecules, it has been reported to possess pleiotropic activities. First demonstrated to have antibacterial activity in 1949, curcumin has since been shown to have anti-inflammatory, anti-oxidant, pro-apoptotic, chemopreventive, chemotherapeutic, antiproliferative, wound healing, antinociceptive, antiparasitic and antimalarial properties as well. Animal studies have suggested that curcumin may be active against a wide range of human diseases, including diabetes, obesity, neurological and psychiatric disorders and cancer, as well as chronic illnesses affecting the eyes, lungs, liver, kidneys and gastrointestinal and cardiovascular systems. 3. Although many clinical trials evaluating the safety and efficacy of curcumin against human ailments have already been completed, others are still ongoing. Moreover, curcumin is used as a supplement in several countries, including India, Japan, the US, Thailand, China, Korea, Turkey, South Africa, Nepal and Pakistan. Although inexpensive, apparently well tolerated and potentially active, curcumin has not been approved for the treatment of any human disease. 4. In the present article, we discuss the discovery and key biological activities of curcumin, with a particular emphasis on its activities at the molecular and cellular levels, as well as in animals and humans.

Published

2012

4. Therapeutic Roles of Curcumin: Lessons Learned from Clinical Trials

Author

Sridevi Patchva, Bharat B. Aggarwal, and Subash C. Gupta

Subjects

Peptic Ulcer, Curcumin, Vitiligo, Pharmaceutical Science, Arthritis, Review Article, Pharmacology, Irritable Bowel Syndrome, chemistry.chemical_compound, Diabetes mellitus, Psoriasis, Neoplasms, medicine, Humans, Irritable bowel syndrome, Clinical Trials as Topic, business.industry, medicine.disease, Inflammatory Bowel Diseases, Ulcerative colitis, chemistry, Immunology, Pancreatitis, Oral lichen planus, business

Abstract

Extensive research over the past half century has shown that curcumin (diferuloylmethane), a component of the golden spice turmeric (Curcuma longa), can modulate multiple cell signaling pathways. Extensive clinical trials over the past quarter century have addressed the pharmacokinetics, safety, and efficacy of this nutraceutical against numerous diseases in humans. Some promising effects have been observed in patients with various pro-inflammatory diseases including cancer, cardiovascular disease, arthritis, uveitis, ulcerative proctitis, Crohn's disease, ulcerative colitis, irritable bowel disease, tropical pancreatitis, peptic ulcer, gastric ulcer, idiopathic orbital inflammatory pseudotumor, oral lichen planus, gastric inflammation, vitiligo, psoriasis, acute coronary syndrome, atherosclerosis, diabetes, diabetic nephropathy, diabetic microangiopathy, lupus nephritis, renal conditions, acquired immunodeficiency syndrome, β-thalassemia, biliary dyskinesia, Dejerine-Sottas disease, cholecystitis, and chronic bacterial prostatitis. Curcumin has also shown protection against hepatic conditions, chronic arsenic exposure, and alcohol intoxication. Dose-escalating studies have indicated the safety of curcumin at doses as high as 12 g/day over 3 months. Curcumin's pleiotropic activities emanate from its ability to modulate numerous signaling molecules such as pro-inflammatory cytokines, apoptotic proteins, NF-κB, cyclooxygenase-2, 5-LOX, STAT3, C-reactive protein, prostaglandin E(2), prostate-specific antigen, adhesion molecules, phosphorylase kinase, transforming growth factor-β, triglyceride, ET-1, creatinine, HO-1, AST, and ALT in human participants. In clinical trials, curcumin has been used either alone or in combination with other agents. Various formulations of curcumin, including nanoparticles, liposomal encapsulation, emulsions, capsules, tablets, and powder, have been examined. In this review, we discuss in detail the various human diseases in which the effect of curcumin has been investigated.

Published

2012

5. Tocotrienols, Inflammation, and Cancer

Author

Subash C. Gupta, Sahdeo Prasad, Bokyung Sung, Sridevi Patchva, and Bharat B. Aggarwal

Subjects

business.industry, Cancer research, Medicine, Cancer, Inflammation, medicine.symptom, business, medicine.disease

Published

2012

6. ChemInform Abstract: Multitargeting by Curcumin as Revealed by Molecular Interaction Studies

Author

Lauren J. Webb, Sridevi Patchva, Ji Hye Kim, Bharat B. Aggarwal, Sahdeo Prasad, Subash C. Gupta, and Indira K. Priyadarsini

Subjects

chemistry.chemical_compound, Circular dichroism, Phage display, Förster resonance energy transfer, chemistry, Curcumin, Biophysics, Moiety, General Medicine, Histone deacetylase, Binding site, Macromolecule

