GATM: A Protein Involved in Various Cellular Processes (G2628)
GATM: A Protein Involved in Various Cellular Processes
GATM (GATA-conserved transmembrane protein) is a gene that encodes a protein that is expressed in various tissues and cells throughout the body. The protein is involved in a variety of cellular processes, including cell signaling, chromosome structure, and DNA replication. GATM is also known as GATM variant 1, and it is a protein that is expressed in many tissues and cells throughout the body, including the brain, heart, liver, and muscle.
GATM is a transmembrane protein, which means that it spans the cell membrane and is expressed in the cell's membrane. This allows the protein to interact with other proteins and molecules that are on the outside of the cell. GATM is also a G protein-coupled receptor, which means that it is a protein that is involved in a signaling pathway that involves the interaction between proteins and other molecules.
GATM is involved in a variety of cellular processes that are important for the proper functioning of the body. For example, GATM is involved in the regulation of cell signaling, which is important for the development and maintenance of tissues and organs. GATM is also involved in the regulation of cell growth and differentiation, which is important for the development and maintenance of tissues and organs.
GATM is also involved in the regulation of DNA replication, which is important for the proper functioning of the immune system. GATM is involved in the regulation of DNA replication in order to ensure that the DNA of the cell is replicated accurately and completely. This is important for the development and maintenance of tissues and organs, as well as for the proper functioning of the immune system.
In addition to its role in cell signaling and DNA replication, GATM is also involved in the regulation of cell adhesion. GATM helps to regulate the stickiness of cells to other cells, which is important for the development and maintenance of tissues and organs. GATM is also involved in the regulation of cell migration, which is important for the formation of tissues and organs during development.
GATM is also involved in the regulation of the release of neurotransmitters, which is important for the proper functioning of the nervous system. GATM is involved in the regulation of the release of neurotransmitters, which are important for transmitting signals between neurons.
GATM is also involved in the regulation of pain perception, which is important for the proper functioning of the endocervical nervous system. GATM is involved in the regulation of pain perception, which is important for the development and maintenance of tissues and organs.
In conclusion, GATM is a protein that is involved in a variety of cellular processes that are important for the proper functioning of the body. GATM is a transmembrane protein that is expressed in many tissues and cells throughout the body, including the brain, heart, liver, and muscle. GATM is also a G protein-coupled receptor and is involved in the regulation of cell signaling, cell growth and differentiation, DNA replication, cell adhesion, neurotransmitter release, and pain perception. Therefore, GATM is a potential drug target and may be useful for the development of new treatments for a variety of diseases.
Protein Name: Glycine Amidinotransferase
Functions: Catalyzes the biosynthesis of guanidinoacetate, the immediate precursor of creatine. Creatine plays a vital role in energy metabolism in muscle tissues. May play a role in embryonic and central nervous system development. May be involved in the response to heart failure by elevating local creatine synthesis
The "GATM 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 GATM 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
More Common Targets
GATOR1 Complex | GAU1 | GBA1 | GBA2 | GBA3 | GBAP1 | GBE1 | GBF1 | GBGT1 | GBP1 | GBP1P1 | GBP2 | GBP3 | GBP4 | GBP5 | GBP6 | GBP7 | GBX1 | GBX2 | GC | GCA | GCAT | GCC1 | GCC2 | GCC2-AS1 | GCDH | GCFC2 | GCG | GCGR | GCH1 | GCHFR | GCK | GCKR | GCLC | GCLM | GCM1 | GCM2 | GCN1 | GCNA | GCNT1 | GCNT1P3 | GCNT2 | GCNT3 | GCNT4 | GCNT7 | GCOM1 | GCSAM | GCSAML | GCSAML-AS1 | GCSH | GCSHP3 | GCSIR | GDA | GDAP1 | GDAP1L1 | GDAP2 | GDE1 | GDF1 | GDF10 | GDF11 | GDF15 | GDF2 | GDF3 | GDF5 | GDF6 | GDF7 | GDF9 | GDI1 | GDI2 | GDI2P1 | GDNF | GDNF Family Receptor alpha | GDNF-AS1 | GDPD1 | GDPD2 | GDPD3 | GDPD4 | GDPD5 | GDPGP1 | GEM | GEMIN2 | GEMIN4 | GEMIN5 | GEMIN6 | GEMIN7 | GEMIN8 | GEMIN8P1 | GEMIN8P4 | GEN1 | general transcription factor IIF (TFIIF) | General transcription factor IIH | Geranylgeranyl transferase | Geranylgeranyl transferase type-1 | GET1 | GET3 | GET4 | GFAP | GFER | GFI1 | GFI1B
