ATP5PF Knockout Cell Lines

Gene: ATP5PF

Official Full Name: ATP synthase peripheral stalk subunit F6provided by HGNC

Gene Summary: Mitochondrial ATP synthase catalyzes ATP synthesis, utilizing an electrochemical gradient of protons across the inner membrane during oxidative phosphorylation. It is composed of two linked multi-subunit complexes: the soluble catalytic core, F1, and the membrane-spanning component, Fo, which comprises the proton channel. The F1 complex consists of 5 different subunits (alpha, beta, gamma, delta, and epsilon) assembled in a ratio of 3 alpha, 3 beta, and a single representative of the other 3. The Fo complex has nine subunits (a, b, c, d, e, f, g, F6 and 8). This gene encodes the F6 subunit of the Fo complex. The F6 subunit is required for F1 and Fo interactions. Alternatively spliced transcript variants encoding different isoforms have been identified for this gene. This gene has 1 or more pseudogenes. [provided by RefSeq, Feb 2016]

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Products Background

Products

Catalog Number	Product Name	Species	Gene	Passage ratio	Mycoplasma testing	Price
KO38879	ATP5PF Knockout cell line (HeLa)	Human	ATP5PF	1:3~1:6	Negative	Online Inquiry
KO38880	ATP5PF Knockout cell line (HCT 116)	Human	ATP5PF	1:2~1:4	Negative	Online Inquiry
KO38881	ATP5PF Knockout cell line (HEK293)	Human	ATP5PF	1:3~1:6	Negative	Online Inquiry
KO38882	ATP5PF Knockout cell line (A549)	Human	ATP5PF	1:3~1:4	Negative	Online Inquiry

Background

ATP5PF Gene Knockout Cell Lines are a specialized biological product designed for advanced research into mitochondrial function and energy metabolism. These cell lines have been genetically engineered to disrupt the ATP5PF gene, which encodes for a component of the ATP synthase complex essential for oxidative phosphorylation. By knocking out this gene, researchers can study the downstream effects on cellular respiration, ATP production, and overall metabolic pathways, providing a valuable tool for understanding cellular energy dynamics.

The primary mechanism of action involves the elimination of ATP5PF expression, resulting in impaired assembly of the ATP synthase complex. This disruption leads to decreased ATP synthesis in response to oxygen, allowing researchers to explore the impact of reduced energy supply on various cellular processes, including proliferation, apoptosis, and disease models. Thus, these knockout cell lines serve as a pivotal resource for elucidating the role of ATP5PF in metabolic disorders, mitochondrial diseases, and aging.

In scientific research and clinical settings, the ATP5PF gene knockout cell lines offer significant advantages over traditional models. Researchers can easily conduct functional assays to assess the metabolic profiles of these cells, providing insights that are crucial for developing therapeutic strategies targeting metabolic dysfunctions. Additionally, the specificity of the knockout approach minimizes off-target effects, resulting in more reliable and reproducible data.

The unique selling point of ATP5PF Gene Knockout Cell Lines lies in their ability to serve as a potent model system for studying mitochondrial dysfunction, enabling researchers to bridge the gap between basic science and clinical application. This product is invaluable for those investigating novel interventions in cancer, neurodegenerative diseases, and metabolic syndromes, as the insights gained can lead to the development of effective therapeutic approaches.

Our company specializes in the development and production of high-quality biological research tools, leveraging years of expertise in genetic modification and cell line technology. We strive to empower researchers with reliable resources that facilitate groundbreaking discoveries and advance the field of molecular biology.

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

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