Your search keyword '"Mehrdad Rajaei"' showing total 8 results

1. AKAP12 Upregulation Associates With PDE8A to Accelerate Cardiac Dysfunction.

Author

Qasim, Hanan, Rajaei, Mehrdad, Xu, Ying, Reyes-Alcaraz, Arfaxad, Abdelnasser, Hala Y., Stewart, M. David, Lahiri, Satadru K., Wehrens, Xander H.T., and McConnell, Bradley K.

Published

2024

2. New Heart Failure Findings from University of Houston Described (Akap12 Upregulation Associates With Pde8a To Accelerate Cardiac Dysfunction).

Subjects

HEART failure, HEART diseases, BETA adrenoceptors, MEMBRANE proteins, ADRENERGIC receptors, ADENOSINES, CYCLIC-AMP-dependent protein kinase

Abstract

A recent study conducted by researchers at the University of Houston explores the role of AKAP12 (A kinase anchoring protein 12) in heart failure. The study found that AKAP12 upregulation is associated with accelerated cardiac dysfunction through the AKAP12-PDE8 axis. The researchers used various methods, including live cell imaging and mouse models, to investigate the effects of AKAP12 on cardiac function. The findings suggest that AKAP12 may be a potential target for pharmacological interventions in heart failure. [Extracted from the article]

Published

2024

3. Discovery of key target for precision pharmacology makes ideal candidate to treat heart failure.

Subjects

HEART failure, PHARMACOLOGY, CONGESTIVE heart failure, HEART diseases, CARDIAC contraction

Abstract

Researchers at the University of Houston College of Pharmacy have discovered that increased levels of a protein called AKAP12 in the heart can accelerate cardiac dysfunction. The researchers found that increased activity of AKAP12 reduces the contractility of cardiac myocytes, the cells responsible for heart contraction. This reduced contractility can be reversed by inhibiting an enzyme called PDE8A, which is located near AKAP12. The researchers suggest that AKAP12 could be a potential target for precision pharmacology in the treatment of heart failure, a condition that affects over 6 million adults in the United States. [Extracted from the article]

Published

2024

4. Targeting MDM2 for novel molecular therapy: Beyond oncology.

Author

Wang, Wei, Qin, Jiang‐Jiang, Rajaei, Mehrdad, Li, Xin, Yu, Xiaoyi, Hunt, Courtney, and Zhang, Ruiwen

Subjects

PATHOLOGY, CARDIOVASCULAR diseases, TREATMENT effectiveness, ANIMAL models in research, ONCOGENES, NON-communicable diseases

Abstract

The murine double minute 2 (MDM2) oncogene exerts major oncogenic activities in human cancers; it is not only the best‐documented negative regulator of the p53 tumor suppressor, but also exerts p53‐independent activities. There is an increasing interest in developing MDM2‐based targeted therapies. Several classes of MDM2 inhibitors have been evaluated in preclinical models, with a few entering clinical trials, mainly for cancer therapy. However, noncarcinogenic roles for MDM2 have also been identified, demonstrating that MDM2 is involved in many chronic diseases and conditions such as inflammation and autoimmune diseases, dementia and neurodegenerative diseases, heart failure and cardiovascular diseases, nephropathy, diabetes, obesity, and sterility. MDM2 inhibitors have been shown to have promising therapeutic efficacy for treating inflammation and other nonmalignant diseases in preclinical evaluations. Therefore, targeting MDM2 may represent a promising approach for treating and preventing these nonmalignant diseases. In addition, a better understanding of how MDM2 works in nonmalignant diseases may provide new biomarkers for their diagnosis, prognostic prediction, and monitoring of therapeutic outcome. In this review article, we pay special attention to the recent findings related to the roles of MDM2 in the pathogenesis of several nonmalignant diseases, the therapeutic potential of its downregulation or inhibition, and its use as a biomarker. [ABSTRACT FROM AUTHOR]

Published

2020

5. STUDENT ABSTRACTS.

Subjects

CERVICAL cancer, DNA, BREAST cancer, NON-small-cell lung carcinoma, CHROMOSOMES

Published

2017

6. Targeting MDM2 for Neuroblastoma Therapy: In Vitro and In Vivo Anticancer Activity and Mechanism of Action.

Author

Wang, Wei, Wang, Xinjie, Rajaei, Mehrdad, Youn, Ji Youn, Zafar, Atif, Deokar, Hemantkumar, Buolamwini, John K., Yang, Jianhua, Foster, Jennifer H., Zhou, Jia, and Zhang, Ruiwen

Subjects

ANIMAL experimentation, ANTINEOPLASTIC agents, TUMOR suppressor genes, BIOLOGICAL models, CELL lines, DRUG efficacy, HETEROCYCLIC compounds, MICE, NEUROBLASTOMA, ONCOGENES, PROTEINS, SAFETY, IN vitro studies, IN vivo studies, CHEMICAL inhibitors, PHARMACODYNAMICS

