Anti-SMNDC1 antibody [PCRP-SMNDC1-1A9]

Supplementary info

This supplementary information is collated from multiple sources and compiled automatically.

Activity summary

SMNDC1 also known as Small Nuclear Riboprotein SmN functions as an important player in pre-mRNA splicing. It is a protein weighing approximately 37 kDa. SMNDC1 shows expression in a variety of tissues notably in the brain and spinal cord. It interacts directly with components of the spliceosome suggesting that its primary mechanical role involves the assembly and rearrangement of spliceosomal complexes to facilitate accurate splicing processes.

Biological function summary

SMNDC1 assists in regulating gene expression through its contribution to mRNA maturation. SMNDC1 forms part of the spliceosomal complex which is important for the removal of introns from pre-mRNA transcripts. The assembly of this complex ensures that genetic messages are processed and translated correctly within the cell. Furthermore SMNDC1's involvement in RNA metabolism affects overall cellular function highlighting its importance in maintaining the integrity of cellular biology.

Pathways

SMNDC1 is integral in the spliceosome pathway where it collaborates with other proteins to perform splicing activities. This pathway influences gene expression patterns critical for cellular function and differentiation. Another related pathway is the RNA transport pathway where SMNDC1 is associated with proteins such as SMN1 and Gemin2. These associations highlight its contribution to the regulation of gene expression beyond splicing alone accommodating the broader requirements of cell survival and adaptability.

Associated diseases and disorders

SMNDC1's involvement connects to neurodegenerative conditions such as spinal muscular atrophy (SMA). Dysfunction in its interactions particularly with the SMN1 protein disrupts normal spliceosomal activity which can lead to neuronal degeneration and muscle wasting characteristic of SMA. Additionally researchers have noted links between SMNDC1 and certain cancers which may arise from its role in genomic stability and cell cycle regulation. Understanding these disease associations provides insight into potential therapeutic targets for modulating SMNDC1's function.