Trans-Resveratrol

Description

Trans-Resveratrol Overview

Trans-Resveratrol is a naturally occurring polyphenolic compound belonging to the stilbene class of phytochemicals. It is the trans geometric isomer of resveratrol, characterized by a planar molecular configuration that contributes to its chemical stability and biological interaction potential in biochemical systems.

Trans-resveratrol is commonly identified in plant-derived sources such as grape skins and certain botanical species, where it functions as a phytoalexin involved in plant defense mechanisms. In laboratory environments, it is used as an investigational compound in biochemical and molecular research.

Scientists examine this molecule to better understand polyphenol-mediated signaling pathways, oxidative stress responses, and intracellular regulatory mechanisms. Because of its well-defined structure and redox-active functional groups, trans-resveratrol is frequently utilized in in vitro studies and experimental research models exploring cellular signaling, enzyme regulation, and transcriptional pathway modulation.

Chemical and Molecular Properties

Property	Value
Compound Name	Trans-Resveratrol
CAS Number	501-36-0
Molecular Formula	C14H12O3
Molecular Weight	228.24 g/mol
Chemical Classification	Stilbene polyphenol
IUPAC Name	5-[(E)-2-(4-hydroxyphenyl)ethenyl]benzene-1,3-diol
Structural Features	Two phenolic rings connected by an ethylene bridge

Working Mechanism

Redox Signaling and Reactive Oxygen Species Regulation

Due to the presence of multiple phenolic groups, trans-resveratrol can participate in redox-related biochemical interactions. In experimental models, researchers study its influence on cellular pathways involved in the regulation of reactive oxygen species (ROS) and redox-sensitive signaling cascades.

Interaction With Enzymatic Signaling Pathways

Laboratory investigations have examined trans-resveratrol in relation to enzyme-mediated regulatory pathways, including interactions with enzymes involved in cellular metabolic signaling. These pathways often include regulatory proteins associated with energy metabolism and intracellular stress-response signaling.

Modulation of Transcriptional Regulatory Networks

Experimental research indicates that trans-resveratrol may influence transcription factors and signaling molecules involved in cellular stress responses and metabolic regulation. These mechanisms are commonly explored through molecular assays designed to analyze changes in gene expression and intracellular signaling behavior.

Cellular Signal Transduction

Within controlled research environments, trans-resveratrol is studied for its potential role in modulating signaling pathways such as:

• AMP-activated protein kinase (AMPK) signaling
  
• Sirtuin-associated regulatory pathways
  
• NF-kB-associated transcriptional signaling

These pathways are widely investigated in experimental models examining cellular stress signaling, metabolic regulation, and intracellular communication mechanisms.

Research Applications of the Product in Laboratory Settings

Oxidative Stress and Redox Biology Research

In in vitro experimental models, trans-resveratrol is commonly used to investigate cellular responses to oxidative stress and to study mechanisms that regulate redox-sensitive signaling pathways.

Cellular Metabolism and Energy Signaling Studies

Researchers incorporate trans-resveratrol into experimental metabolic research models to analyze pathways associated with cellular energy regulation, enzyme activity, and metabolic signaling networks.

Gene Expression and Transcriptional Regulation

Laboratory studies frequently utilize trans-resveratrol to examine transcription factor activation and gene expression regulation in cell-based research systems. These experiments help characterize how polyphenolic molecules influence intracellular signaling cascades.

Molecular Interaction and Polyphenol Research

Trans-resveratrol is also used in structure-activity relationship (SAR) studies that investigate how polyphenolic compounds interact with enzymes, receptors, and regulatory proteins. Such research contributes to a deeper understanding of molecular binding dynamics and biochemical pathway modulation.

Preclinical Experimental Models

In preclinical research models, trans-resveratrol may be used to explore biochemical pathways related to oxidative signaling, metabolic regulation, and intracellular communication mechanisms within controlled laboratory conditions.

Why Choose Purerawz for Trans-Resveratrol?

Buy Trans-Resveratrol for laboratory research use from our online shop. At Purerawz, we provide high-quality reference materials. Each research compound comes with a Certificate of Analysis for verification of purity and concentration.

Disclaimer

This information is for educational purposes only and not medical advice. Products are for research use only. Research must follow IRB or IACUC guidelines. Verify information independently before purchasing. By ordering, you agree to our Terms and Conditions. If you are not 100% satisfied with the product you received, please contact us at support@staging.purerawz.co

Reference Links

• Qureshi, M. A., & Javed, S. (2022). Investigating binding dynamics of trans resveratrol to HSA for an efficient displacement of aflatoxin B1 using spectroscopy and molecular simulation. Scientific Reports, 12(1), 2400. https://doi.org/10.1038/s41598-022-06375-5
• Chiba, T., Kimura, Y., Suzuki, S., Tatefuji, T., & Umegaki, K. (2016). Trans-Resveratrol Enhances the Anticoagulant Activity of Warfarin in a Mouse Model. Journal of Atherosclerosis and Thrombosis, 23(9), 1099-1110. https://doi.org/10.5551/jat.31765