Target Name: MRPS30
NCBI ID: G10884
Review Report on MRPS30 Target / Biomarker Content of Review Report on MRPS30 Target / Biomarker
MRPS30
Other Name(s): mitochondrial large ribosomal subunit protein mS30 | Mitochondrial ribosomal protein S30 | PAP | 28S ribosomal protein S30, mitochondrial | Mitochondrial large ribosomal subunit protein mS30 | MRP-S30 | Mitochondrial large ribosomal subunit protein mL65 | mitochondrial large ribosomal subunit protein mL65 | PDCD9 | RT30_HUMAN | DKFZp566B2024 | programmed cell death 9 | 39S ribosomal protein S30, mitochondrial | S30mt | Programmed cell death protein 9 | mitochondrial ribosomal protein S30 | Programmed cell death 9

Understanding Mitochondrial Ribosomal Subunit Protein (mS30)

Mitochondrial large ribosomal subunit protein (mS30) is a protein that plays a crucial role in the function of the mitochondria, which are organelles found in the cells that power our bodies. Mitochondria are responsible for generating the energy that our cells need to function, and they are also involved in the production of the molecules that make up the cell nucleus.

One of the key functions of mS30 is its role in regulating the size and shape of the mitochondria. Mitochondria are found in most cells of the body, including muscle, nerve, and brain cells. They are responsible for generating the energy that our cells need to function, and they are also involved in the production of the molecules that make up the cell nucleus.

In order for mS30 to function properly, it needs to be produced in the right amount and in the right form. The production of mS30 is regulated by a number of different factors, including the levels of various nutrients and the presence of certain enzymes.

One of the key functions of mS30 is its role in regulating the size and shape of the mitochondria. Mitochondria are found in most cells of the body, including muscle, nerve, and brain cells. They are responsible for generating the energy that our cells need to function, and they are also involved in the production of the molecules that make up the cell nucleus.

In order for mS30 to function properly, it needs to be produced in the right amount and in the right form. The production of mS30 is regulated by a number of different factors, including the levels of various nutrients and the presence of certain enzymes. For example, mS30 is known to be sensitive to changes in the levels of oxygen in the body, which can affect the amount of mS30 that is produced.

In addition to its role in regulating the size and shape of the mitochondria, mS30 is also involved in the production of other important proteins in the cell. For example, it is known to be involved in the production of the proteins that make up the mitochondrial inner membrane, which is a layer of fat and protein that surrounds the mitochondria.

Despite its important role in the functioning of the mitochondria, mS30 is not yet well understood. There are currently very few studies that have been conducted to determine the exact function of mS30, and much of what is known about it comes from experiments that were done in the past.

In conclusion, mitochondrial large ribosomal subunit protein (mS30) is a protein that plays a crucial role in the function of the mitochondria. It is involved in regulating the size and shape of the mitochondria, as well as the production of other important proteins in the cell. While more research is needed to fully understand the role of mS30 in the functioning of the mitochondria, it is clear that it is an important molecule that plays a critical role in the health and function of our cells.

Protein Name: Mitochondrial Ribosomal Protein S30

The "MRPS30 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 MRPS30 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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