Abstract

Simple Summary: Neuroblastoma is a malignant tumor of the sympathetic nervous system that causes aggressive disease in children. The overall survival rate of high-risk patients is very low, therefore developing effective and safe therapies for neuroblastoma is an urgent unmet medical need. The mouse double minute 2 (MDM2) homolog gene is amplified and overexpressed in neuroblastoma and contributes to the poor response to treatment and poor prognosis in patients with high-risk neuroblastoma. Therefore, targeting MDM2 provides a promising approach to neuroblastoma therapy, especially for advanced disease. In the present study, we tested a unique MDM2 inhibitor, SP141, for its therapeutic efficacy and safety in neuroblastoma tumor models. We found that SP141 has significant anti- neuroblastoma activity in cell culture and inhibits tumor growth in animal models of human neuroblastoma, without any noticeable host toxicity. These results provide the basis for targeting MDM2 to treat high-risk neuroblastoma. Background: Neuroblastoma is an aggressive pediatric solid tumor with an overall survival rate of <50% for patients with high-risk disease. The majority (>98%) of pathologically-diagnosed neuroblastomas have wild-type p53 with intact functional activity. However, the mouse double minute 2 (MDM2) homolog, an E3 ubiquitin ligase, is overexpressed in neuroblastoma and leads to inhibition of p53. MDM2 also exerts p53-independent oncogenic functions. Thus, MDM2 seems to be an attractive target for the reactivation of p53 and attenuation of oncogenic activity in neuroblastoma. Methods: In this study, we evaluated the anticancer activities and underlying mechanisms of action of SP141, a first-in-class MDM2 inhibitor, in neuroblastoma cell lines with different p53 backgrounds. The findings were confirmed in mouse xenograft models of neuroblastoma. Results: We demonstrate that SP141 reduces neuroblastoma cell viability, induces apoptosis, arrests cells at the G2/M phase, and prevents cell migration, independent of p53. In addition, in neuroblastoma xenograft models, SP141 inhibited MDM2 expression and suppressed tumor growth without any host toxicity at the effective dose. Conclusions: MDM2 inhibition by SP141 results in the inhibition of neuroblastoma growth and metastasis, regardless of the p53 status of the cells and tumors. These findings provide proof-of-concept that SP141 represents a novel treatment option for both p53 wild-type and p53 null neuroblastoma. [ABSTRACT FROM AUTHOR]

Published

2020

7. Targeted Brain Tumor Therapy by Inhibiting the MDM2 Oncogene: In Vitro and In Vivo Antitumor Activity and Mechanism of Action.

Author

Punganuru, Surendra R., Arutla, Viswanath, Zhao, Wei, Rajaei, Mehrdad, Deokar, Hemantkumar, Zhang, Ruiwen, Buolamwini, John K., Srivenugopal, Kalkunte S., and Wang, Wei

Subjects

BRAIN tumors, CENTRAL nervous system tumors, ONCOGENES, TUMOR growth, GLIOBLASTOMA multiforme

Abstract

There is a desperate need for novel and efficacious chemotherapeutic strategies for human brain cancers. There are abundant molecular alterations along the p53 and MDM2 pathways in human glioma, which play critical roles in drug resistance. The present study was designed to evaluate the in vitro and in vivo antitumor activity of a novel brain-penetrating small molecule MDM2 degrader, termed SP-141. In a panel of nine human glioblastoma and medulloblastoma cell lines, SP-141, as a single agent, potently killed the brain tumor-derived cell lines with IC50 values ranging from 35.8 to 688.8 nM. Treatment with SP-141 resulted in diminished MDM2 and increased p53 and p21cip1 levels, G2/M cell cycle arrest, and marked apoptosis. In intracranial xenograft models of U87MG glioblastoma (wt p53) and DAOY medulloblastoma (mutant p53) expressing luciferase, treatment with SP-141 caused a significant 4- to 9-fold decrease in tumor growth in the absence of discernible toxicity. Further, combination treatment with a low dose of SP-141 (IC20) and temozolomide, a standard anti-glioma drug, led to synergistic cell killing (1.3- to 31-fold) in glioma cell lines, suggesting a novel means for overcoming temozolomide resistance. Considering that SP-141 can be taken up by the brain without the need for any special delivery, our results suggest that SP-141 should be further explored for the treatment of tumors of the central nervous system, regardless of the p53 status of the tumor. [ABSTRACT FROM AUTHOR]

Published

2020

8. Two Birds with One Stone: NFAT1-MDM2 Dual Inhibitors for Cancer Therapy †.

Author

Wang, Wei, Zafar, Atif, Rajaei, Mehrdad, and Zhang, Ruiwen

Subjects

CANCER treatment, MEDICAL research, CANCER cells, BIOMOLECULES, T cells, P53 antioncogene

Abstract

The tumor suppressor p53 is believed to be the mostly studied molecule in modern biomedical research. Although p53 interacts with hundreds of molecules to exert its biological functions, there are only a few modulators regulating its expression and function, with murine double minute 2 (MDM2) playing a key role in this regard. MDM2 also contributes to malignant transformation and cancer development through p53-dependent and -independent mechanisms. There is an increasing interest in developing MDM2 inhibitors for cancer prevention and therapy. We recently demonstrated that the nuclear factor of activated T cells 1 (NFAT1) activates MDM2 expression. NFAT1 regulates several cellular functions in cancer cells, such as cell proliferation, migration, invasion, angiogenesis, and drug resistance. Both NFAT isoforms and MDM2 are activated and overexpressed in several cancer subtypes. In addition, a positive correlation exists between NFAT1 and MDM2 in tumor tissues. Our recent clinical study has demonstrated that high expression levels of NFAT1 and MDM2 are independent predictors of a poor prognosis in patients with hepatocellular carcinoma. Thus, inhibition of the NFAT1-MDM2 pathway appears to be a novel potential therapeutic strategy for cancer. In this review, we summarize the potential oncogenic roles of MDM2 and NFAT1 in cancer cells and discuss the efforts of discovery and the development of several newly identified MDM2 and NFAT1 inhibitors, focusing on their potent in vitro and in vivo anticancer activities. This review also highlights strategies and future directions, including the need to focus on the development of more specific and effective NFAT1-MDM2 dual inhibitors for cancer therapy. [ABSTRACT FROM AUTHOR]

Published

2020