Target Name: SPESP1
NCBI ID: G246777
Review Report on SPESP1 Target / Biomarker Content of Review Report on SPESP1 Target / Biomarker
SPESP1
Other Name(s): glycosylated 38 kDa sperm protein C-7/8 | Sperm equatorial segment protein 1 | Equatorial segment protein | Glycosylated 38 kDa sperm protein C-7/8 | SPESP_HUMAN | equatorial segment protein | ESP | SP-ESP | sperm equatorial segment protein 1

SPESP1: A Potential Drug Target and Biomarker for Sperm Function

Sperm are an essential component of the male reproductive system, and their role is crucial for the continuation of life. Sperm are also involved in fertilization and the development of new organisms. The sperm protein C-7/8, also known as SPESP1, plays a vital role in these processes. It is a glycosylated protein that is expressed in high levels in the testes of humans.

SPESP1 is a member of the SPESP family, which includes several other proteins that are involved in sperm function. These proteins are known as sperm-specific proteins (SSPs) and are expressed at different levels in the testes. SPESP1 is one of the most well-known SSPs and is expressed at high levels in the testes of humans.

SPESP1 functions as a protein that is involved in several important processes in sperm. It is involved in the regulation of the association of sperm with eggs and in the process of fertilization. SPESP1 is also involved in the production of acrosulfur compounds, which are toxic to bacteria and other microorganisms that may be present in the semen. These compounds help to protect the sperm from infection and damage.

SPESP1 is also involved in the regulation of the pH level in the testes. It helps to maintain a neutral pH environment that is optimal for the survival and function of sperm. It is also involved in the regulation of the temperature in the testes, which is important for the proper functioning of sperm.

SPESP1 is a glycosylated protein, which means that it has a sugar molecule attached to its amino acids. This sugar molecule plays a vital role in the regulation of the structure and function of SPESP1. It helps to give SPESP1 its unique structure and properties.

The research on SPESP1 is still in its early stages, but it is clear that it has a significant role to play in the functions of sperm. The studies that have been conducted on SPESP1 have shown that it is involved in several important processes in sperm, including the regulation of fertilization, the production of acrosulfur compounds, and the regulation of the pH and temperature in the testes.

In addition to its role in sperm function, SPESP1 is also a potential drug target. The glycosylated structure of SPESP1 makes it a unique target for drug development. The development of drugs that can specifically target SPESP1 and modulate its function could lead to new treatments for a variety of sperm-related disorders.

The research on SPESP1 is still in its early stages, but it is clear that it has a significant role to play in the functions of sperm. The studies that have been conducted on SPESP1 have shown that it is involved in several important processes in sperm, including the regulation of fertilization, the production of acrosulfur compounds, and the regulation of the pH and temperature in the testes. In addition to its role in sperm function, SPESP1 is also a potential drug target. Further research is needed to fully understand the role of SPESP1 in these processes and to develop new treatments for sperm-related disorders.

Protein Name: Sperm Equatorial Segment Protein 1

Functions: Involved in fertilization ability of sperm

The "SPESP1 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 SPESP1 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

SPG11 | SPG21 | SPG7 | SPHAR | Sphingolipid delta(4)-desaturase | Sphingomyelin phosphodiesterase | Sphingomyelin synthase | Sphingosine kinase | SPHK1 | SPHK2 | SPHKAP | SPI1 | SPIB | SPIC | SPICE1 | SPIDR | SPIN1 | SPIN2A | SPIN2B | SPIN3 | SPIN4 | SPINDOC | SPINK1 | SPINK13 | SPINK14 | SPINK2 | SPINK4 | SPINK5 | SPINK6 | SPINK7 | SPINK8 | SPINK9 | SPINT1 | SPINT2 | SPINT3 | SPINT4 | SPINT5P | SPIRE1 | SPIRE2 | Spliceosomal complex | Spliceosome C complex | Spliceosome Complex | 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