Abstract

Covering: up to early 2011 Curcumin (diferuloylmethane), the active ingredient in turmeric (Curcuma longa), is a highly pleiotropic molecule with anti-inflammatory, anti-oxidant, chemopreventive, chemosensitization, and radiosensitization activities. The pleiotropic activities attributed to curcumin come from its complex molecular structure and chemistry, as well as its ability to influence multiple signaling molecules. Curcumin has been shown to bind by multiple forces directly to numerous signaling molecules, such as inflammatory molecules, cell survival proteins, protein kinases, protein reductases, histone acetyltransferase, histone deacetylase, glyoxalase I, xanthine oxidase, proteasome, HIV1 integrase, HIV1 protease, sarco (endo) plasmic reticulum Ca2+ ATPase, DNA methyltransferases 1, FtsZ protofilaments, carrier proteins, and metal ions. Curcumin can also bind directly to DNA and RNA. Owing to its β-diketone moiety, curcumin undergoes keto–enol tautomerism that has been reported as a favorable state for direct binding. The functional groups on curcumin found suitable for interaction with other macromolecules include the α, β-unsaturated β-diketone moiety, carbonyl and enolic groups of the β-diketone moiety, methoxy and phenolic hydroxyl groups, and the phenyl rings. Various biophysical tools have been used to monitor direct interaction of curcumin with other proteins, including absorption, fluorescence, Fourier transform infrared (FTIR) and circular dichroism (CD) spectroscopy, surface plasmon resonance, competitive ligand binding, Forster type fluorescence resonance energy transfer (FRET), radiolabeling, site-directed mutagenesis, matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF MS), immunoprecipitation, phage display biopanning, electron microscopy, 1-anilino-8-naphthalene-sulfonate (ANS) displacement, and co-localization. Molecular docking, the most commonly employed computational tool for calculating binding affinities and predicting binding sites, has also been used to further characterize curcumin's binding sites. Furthermore, the ability of curcumin to bind directly to carrier proteins improves its solubility and bioavailability. In this review, we focus on how curcumin directly targets signaling molecules, as well as the different forces that bind the curcumin–protein complex and how this interaction affects the biological properties of proteins. We will also discuss various analogues of curcumin designed to bind selective targets with increased affinity.

Published

2012

7. Regulation of Inflammation-Mediated Chronic Diseases by Botanicals

Author

Sridevi Patchva, Subash C. Gupta, Bokyung Sung, Sahdeo Prasad, and Bharat B. Aggarwal

Subjects

biology, Wnt signaling pathway, Cancer, Inflammation, Pharmacology, Bioinformatics, medicine.disease, Obesity, Diabetes mellitus, medicine, biology.protein, medicine.symptom, STAT3, Hedgehog, Transcription factor

Abstract

Extensive research over the past several years has indicated a close association between chronic inflammation and chronic diseases. Chronic inflammation has now been shown to be involved in the onset and development of numerous chronic diseases, including cancer, neurological diseases, cardiovascular diseases, hypertension, blood pressure, atherosclerosis, diabetes, obesity, respiratory disorders, musculoskeletal disorders, gastro-intestinal disorders, and autoimmune disorders. An interesting fact that has emerged over the years is that most chronic diseases are caused by lifestyle factors such as stress, toxicants, tobacco, alcohol, infectious agents, and radiation. How chronic inflammation contributes to chronic diseases has also been elucidated over the years. The discovery of transcription factors such as NF-κB, STAT3, AP-1, NRF2, PPAR-γ, β-catenin/Wnt, HIF-1α, and Hedgehog, as well as the signalling molecules regulating these transcription factors has provided a molecular link between chronic inflammation and chronic diseases. Thus agents that can modulate the expression of these transcription factors might be useful against chronic diseases. Because of limited efficacy and high toxicity, mono-targeted anti-inflammatory agents have little effect against chronic diseases. Agents derived from natural sources called botanicals have gained particular attention for their anti-inflammatory activity, not only because they are multi-targeted but also because they are safe, cost effective, and readily available. How transcription factors contribute to the development of chronic diseases is the focus of this review. Additionally, we also describe various botanicals and the inflammatory transcription factors that they modulate.

