Your search keyword '"Jacob Raiten"' showing total 3 results

1. Mitochondrial metabolism regulation and epigenetics in hypoxia

Author

Madison Laird, Jennifer C. Ku, Jacob Raiten, Sashwat Sriram, Megan Moore, and Yong Li

Subjects

mitochondrial metabolism, epigenetic modifications, hypoxia, gene expression, oxygen, Physiology, QP1-981

Abstract

The complex and dynamic interaction between cellular energy control and gene expression modulation is shown by the intersection between mitochondrial metabolism and epigenetics in hypoxic environments. Poor oxygen delivery to tissues, or hypoxia, is a basic physiological stressor that sets off a series of reactions in cells to adapt and endure oxygen-starved environments. Often called the “powerhouse of the cell,” mitochondria are essential to cellular metabolism, especially regarding producing energy through oxidative phosphorylation. The cellular response to hypoxia entails a change in mitochondrial metabolism to improve survival, including epigenetic modifications that control gene expression without altering the underlying genome. By altering the expression of genes involved in angiogenesis, cell survival, and metabolism, these epigenetic modifications help cells adapt to hypoxia. The sophisticated interplay between mitochondrial metabolism and epigenetics in hypoxia is highlighted by several important points, which have been summarized in the current article. Deciphering the relationship between mitochondrial metabolism and epigenetics during hypoxia is essential to understanding the molecular processes that regulate cellular adaptation to reduced oxygen concentrations.

Published

2024

2. Understanding fibrosis: Mechanisms, clinical implications, current therapies, and prospects for future interventions

Author

Jennifer C. Ku, Jacob Raiten, and Yong Li

Subjects

Fibrosis, Inflammatory, Fibroblasts, Extracellular matrix, Therapeutic strategy, Medical technology, R855-855.5

Abstract

Fibrosis is a prevalent and detrimental condition associated with various diseases with a high impact on global morbidity and mortality rates. Despite its diverse causes and affected organs, common underlying mechanisms drive the development and progression of the disease. These mechanisms include an exaggerated inflammatory response, excessive activation of fibroblasts, and abnormal tissue remodeling following severe or repetitive tissue injury. Although significant advancements have been achieved to enhance our understanding of fibrosis, there is still a gap between identifying potential antifibrotic targets and successfully translating them into effective clinical interventions. Novel approaches that target specific cellular and molecular processes involved in fibrosis hold promise for reducing the pathological consequences of the disease. Understanding the pathogenesis and clinical implications of fibrotic diseases is crucial for developing effective therapeutic strategies and improving patient outcomes. In this review, we introduce the concept of fibrosis, discuss the mechanisms by which it arises, and explore existing and emerging therapeutic approaches in development.

Published

2024

3. Two chemoattenuated PfSPZ malaria vaccines induce sterile hepatic immunity

Author

Sumana Chakravarty, Eric R. James, Stephen L. Hoffman, Lei K. Ding, Jillian Neal, Charles Wyatt, Sahand Kalhori, Anita Manoj, Alemush Imeru, Omely Marte-Salcedo, Sangeeta N. Bhatia, Hope Decederfelt, David M. Cook, Agnes Mwakingwe-Omari, Martha Nason, Jen C. C. Hume, Sara A. Healy, Aarti Kolluri, Natasha Kc, Ijeoma Ikpeama, B. Kim Lee Sim, Peter F. Billingsley, Sean C. Murphy, L. W. Preston Church, Jihyun E. Jeon, Sandra March, Grace K. Lee, Irfan Zaidi, Jacob Raiten, Junhui Duan, Anusha Gunasekera, Thomas L. Richie, Tooba Murshedkar, Jacquelyn Lane, Patrick E. Duffy, and Charles Anderson

Subjects

Adult, Male, 0301 basic medicine, Time Factors, T-Lymphocytes, Plasmodium falciparum, 030231 tropical medicine, Heterologous, Enzyme-Linked Immunosorbent Assay, Vaccines, Attenuated, 03 medical and health sciences, 0302 clinical medicine, Immunity, Chloroquine, Malaria Vaccines, parasitic diseases, medicine, Animals, Humans, Life Cycle Stages, Multidisciplinary, biology, Vaccination, Middle Aged, biology.organism_classification, medicine.disease, Vaccine efficacy, Antibodies, Neutralizing, Virology, Malaria, 030104 developmental biology, Pyrimethamine, Liver, Immunoglobulin G, Antibody Formation, Female, medicine.drug

Abstract

The global decline in malaria has stalled1, emphasizing the need for vaccines that induce durable sterilizing immunity. Here we optimized regimens for chemoprophylaxis vaccination (CVac), for which aseptic, purified, cryopreserved, infectious Plasmodium falciparum sporozoites (PfSPZ) were inoculated under prophylactic cover with pyrimethamine (PYR) (Sanaria PfSPZ-CVac(PYR)) or chloroquine (CQ) (PfSPZ-CVac(CQ))—which kill liver-stage and blood-stage parasites, respectively—and we assessed vaccine efficacy against homologous (that is, the same strain as the vaccine) and heterologous (a different strain) controlled human malaria infection (CHMI) three months after immunization ( https://clinicaltrials.gov/ , NCT02511054 and NCT03083847). We report that a fourfold increase in the dose of PfSPZ-CVac(PYR) from 5.12 × 104 to 2 × 105 PfSPZs transformed a minimal vaccine efficacy (low dose, two out of nine (22.2%) participants protected against homologous CHMI), to a high-level vaccine efficacy with seven out of eight (87.5%) individuals protected against homologous and seven out of nine (77.8%) protected against heterologous CHMI. Increased protection was associated with Vδ2 γδ T cell and antibody responses. At the higher dose, PfSPZ-CVac(CQ) protected six out of six (100%) participants against heterologous CHMI three months after immunization. All homologous (four out of four) and heterologous (eight out of eight) infectivity control participants showed parasitaemia. PfSPZ-CVac(CQ) and PfSPZ-CVac(PYR) induced a durable, sterile vaccine efficacy against a heterologous South American strain of P. falciparum, which has a genome and predicted CD8 T cell immunome that differs more strongly from the African vaccine strain than other analysed African P. falciparum strains. Two malaria vaccines comprising Plasmodium falciparum sporozoites and treatment with either pyrimethamine or chloroquine induced durable protective responses against both the African vaccine strain and a heterologous South American strain of P. falciparum.

Published

2021