Target Name: Spliceosome Complex
NCBI ID: P17930
Review Report on Spliceosome Complex Target / Biomarker Content of Review Report on Spliceosome Complex Target / Biomarker
Spliceosome Complex
Other Name(s): None

Spliceosome Complex: A Tool for Understanding RNA Splicing

Spliceosome complex is a protein that plays a crucial role in the process of splicing RNA in the nucleus of a cell. It is a complex structure composed of multiple proteins that work together to ensure the accurate and efficient transfer of genetic information from the DNA to the RNA.

The spliceosome complex is made up of four main proteins: splicase 1, splicase 2, splicase 3, and the protein splicelinker. These proteins work together to form a highly specialized machine that can accurately and efficiently transfer the genetic material from the DNA to the RNA.

Splicase 1 is the enzyme that initiates the process of splicing by cutting the DNA at specific sequences. Splicase 2 then takes over and cuts the DNA at the same sequence, creating a trough that the splicelinker can then bind to. Splicase 3 then takes over and adds a specific segment of DNA at the trough to the RNA, and finally, splicelinker binds to the newly formed RNA and helps it to be wrapped into a functional RNA molecule.

The spliceosome complex is a highly specialized machine that is able to accurately and efficiently transfer the genetic material from the DNA to the RNA. However, it is also known to be involved in the regulation of gene expression and has been implicated in a number of diseases , including cancer.

One of the key features of the spliceosome complex is its ability to recognize and bind to specific sequences in the DNA. This allows it to be highly specific in its cutting and joining actions, and ensures that the genetic material is only transferred to the RNA at the intended location.

The spliceosome complex is also able to adapt to changing conditions. For example, when the double-stranded structure of the DNA is interrupted, the spliceosome complex is able to recognize the change and adjust its actions accordingly. This allows it to continue to function even in the presence of DNA damage or other factors that may affect the accuracy of the gene expression.

In addition to its role in the regulation of gene expression, the spliceosome complex is also involved in the development and maintenance of RNA molecules. For example, it is known to play a role in the processing of RNA molecules that are derived from preference for specific classes of RNA molecules, such as microRNAs.

The spliceosome complex is also a potential drug target and has been shown to have a number of potential therapeutic applications. For example, it is known to play a role in the development of certain types of cancer, and may be a useful target for interventions aimed at inhibiting its activity.

In addition to its potential therapeutic applications, the spliceosome complex is also of interest to researchers because of its structure and mechanism. The structure of the spliceosome complex has been studied extensively in order to understand its function and how it works. This has led to a greater understanding of the fundamental principles of splicing and gene expression, and has implications for the study of a wide range of biological processes.

Overall, the spliceosome complex is a complex protein that plays a crucial role in the process of splicing RNA in the nucleus of a cell. Its ability to recognize and bind to specific sequences in the DNA, as well as its adaptability in response to changing conditions , make it an interesting potential drug target and a valuable tool for understanding the fundamental principles of gene expression.

Protein Name: Spliceosome Complex

The "Spliceosome Complex 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 Spliceosome Complex 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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Splicing factor 3A protein complex | Splicing factor 3B protein complex | SPN | SPNS1 | SPNS2 | SPNS3 | SPO11 | SPOCD1 | SPOCK1 | SPOCK2 | SPOCK3 | SPON1 | SPON2 | SPOP | SPOPL | SPOUT1 | SPP1 | SPP2 | SPPL2A | SPPL2B | SPPL2C | SPPL3 | SPR | SPRED1 | SPRED2 | SPRED3 | SPRING1 | SPRN | SPRNP1 | SPRR1A | SPRR1B | SPRR2A | SPRR2B | SPRR2C | SPRR2D | SPRR2E | SPRR2F | SPRR2G | SPRR3 | SPRR4 | SPRTN | SPRY1 | SPRY2 | SPRY3 | SPRY4 | SPRY4-AS1 | SPRY4-IT1 | SPRYD3 | SPRYD4 | SPRYD7 | SPSB1 | SPSB2 | SPSB3 | SPSB4 | SPTA1 | SPTAN1 | SPTB | SPTBN1 | SPTBN2 | SPTBN4 | SPTBN5 | SPTLC1 | SPTLC1P1 | SPTLC2 | SPTLC3 | SPTSSA | SPTSSB | SPTY2D1 | SPX | SPZ1 | SQLE | SQOR | SQSTM1 | SRA1 | SRARP | SRBD1 | SRC | SRCAP | SRCIN1 | SRD5A1 | SRD5A1P1 | SRD5A2 | SRD5A3 | SRD5A3-AS1 | SREBF1 | SREBF2 | SREBF2-AS1 | SREK1 | SREK1IP1 | SRF | SRFBP1 | SRGAP1 | SRGAP2 | SRGAP2B | SRGAP2C | SRGAP2D | SRGAP3 | SRGN | SRI | SRI-AS1