Target Name: APOBEC3A
NCBI ID: G200315
Other Name(s): Apolipoprotein B mRNA editing enzyme catalytic subunit 3A, transcript variant 1 | ARP3 | Phorbolin-1 | bK150C2.1 | phorbolin-1 | DNA dC->dU-editing enzyme APOBEC-3A | apolipoprotein B mRNA editing enzyme, catalytic polypeptide-like 3A | probable DNA dC->dU-editing enzyme APOBEC-3A | ABC3A_HUMAN | apolipoprotein B mRNA editing enzyme catalytic subunit 3A | PHRBN | A3A | DNA dC->dU-editing enzyme APOBEC-3A (isoform a) | APOBEC3A variant 1 | APOBEC3A and APOBEC3B deletion hybrid

Unlocking the Potential of APOBEC3A as a Drug Target: A Potential Biomarker for Cardiovascular Disease

Apolipoprotein B mRNA editing enzyme catalytic subunit 3A (APOBEC3A) is a key enzyme in the regulation of apolipoprotein (APOProtein) expression in the body. It is a transmembrane protein that plays a crucial role in the editing of APOBEC mRNAs, which are crucial for the production of functional APOProteins. Mutations in the APOBEC3A gene have been linked to a range of cardiovascular diseases, including cardiovascular disease, cancer, and neurodegenerative diseases.

The search for new drug targets and biomarkers has become a major focus in modern medicine, and APOBEC3A is an attractive candidate due to its central role in the regulation of APOProtein expression. In this article, we will explore the potential of APOBEC3A as a drug target and a biomarker for cardiovascular disease.

APOBEC3A as a Drug Target

The identification of APOBEC3A as a potential drug target comes from several studies that have demonstrated its involvement in various cardiovascular diseases. Several studies have shown that APOBEC3A plays a role in the regulation of APOProtein expression and that it is involved in the development of cardiovascular disease.

One of the key findings of these studies is the role of APOBEC3A in the development of atherosclerosis, a leading cause of cardiovascular disease. Atherosclerosis is the buildup of plaque in the arteries, which can cause a heart attack or stroke. Studies have shown that APOBEC3A is involved in the regulation of plaque formation and that it plays a role in the development of cardiovascular disease.

Another study has shown that APOBEC3A is involved in the regulation of inflammation, a key player in the development of many cardiovascular diseases. Inflammation is the body's natural response to injury or infection, but it can also contribute to the development of cardiovascular disease. Studies have shown that APOBEC3A is involved in the regulation of inflammation and that it plays a role in the development of cardiovascular disease.

APOBEC3A as a Biomarker

The identification of APOBEC3A as a potential biomarker for cardiovascular disease comes from several studies that have demonstrated its involvement in the regulation of APOProtein expression in the body. Studies have shown that APOBEC3A is involved in the regulation of APOProtein expression and that it is a key factor in the production of functional APOProteins.

One of the key findings of these studies is the role of APOBEC3A in the regulation of cardiovascular disease risk factors. Studies have shown that APOBEC3A plays a role in the regulation of several cardiovascular disease risk factors, including blood pressure, cholesterol, and blood sugar levels. These factors are known to contribute to the development of cardiovascular disease, and changes in these factors can increase the risk of cardiovascular disease.

Another study has shown that APOBEC3A is involved in the regulation of the immune response. Studies have shown that APOBEC3A plays a role in the regulation of the immune response and that it is involved in the development of cardiovascular disease. The immune response is the body's natural response to infection, but it can also contribute to the development of cardiovascular disease.

Conclusion

In conclusion, APOBEC3A is a key enzyme in the regulation of APOProtein expression in the body and is involved in the development of cardiovascular disease. The potential of APOBEC3A as a drug target and biomarker for cardiovascular disease makes it an attractive candidate for further research. Further studies are needed to fully understand the role of APOBEC3A in the development of cardiovascular disease and to develop new treatments based on

Protein Name: Apolipoprotein B MRNA Editing Enzyme Catalytic Subunit 3A

More Common Targets

APOBEC3A_B | APOBEC3B | APOBEC3B-AS1 | APOBEC3C | APOBEC3D | APOBEC3F | APOBEC3G | APOBEC3H | APOBEC4 | APOBR | APOC1 | APOC1P1 | APOC2 | APOC3 | APOC4 | APOC4-APOC2 | APOD | APOE | APOF | APOH | APOL1 | APOL2 | APOL3 | APOL4 | APOL5 | APOL6 | APOLD1 | Apolipoprotein B mRNA editing complex | APOM | APOO | APOOL | APOOP2 | APOOP5 | APP | APPAT | APPBP2 | APPL1 | APPL2 | APRG1 | APRT | APTR | APTX | AQP1 | AQP10 | AQP11 | AQP12A | AQP12B | AQP2 | AQP3 | AQP4 | AQP4-AS1 | AQP5 | AQP6 | AQP7 | AQP7P1 | AQP7P2 | AQP7P3 | AQP7P5 | AQP8 | AQP9 | AQR | AR | ARAF | ARAP1 | ARAP1-AS2 | ARAP2 | ARAP3 | ARC | ARCN1 | AREG | AREL1 | ARF1 | ARF3 | ARF4 | ARF5 | ARF6 | ARFGAP1 | ARFGAP2 | ARFGAP3 | ARFGEF1 | ARFGEF2 | ARFGEF3 | ARFIP1 | ARFIP2 | ARFRP1 | ARG1 | ARG2 | ARGFX | ARGFXP2 | Arginase | ARGLU1 | ARHGAP1 | ARHGAP10 | ARHGAP11A | ARHGAP11A-DT | ARHGAP11B | ARHGAP12 | ARHGAP15 | ARHGAP17 | ARHGAP18