SLC2A4: A Potential Drug Target and Biomarker for Glucose Management

SLC2A4: A Potential Drug Target and Biomarker for Glucose Management

Introduction

Glucose is a critical macronutrient that serves as the primary source of energy for the body. The glucose transporter family plays a crucial role in glucose uptake and storage in the body. Glucose transporter type 4 (SLC2A4) is a key member of this family, and Its function in glucose metabolism has been extensively studied. In this article, we will explore the potential implications of SLC2A4 as a drug target and biomarker for glucose management.

SLC2A4: Structure and Function

SLC2A4 is a member of the glucose transporter family, which includes six transporters: SLC2A1, SLC2A2, SLC2A3, SLC2A4, SLC2A5, and SLC2A6. These transporters are expressed in various tissues and cells throughout the body and play a vital role in glucose uptake and storage . SLC2A4 is a 22kDa protein that consists of a transmembrane region and an intracellular domain.

SLC2A4 is primarily expressed in the liver, where it is involved in glucose uptake and storage. The liver is a major site for glucose metabolism, and it is responsible for producing and storing glucose to supply the body's energy needs. SLC2A4 is known to be expressed in the liver cortical tissue and is co-expressed with GLUT1, GLUT2, and GLUT4, which are also known as the GLUT family.

SLC2A4 is involved in the uptake and storage of glucose in the liver. It functions as a glucose transporter, allowing glucose to enter the liver cells via its extracellular domain. Once inside the cell, SLC2A4 is involved in the transporter's catalytic activity, which is essential for its function. SLC2A4 has been shown to promote glucose uptake and storage in the liver, which is critical for maintaining normal blood glucose levels.

SLC2A4 has also been shown to play a role in glucose metabolism outside the liver. For example, studies have shown that SLC2A4 is involved in glucose uptake and storage in muscle cells. This suggests that SLC2A4 may be a potential drug target for treating diabetes, as Muscle cells are often targeted by the disease.

Potential Therapeutic Applications

SLC2A4 has significant potential as a drug target for treating diabetes. Diabetes is a chronic metabolic disorder that is characterized by high blood sugar levels. It is a leading cause of morbidity and mortality, and its impact on the global economy is substantial.

SLC2A4 has been shown to be involved in the uptake and storage of glucose in the liver, which is critical for maintaining normal blood glucose levels. By targeting SLC2A4, researchers may be able to develop new treatments for diabetes that target this protein. This could include drugs that inhibit SLC2A4 function or drugs that modulate its activity to improve insulin sensitivity.

SLC2A4 has also been shown to be involved in glucose uptake and storage in muscle cells. This suggests that SLC2A4 may be a potential drug target for treating muscle-related diseases, such as muscle dystrophy or myopathies.

Biomarker Potential

SLC2A4 is also a potential biomarker for measuring glucose metabolism. The liver is a major site for glucose metabolism, and it is responsible for producing and storing glucose to supply the body's energy needs. By measuring SLC2A4 expression in the liver, researchers may be able to assess glucose metabolism and monitor the effectiveness of potential

Protein Name: Solute Carrier Family 2 Member 4

Functions: Insulin-regulated facilitative glucose transporter, which plays a key role in removal of glucose from circulation. Response to insulin is regulated by its intracellular localization: in the absence of insulin, it is efficiently retained intracellularly within storage compartments in muscle and fat cells. Upon insulin stimulation, translocates from these compartments to the cell surface where it transports glucose from the extracellular milieu into the cell

The "SLC2A4 Target / Biomarker Review Report" is a customizable review of hundreds up to thousends of related scientific research literature by AI technology, covering specific information about SLC2A4 comprehensively, including but not limited to:
•   general information;
•   protein structure and compound binding;
•   protein biological mechanisms;
•   its importance;
•   the target screening and validation;
•   expression level;
•   disease relevance;
•   drug resistance;
•   related combination drugs;
•   pharmacochemistry experiments;
•   related patent analysis;
•   advantages and risks of development, etc.
The report is helpful for project application, drug molecule design, research progress updates, publication of research papers, patent applications, etc. If you are interested to get a full version of this report, please feel free to contact us at BD@silexon.ai

More Common Targets

SLC2A4RG | SLC2A5 | SLC2A6 | SLC2A7 | SLC2A8 | SLC2A9 | SLC2A9-AS1 | SLC30A1 | SLC30A10 | SLC30A2 | SLC30A3 | SLC30A4 | SLC30A4-AS1 | SLC30A5 | SLC30A6 | SLC30A7 | SLC30A8 | SLC30A9 | SLC31A1 | SLC31A2 | SLC32A1 | SLC33A1 | SLC34A1 | SLC34A2 | SLC34A3 | SLC35A1 | SLC35A2 | SLC35A3 | SLC35A4 | SLC35A5 | SLC35B1 | SLC35B2 | SLC35B3 | SLC35B4 | SLC35C1 | SLC35C2 | SLC35D1 | SLC35D2 | SLC35D3 | SLC35E1 | SLC35E1P1 | SLC35E2A | SLC35E2B | SLC35E3 | SLC35E4 | SLC35F1 | SLC35F2 | SLC35F3 | SLC35F4 | SLC35F5 | SLC35F6 | SLC35G1 | SLC35G2 | SLC35G3 | SLC35G4 | SLC35G5 | SLC35G6 | SLC36A1 | SLC36A2 | SLC36A3 | SLC36A4 | SLC37A1 | SLC37A2 | SLC37A3 | SLC37A4 | SLC38A1 | SLC38A10 | SLC38A11 | SLC38A2 | SLC38A3 | SLC38A4 | SLC38A4-AS1 | SLC38A5 | SLC38A6 | SLC38A7 | SLC38A8 | SLC38A9 | SLC39A1 | SLC39A10 | SLC39A11 | SLC39A12 | SLC39A13 | SLC39A14 | SLC39A2 | SLC39A3 | SLC39A4 | SLC39A5 | SLC39A6 | SLC39A7 | SLC39A8 | SLC39A9 | SLC3A1 | SLC3A2 | SLC40A1 | SLC41A1 | SLC41A2 | SLC41A3 | SLC43A1 | SLC43A2 | SLC43A3