Target Name: FYB1
NCBI ID: G2533
Review Report on FYB1 Target / Biomarker Content of Review Report on FYB1 Target / Biomarker
FYB1
Other Name(s): FYB | FYN-binding protein 1 | SLAP130 | THC3 | FYN-binding protein 1 (isoform 1) | PRO0823 | FYB-120/130 | FYB1 variant 1 | FYN-T-binding protein | FYN binding protein 1, transcript variant 1 | FYN-binding protein 1 (isoform 3) | SLAP-130 | ADAP | p120/p130 | Adhesion and degranulation promoting adaptor protein | FYN binding protein 1 | FYB1 variant 3 | adhesion and degranulation-promoting adaptor protein | SLP-76-associated phosphoprotein | FYN binding protein 1, transcript variant 3 | FYB1_HUMAN | Adhesion and degranulation-promoting adaptor protein

Discovering The Multi-Functional Protein FYB1: Potential Drug Targets

FYB1 (FYB1) is a protein that has multiple functions in organisms. FYB1 plays a key role in various physiological processes such as cell signaling, cell cycle regulation, apoptosis, immune response, and metabolism. In recent years, researchers have conducted in-depth research on the function of FYB1 and also discovered the important value of FYB1 in the field of drug research and development. This article will discuss FYB1 from multiple aspects and explore the potential and challenges of FYB1 as a drug target.

Structure and function of FYB1

FYB1 is a short-tail fragment protein consisting of 114 amino acids. Its molecular weight is 17.95 kDa and it has rich conserved domains. FYB1 has a variety of features including:

1. Participate in cell signaling

FYB1 is a key molecule in cell signaling networks. In neurons, FYB1 is involved in many signaling processes, such as the release of neurotransmitters and the generation of action potentials. Studies have shown that the function of FYB1 mainly depends on its unique conserved domain. These domains can form a highly active charge site of FYB1, thereby attracting other proteins to bind to it and participate in signal transduction.

2. Regulation of cell cycle

FYB1 plays an important role in cell cycle regulation. Studies have shown that FYB1 can bind to tubulin, thereby preventing spindle advancement and delaying the cell cycle. In addition, FYB1 can also inhibit the formation of the mitotic spindle, resulting in the failure of chromosome separation and increasing the risk of chromosomal abnormalities. These findings provide important clues for studying the role of FYB1 in cell cycle regulation.

3. Participate in cell apoptosis

Apoptosis is an important way of cell death and plays an important role in the growth and development of organisms. Studies have shown that FYB1 plays an important role in apoptosis. FYB1 can bind to apoptosis-related proteins, thereby promoting apoptosis. These findings provide important clues for studying the role of FYB1 in apoptosis.

4. Participate in immune response

FYB1 plays an important role in immune responses. Studies have shown that FYB1 can bind to immunoglobulins and thereby participate in humoral immune responses. In addition, FYB1 can also promote T cell proliferation and activation, thereby participating in cellular immune responses. These findings provide important clues for studying the role of FYB1 in immune responses.

5. Participate in metabolism

FYB1 plays an important role in metabolism. Studies have shown that FYB1 can bind to

Protein Name: FYN Binding Protein 1

Functions: Acts as an adapter protein of the FYN and LCP2 signaling cascades in T-cells (By similarity). May play a role in linking T-cell signaling to remodeling of the actin cytoskeleton (PubMed:10747096, PubMed:16980616). Modulates the expression of IL2 (By similarity). Involved in platelet activation (By similarity). Prevents the degradation of SKAP1 and SKAP2 (PubMed:15849195). May be involved in high affinity immunoglobulin epsilon receptor signaling in mast cells (By similarity)

The "FYB1 Target / Biomarker Review Report" is a customizable review of hundreds up to thousends of related scientific research literature by AI technology, covering specific information about FYB1 comprehensively, including but not limited to:
•   general information;
•   protein structure and compound binding;
•   protein biological mechanisms;
•   its importance;
•   the target screening and validation;
•   expression level;
•   disease relevance;
•   drug resistance;
•   related combination drugs;
•   pharmacochemistry experiments;
•   related patent analysis;
•   advantages and risks of development, etc.
The report is helpful for project application, drug molecule design, research progress updates, publication of research papers, patent applications, etc. If you are interested to get a full version of this report, please feel free to contact us at BD@silexon.ai

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FYB2 | FYCO1 | FYN | FYTTD1 | FZD1 | FZD10 | FZD10-AS1 | FZD2 | FZD3 | FZD4 | FZD4-DT | FZD5 | FZD6 | FZD7 | FZD8 | FZD9 | FZR1 | G protein-Coupled Inwardly-Rectifying Potassium Channel (GIRK) | G Protein-Coupled Receptor Kinases (GRKs) | G0S2 | G2E3 | G2E3-AS1 | G3BP1 | G3BP2 | G6PC1 | G6PC2 | G6PC3 | G6PD | GA-binding protein | GAA | GAB1 | GAB2 | GAB3 | GAB4 | GABA(A) receptor | GABARAP | GABARAPL1 | GABARAPL2 | GABARAPL3 | GABBR1 | GABBR2 | GABPA | GABPAP | GABPB1 | GABPB1-AS1 | GABPB1-IT1 | GABPB2 | GABRA1 | GABRA2 | GABRA3 | GABRA4 | GABRA5 | GABRA6 | GABRB1 | GABRB2 | GABRB3 | GABRD | GABRE | GABRG1 | GABRG2 | GABRG3 | GABRG3-AS1 | GABRP | GABRQ | GABRR1 | GABRR2 | GABRR3 | GACAT1 | GACAT2 | GACAT3 | GAD1 | GAD2 | GADD45A | GADD45B | GADD45G | GADD45GIP1 | GADL1 | GAGE1 | GAGE10 | GAGE12B | GAGE12C | GAGE12D | GAGE12F | GAGE12G | GAGE12H | GAGE12J | GAGE2A | GAGE2B | GAGE2C | GAGE2D | GAGE4 | GAGE5 | GAGE6 | GAGE7 | GAGE8 | GAK | GAL | GAL3ST1 | GAL3ST2 | GAL3ST3