Target Name: TOR3A
NCBI ID: G64222
Other Name(s): ATP-dependent interferon-responsive protein | ATP-dependant interferon responsive | ATP-dependant interferon response protein 1 | ADIR | FLJ22345 | MGC111104 | torsin family 3 member A | Torsin family 3 member A | TOR3A_HUMAN | ADIR2 | epididymis secretory sperm binding protein | Torsin-3A

TOR3A: A Potential Drug Target and Biomarker for Interferon-Responsive Protein

Abstract:

Interferon-responsive proteins play a crucial role in the regulation of cellular processes, including cell growth, apoptosis, and inflammation. TOR3A, a protein that belongs to the Tor gene family, is a highly conserved interferon-responsive protein that has been identified as a potential drug target and biomarker. In this article, we will discuss the structure and function of TOR3A, its potential as a drug target, and its potential as a biomarker for various diseases.

Introduction:

The interferon pathway is a complex signaling pathway that involves the regulation of cellular processes by the production of intracellular signaling molecules, including interferon. Interferon is a protein that is synthesized from DNA and contains several critical regions, including the amino terminal and C-terminus regions . Interferon is involved in the regulation of cellular processes, including cell growth, apoptosis, and inflammation. TOR3A is a protein that belongs to the Tor gene family and is highly conserved with other interferon-responsive proteins. TOR3A has been identified as a potential drug target and biomarker due to its unique structure and function.

Structure and Function:

TOR3A is a protein that contains 219 amino acids and has a calculated molecular mass of 24.8 kDa. It has a unique molecular structure that consists of a protein domain that contains a single open reading frame (ORF) and a non-coding region that is rich in conserved secondary structure elements, including a helix and a loop. The protein domain of TOR3A consists of a unique N-terminal region that contains a putative nucleotide-binding oligomerization (NBO) domain and a unique C-terminal region that contains a conserved protein-coding region and a putative transmembrane region.

TOR3A is a highly conserved protein that has been identified as a potential drug target due to its unique structure and function. The NBO domain of TOR3A is a unique region that is rich in conserved secondary structure elements and has been identified as a potential drug target due to its ability to interact with small molecules, including inhibitors. The C-terminus region of TOR3A is also a unique region that has been identified as a potential drug target due to its ability to interact with small molecules, including inhibitors.

TOR3A functions as an interferon-responsive protein that is involved in the regulation of cellular processes, including cell growth, apoptosis, and inflammation. TOR3A has been shown to play a role in the regulation of cell growth by inhibiting the activities of the cell growth factors , including the TGF-β pathway. TOR3A has also been shown to play a role in the regulation of cell apoptosis by activating the Bax gene and promoting the formation of apoptotic cells. TOR3A has also been shown to play a role in the regulation of inflammation by promoting the production of pro-inflammatory cytokines.

Potential Drug Target:

TOR3A has been identified as a potential drug target due to its unique structure and function. The NBO domain of TOR3A has been shown to interact with small molecules, including inhibitors, which suggests that TOR3A may be a drug target that can be inhibited by small molecules . The C-terminus region of TOR3A has also been shown to interact with small molecules, including inhibitors, which suggests that TOR3A may be a drug target that can be inhibited by small molecules.

Potential Biomarkers:

TOR3A has been identified as a potential biomarker for various diseases due to its unique structure and function. The NBO domain of TOR3A has been shown to interact with small molecules, including inhibitors, which suggests that TOR3A may be a drug target that can be targeted by small molecules. The C-terminus region of TOR3A has also been shown to interact with small molecules, including inhibitors, which suggests that TOR3A may be a drug target that can be targeted by small molecules.

Conclusion:

TOR3A is a protein that belongs to the Tor gene family and is highly conserved with other interferon-responsive proteins. TOR3A has been identified as a potential drug target and biomarker due to its unique structure and function. The NBO domain of TOR3A has been shown to interact with small molecules, including inhibitors, which suggests that TOR3A may be a drug target that can be inhibited by small molecules. The C-terminus region of TOR3A has also been shown to interact with small molecules, including inhibitors, which suggests that TOR3A may be a drug target that can be inhibited by small molecules. Further studies are needed to confirm the potential of TOR3A as a drug target and biomarker.

Protein Name: Torsin Family 3 Member A

More Common Targets

TOR4A | TOX | TOX2 | TOX3 | TOX4 | TP53 | TP53AIP1 | TP53BP2 | TP53I11 | TP53I13 | TP53I3 | TP53INP1 | TP53INP2 | TP53RK | TP53TG1 | TP53TG3 | TP53TG3HP | TP53TG5 | TP63 | TP73 | TP73-AS1 | TPBG | TPBGL | TPCN1 | TPCN2 | TPD52 | TPD52L1 | TPD52L2 | TPD52L3 | TPGS1 | TPGS2 | TPH1 | TPH2 | TPI1 | TPI1P1 | TPI1P2 | TPI1P3 | TPK1 | TPM1 | TPM2 | TPM3 | TPM3P5 | TPM3P7 | TPM3P9 | TPM4 | TPMT | TPO | TPP1 | TPP2 | TPPP | TPPP2 | TPPP3 | TPR | TPRA1 | TPRG1 | TPRG1-AS1 | TPRG1-AS2 | TPRG1L | TPRKB | TPRN | TPRX1 | TPRXL | TPSAB1 | TPSB2 | TPSD1 | TPSG1 | TPST1 | TPST2 | TPST2P1 | TPT1 | TPT1-AS1 | TPT1P6 | TPT1P8 | TPT1P9 | TPTE | TPTE2 | TPTE2P1 | TPTE2P2 | TPTE2P3 | TPTE2P4 | TPTE2P5 | TPTE2P6 | TPTEP1 | TPTEP2 | TPTEP2-CSNK1E | TPX2 | TRA2A | TRA2B | TRABD | TRABD2A | TRABD2B | TRAC | TRADD | TRAF1 | TRAF2 | TRAF3 | TRAF3IP1 | TRAF3IP2 | TRAF3IP2-AS1 | TRAF3IP3