SLC5A3 Knockout Cell Lines

Gene: SLC5A3

Official Full Name: solute carrier family 5 member 3provided by HGNC

Gene Summary: Enables myo-inositol:sodium symporter activity; potassium channel regulator activity; and transmembrane transporter binding activity. Predicted to be involved in several processes, including inositol metabolic process; monosaccharide transmembrane transport; and myo-inositol import across plasma membrane. Predicted to act upstream of or within several processes, including positive regulation of protein localization to membrane; positive regulation of reactive oxygen species biosynthetic process; and regulation of respiratory gaseous exchange. Located in perinuclear region of cytoplasm and plasma membrane. [provided by Alliance of Genome Resources, Apr 2025]

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Products Background

Products

Catalog Number	Product Name	Species	Gene	Passage ratio	Mycoplasma testing	Price
KO35398	SLC5A3 Knockout cell line (HeLa)	Human	SLC5A3	1:3~1:6	Negative	Online Inquiry
KO35399	SLC5A3 Knockout cell line (HCT 116)	Human	SLC5A3	1:2~1:4	Negative	Online Inquiry
KO35400	SLC5A3 Knockout cell line (HEK293)	Human	SLC5A3	1:3~1:6	Negative	Online Inquiry
KO35401	SLC5A3 Knockout cell line (A549)	Human	SLC5A3	1:3~1:4	Negative	Online Inquiry

Background

SLC5A3 Gene Knockout Cell Lines are specialized cellular models designed to facilitate in-depth functional studies of the SLC5A3 gene, which encodes a sodium-glucose cotransporter critical for the uptake of glucose and other substrates in various cell types. By employing CRISPR-Cas9 gene-editing technology, these cell lines exhibit complete knockout of the SLC5A3 gene, allowing researchers to investigate the gene's role in physiological and pathological conditions without confounding effects from the wild-type allele.

The primary function of the SLC5A3 Gene Knockout Cell Lines lies in their ability to provide a controlled environment for studying the mechanisms underlying glucose metabolism and transport, as well as cellular osmoregulation. Researchers can analyze how the absence of SLC5A3 impacts cellular behavior, including changes in metabolic pathways, ionic balance, and responses to osmotic stimuli. This is particularly valuable in the context of disorders such as diabetes and cystic fibrosis, where glucose handling is significantly altered.

The scientific importance of these cell lines is underscored by their diverse applications in both basic research and clinical settings. They serve as essential tools for drug screening, gene therapy research, and exploration of gene-environment interactions that affect health. By enabling targeted investigations into the molecular mechanisms of disease, SLC5A3 Gene Knockout Cell Lines can lead to the development of novel therapeutic strategies.

Compared to traditional cell lines, which may retain functional copies of the gene, these knockout models offer unparalleled specificity in functional assays and significantly reduce the risk of non-specific effects. Additionally, they are equipped with robust documentation and guidelines to support researchers in their experimental design and data interpretation.

For researchers and clinicians aiming to advance their understanding of glucose transport mechanisms and associated disorders, the SLC5A3 Gene Knockout Cell Lines provide a valuable platform that combines accuracy with versatility. With a commitment to excellence in genetic engineering and cellular sciences, our company stands at the forefront of biotechnological innovation, offering cutting-edge products that empower scientific discovery and clinical advancement.

Please note that all services are for research use only. Not intended for any clinical use.

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