Published

2012

8. Discovery of curcumin, a component of golden spice, and its miraculous biological activities

Author

Subash C, Gupta, Sridevi, Patchva, Wonil, Koh, and Bharat B, Aggarwal

Subjects

Clinical Trials as Topic, Curcuma, Curcumin, Anti-Inflammatory Agents, Animals, Humans, Inflammation Mediators, Antioxidants, Article, Anti-Bacterial Agents

Abstract

1. Curcumin is the active ingredient of the dietary spice turmeric and has been consumed for medicinal purposes for thousands of years. Modern science has shown that curcumin modulates various signalling molecules, including inflammatory molecules, transcription factors, enzymes, protein kinases, protein reductases, carrier proteins, cell survival proteins, drug resistance proteins, adhesion molecules, growth factors, receptors, cell cycle regulatory proteins, chemokines, DNA, RNA and metal ions. 2. Because of this polyphenol's potential to modulate multiple signalling molecules, it has been reported to possess pleiotropic activities. First demonstrated to have antibacterial activity in 1949, curcumin has since been shown to have anti-inflammatory, anti-oxidant, pro-apoptotic, chemopreventive, chemotherapeutic, antiproliferative, wound healing, antinociceptive, antiparasitic and antimalarial properties as well. Animal studies have suggested that curcumin may be active against a wide range of human diseases, including diabetes, obesity, neurological and psychiatric disorders and cancer, as well as chronic illnesses affecting the eyes, lungs, liver, kidneys and gastrointestinal and cardiovascular systems. 3. Although many clinical trials evaluating the safety and efficacy of curcumin against human ailments have already been completed, others are still ongoing. Moreover, curcumin is used as a supplement in several countries, including India, Japan, the US, Thailand, China, Korea, Turkey, South Africa, Nepal and Pakistan. Although inexpensive, apparently well tolerated and potentially active, curcumin has not been approved for the treatment of any human disease. 4. In the present article, we discuss the discovery and key biological activities of curcumin, with a particular emphasis on its activities at the molecular and cellular levels, as well as in animals and humans.

Published

2011

9. Multitargeting by curcumin as revealed by molecular interaction studies

Author

Ji Hye Kim, Sahdeo Prasad, Lauren J. Webb, Sridevi Patchva, Bharat B. Aggarwal, Subash C. Gupta, and Indira K. Priyadarsini

Subjects

Models, Molecular, Circular dichroism, Curcumin, Plants, Medicinal, Phage display, Molecular Structure, Chemistry, Organic Chemistry, Anti-Inflammatory Agents, Antineoplastic Agents, Biochemistry, Article, Antioxidants, Anti-Bacterial Agents, chemistry.chemical_compound, Förster resonance energy transfer, Drug Discovery, Humans, Moiety, Histone deacetylase, Binding site, Macromolecule

Abstract

Covering: up to early 2011 Curcumin (diferuloylmethane), the active ingredient in turmeric (Curcuma longa), is a highly pleiotropic molecule with anti-inflammatory, anti-oxidant, chemopreventive, chemosensitization, and radiosensitization activities. The pleiotropic activities attributed to curcumin come from its complex molecular structure and chemistry, as well as its ability to influence multiple signaling molecules. Curcumin has been shown to bind by multiple forces directly to numerous signaling molecules, such as inflammatory molecules, cell survival proteins, protein kinases, protein reductases, histone acetyltransferase, histone deacetylase, glyoxalase I, xanthine oxidase, proteasome, HIV1 integrase, HIV1 protease, sarco (endo) plasmic reticulum Ca2+ ATPase, DNA methyltransferases 1, FtsZ protofilaments, carrier proteins, and metal ions. Curcumin can also bind directly to DNA and RNA. Owing to its β-diketone moiety, curcumin undergoes keto–enol tautomerism that has been reported as a favorable state for direct binding. The functional groups on curcumin found suitable for interaction with other macromolecules include the α, β-unsaturated β-diketone moiety, carbonyl and enolic groups of the β-diketone moiety, methoxy and phenolic hydroxyl groups, and the phenyl rings. Various biophysical tools have been used to monitor direct interaction of curcumin with other proteins, including absorption, fluorescence, Fourier transform infrared (FTIR) and circular dichroism (CD) spectroscopy, surface plasmon resonance, competitive ligand binding, Forster type fluorescence resonance energy transfer (FRET), radiolabeling, site-directed mutagenesis, matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF MS), immunoprecipitation, phage display biopanning, electron microscopy, 1-anilino-8-naphthalene-sulfonate (ANS) displacement, and co-localization. Molecular docking, the most commonly employed computational tool for calculating binding affinities and predicting binding sites, has also been used to further characterize curcumin's binding sites. Furthermore, the ability of curcumin to bind directly to carrier proteins improves its solubility and bioavailability. In this review, we focus on how curcumin directly targets signaling molecules, as well as the different forces that bind the curcumin–protein complex and how this interaction affects the biological properties of proteins. We will also discuss various analogues of curcumin designed to bind selective targets with increased affinity.

Published

2011