ACP
Species | Cat.# | Product name | Source (Host) | Tag | Protein Length | Price |
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Potato | ACP-150P | Active Native Potato Acid Phosphatase | Sweet Potato | N/A |
ACP involved in several pathways and played different roles in them. We selected most pathways ACP participated on our site, such as , which may be useful for your reference. Also, other proteins which involved in the same pathway with ACP were listed below. Creative BioMart supplied nearly all the proteins listed, you can search them on our site.
Pathway Name | Pathway Related Protein |
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ACP has several biochemical functions, for example, . Some of the functions are cooperated with other proteins, some of the functions could acted by ACP itself. We selected most functions ACP had, and list some proteins which have the same functions with ACP. You can find most of the proteins on our site.
Function | Related Protein |
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ACP has direct interactions with proteins and molecules. Those interactions were detected by several methods such as yeast two hybrid, co-IP, pull-down and so on. We selected proteins and molecules interacted with ACP here. Most of them are supplied by our site. Hope this information will be useful for your research of ACP.
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Q&As (12)
Ask a questionACP protein is a small protein that is part of a larger enzyme complex called fatty acid synthase that is responsible for the biosynthesis of fatty acids. ACP is synthesized as a precursor protein and then cleaved to form the mature form of the protein.
ACP has several potential biomedical applications, including drug development, biofuel production, and engineering of microbial organisms for the production of value-added compounds. ACP can be used as a target for designing drugs that modulate fatty acid synthesis in bacteria and fungi, which could lead to the discovery of novel antibiotics. Additionally, ACP can be harnessed for the production of biofuels such as bioethanol or biodiesel, which are renewable and environmentally sustainable.
Researchers can use a variety of experimental techniques to study the potential applications of ACP protein, such as genetic engineering, protein engineering, and biochemical assays. Animal and cell models can be used to evaluate the efficacy of ACP protein for specific applications.
While ACP protein is a critical component of the fatty acid synthesis pathway, it is not directly involved in the breakdown of fatty acids for energy production. Therefore, it is unlikely that ACP protein could be used for the treatment of acyl-CoA dehydrogenase deficiency.
ACP is a key component in the biosynthetic pathway of fatty acids that are used as building blocks in the production of biofuels. The ACP is involved in the transfer of acyl intermediates between different fatty acid synthesis enzymes, leading to the production of long-chain fatty acids that can be converted into biofuels such as biodiesel or jet fuel.
The use of ACP in biomedical research and development raises ethical concerns about the potential impact on the environment, agricultural practices, and food security. The use of genetically modified microorganisms for biofuel production raises questions about the potential risks of release into the environment and adverse effects on ecosystems. Additionally, the use of ACP for drug development raises concerns about the accessibility and affordability of novel antibiotics and the potential for overuse and development of antibiotic resistance.
ACP protein has a unique three-dimensional structure that is essential for its role in fatty acid synthesis. It has a phosphopantetheine arm that can carry acyl groups and a central hydrophobic cavity where these acyl groups can be extended during the fatty acid synthesis process.
Researchers study the function of ACP protein using biochemical and biophysical techniques, such as X-ray crystallography, NMR spectroscopy, and mass spectrometry. They also use genetic and molecular biology approaches to study the effects of ACP manipulation on cellular processes.
Fatty acid synthesis is a critical process for plant growth and development. By targeting ACP protein, herbicides could disrupt this process and inhibit plant growth, making it a potential target for herbicides.
Dysfunction of ACP protein has been linked to a rare genetic disorder called "acyl-CoA dehydrogenase deficiency," which is characterized by an inability to break down fatty acids for energy production. Additionally, ACP overexpression has been implicated in the development of some types of cancer, such as breast cancer.
ACP can be engineered to improve biofuel production by modifying its specificity towards different fatty acid precursors or modifying its binding affinity towards central enzymes in the fatty acid synthesis pathway. This can ultimately lead to the production of biofuels with improved properties such as higher energy content or lower freezing point.
There is ongoing research into other potential applications of ACP protein, including its use in biofuels production, as a target for herbicides, and as a marker for cancer detection.
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