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- Table of Contents
Facts about 3-ketoacyl-CoA thiolase, mitochondrial.
Human | |
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Gene Name: | ACAA2 |
Uniprot: | P42765 |
Entrez: | 10449 |
Belongs to: |
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thiolase-like superfamily |
3-ketoacyl-CoA thiolase, mitochondrial; acetyl-CoA acyltransferase 2; Acetyl-CoA acyltransferase; acetyl-Coenzyme A acyltransferase 2; beta ketothiolase; beta-ketothiolase; DSAEC; EC 2.3.1; EC 2.3.1.16; FLJ35992; FLJ95265; Mitochondrial 3-oxoacyl-CoA thiolase; mitochondrial 3-oxoacyl-Coenzyme A thiolase; T1
Mass (kDA):
41.924 kDA
Human | |
---|---|
Location: | 18q21.1 |
Sequence: | 18; NC_000018.10 (49782164..49813533, complement) |
Mitochondrion.
Here are some examples of ACAA2 antibodies that can be used to their full potential. You'll first see how Boster offers high-affinity prima antibodies. Then, you'll learn about Boster's background and their gene infographics. Next, you will learn about Boster’s high-affinity prima antibodies, which are often cited in the scientific community. Finally, you will learn about Boster's past.
Boster bio produces high-affinity primaries antibodies. These antibodies are both monoclonal/polyclonal in nature and are well-known for high citation counts and exceptional performance in flow Cytometry. Boster also offers custom service, including BeNeLux delivery. Sanbio can provide more information about their high-affinity prima antibodies. This company specializes in high-affinity primary antibodies for a variety of applications.
Boster Bio also develops primary antibodies and produces ELISA kits as well as research antibodies. These reagents can detect biomarkers in areas such as developmental biology, neurosciences, or inflammation. Many of the immunological reagents from Boster Bio can be purchased at tebu.bio. These antibodies come in a variety of concentrations, from 1 to 1,000,000 dilutions and are optimized for IHC and WB.
Single-cell screening produces high-affinity antibodies, which researchers can identify in a matter weeks. This involves isolating viable b cells from patients or immunized animal. High-throughput single-cell sorting helps isolate high-affinity antibodies within the paired VH/VL antibody genes. Next, they undergo expression and potency testing. The antibody candidates are characterized and purified to meet rigorous quality and safety criteria.
In the most recent study, VHH-72 and CR3022 were found to be neutralizing nanobodies. They are limited in neutralizing activity, but these two antibodies show high affinity for the SARS/CoV-2 receptor binding domain. The results were based upon three independent experiments. They represent the mean half-maximal effectiveness concentrations (MC50s), of each high-affinity antibodies.
The author's name was a common variation of the Anglo-Norman surname. Many names were still in confusion until the introduction of Latin and Norman French languages. Boster's name is just one example. During this time, the names of the literate population in the country changed and became more diverse. Boster's past is a great example of this.
Boster argues throughout that the African-American disability was an integral part of plantation life. Her account describes the struggle and negotiation between plantation owners and disabled individuals. These examples demonstrate the complexity of the relationship between plantation economics and the history of disabled persons. Fett is making a significant contribution to disability studies by doing so. However, her book may be too broad. It would be much more useful to concentrate on specific examples of disability-related history.
Boster's introduction is the beginning of his history. It is divided up into three sections that cover different aspects about slavery in the American South. Boster begins the book telling the story about Tom Wilson, a disabled slave. The slave's tale was retold in abolitionist propaganda. By comparing the plight of disabled fugitives to that of slaves, Boster aims to highlight the difference between the two.
PMID: 8241273 by Abe H., et al. Cloning and sequence analysis of a full length cDNA encoding human mitochondrial 3-oxoacyl-CoA thiolase.
PMID: 15242332 by Aboulaich N., et al. Vectorial proteomics reveal targeting, phosphorylation and specific fragmentation of polymerase I and transcript release factor (PTRF) at the surface of caveolae in human adipocytes.