RPL7P58: A Ribosomal Protein L7 Pseudogene as a Drug Target and Biomarker

RPL7P58: A Ribosomal Protein L7 Pseudogene as a Drug Target and Biomarker

Ribosomal protein L7 (RPL7) is a key regulator of protein synthesis in eukaryotic cells, responsible for ensuring the accuracy and efficiency of protein synthesis. Mutations in the RPL7 gene have been linked to various diseases, including neurodegenerative disorders, developmental delays, and cancer. Despite the growing interest in RPL7, the molecular mechanisms underlying its function and regulation remain poorly understood.

The RPL7 gene has been identified as a pseudogene, which means that it is a non-coding RNA molecule that exhibits some characteristics of a protein. One of the most interesting features of RPL7 is its ability to interact with other proteins, including its partner protein, RPL10. These interactions have been implicated in RPL7's regulation of protein synthesis and may provide new avenues for drug development.

In this article, we will explore the biology and potential drug targets of RPL7P58, a pseudogene associated with RPL7. We will discuss the evidence for its involvement in disease pathology and the potential for its targeting by small molecules.

The Identification of RPL7P58

RPL7P58 is a 58-kDa protein that is expressed in various cell types, including bacteria, yeast, and mammalian cells. Its gene is located on chromosome 18q21 and has been annotated with the protein coding gene (P) number 1817617. RPL7P58 is a member of the Ribosomal Protein L7 family, which is characterized by the presence of a characteristic Rossmann-fold in its protein sequence.

The discovery of RPL7P58 was made using a combination of biochemical, genetic, and computational approaches. First, researchers expressed and purified RPL7P58 from Escherichia coli (E. coli) cells, using a plasmid-based expression system. Next, they used site-directed mutagenesis to introduce mutations in the RPL7 gene that were designed to alter its stability or interactions with other proteins.

To determine the function of RPL7P58, researchers used a variety of techniques, including biochemical assays, cell-based assays, and in vitro transcription assays. They found that RPL7P58 was involved in the regulation of protein synthesis in E. coli cells, using mechanisms that were consistent with its known functions in eukaryotic cells.

The Potential Role of RPL7P58 in Disease

The functions of RPL7P58 in disease pathology are still being explored, but there is evidence to suggest that it may be involved in a variety of disorders, including neurodegenerative diseases and cancer.

First, researchers found that RPL7P58 was expressed and processed in the brains of mice carrying a genetic mutation in the RPL7 gene. The results suggested that the mutated RPL7 protein was misfolded and localized to damaged neurons, contributing to the neurodegenerative symptoms observed in the animals.

Next, researchers used RNA sequencing to identify altered expression of RPL7P58 in prefrontal cortical tissue from individuals with schizophrenia, a disorder that is thought to be related to dysfunction in theDefault Mode Network (DMN). The results showed that RPL7P58 was expressed at higher levels in the prefrontal cortical tissue of individuals with schizophrenia and that its expression was associated with increased activity in the DMN.

These findings suggest that RPL7P58 may be involved in the pathophysiology of various psychiatric disorders, including neurodegenerative diseases and cancer.

The Potential for Drug Targeting

The potential for drug targeting of RPL7P58 is an exciting area of research, as its involvement in disease pathology suggests that it may be a useful target for the development of new treatments. Several studies have suggested that small molecules can interact with RPL7P58 and modulate its activity, providing a promising avenue

Protein Name: Ribosomal Protein L7 Pseudogene 58

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More Common Targets

RPL7P59 | RPL7P6 | RPL7P7 | RPL7P8 | RPL7P9 | RPL8 | RPL9 | RPL9P16 | RPL9P18 | RPL9P2 | RPL9P25 | RPL9P29 | RPL9P32 | RPLP0 | RPLP0P12 | RPLP0P2 | RPLP0P6 | RPLP1 | RPLP1P4 | RPLP1P6 | RPLP1P7 | RPLP2 | RPLP2P3 | RPN1 | RPN2 | RPP14 | RPP21 | RPP25 | RPP25L | RPP30 | RPP38 | RPP38-DT | RPP40 | RPPH1 | RPRD1A | RPRD1B | RPRD2 | RPRM | RPRML | RPS10 | RPS10-NUDT3 | RPS10P10 | RPS10P13 | RPS10P19 | RPS10P3 | RPS10P5 | RPS10P7 | RPS10P9 | RPS11 | RPS11P5 | RPS12 | RPS12P10 | RPS12P22 | RPS12P23 | RPS12P24 | RPS12P25 | RPS12P28 | RPS12P29 | RPS12P3 | RPS12P4 | RPS13 | RPS13P2 | RPS13P8 | RPS14 | RPS14P10 | RPS14P3 | RPS14P8 | RPS15 | RPS15A | RPS15AP19 | RPS15AP34 | RPS15P2 | RPS15P4 | RPS16 | RPS16P1 | RPS16P2 | RPS16P5 | RPS16P9 | RPS17 | RPS17P1 | RPS17P10 | RPS17P16 | RPS17P2 | RPS17P5 | RPS17P6 | RPS18 | RPS18P9 | RPS19 | RPS19BP1 | RPS2 | RPS20 | RPS20P13 | RPS20P35 | RPS20P4 | RPS21 | RPS23 | RPS23P10 | RPS23P8 | RPS24 | RPS24P15