Asparagine--tRNA ligase, cytoplasmic (NARS)

The protein contains 548 amino acids for an estimated molecular weight of 62943 Da.

 

Catalyzes the attachment of asparagine to tRNA(Asn) in a two-step reaction: asparagine is first activated by ATP to form Asn-AMP and then transferred to the acceptor end of tRNA(Asn) (PubMed:9421509). In addition to its essential role in protein synthesis, acts as a signaling molecule that induced migration of CCR3-expressing cells (PubMed:30171954, PubMed:12235211). (updated: Nov. 13, 2019)

Protein identification was indicated in the following studies:

  1. Goodman and co-workers. (2013) The proteomics and interactomics of human erythrocytes. Exp Biol Med (Maywood) 238(5), 509-518.
  2. Hegedűs and co-workers. (2015) Inconsistencies in the red blood cell membrane proteome analysis: generation of a database for research and diagnostic applications. Database (Oxford) 1-8.
  3. Wilson and co-workers. (2016) Comparison of the Proteome of Adult and Cord Erythroid Cells, and Changes in the Proteome Following Reticulocyte Maturation. Mol Cell Proteomics. 15(6), 1938-1946.
  4. D'Alessandro and co-workers. (2017) Red blood cell proteomics update: is there more to discover? Blood Transfus. 15(2), 182-187.
  5. Chu and co-workers. (2018) Quantitative mass spectrometry of human reticulocytes reveal proteome-wide modifications during maturation. Br J Haematol. 180(1), 118-133.

Methods

The following articles were analysed to gather the proteome content of erythrocytes.

The gene or protein list provided in the studies were processed using the ID mapping API of Uniprot in September 2018. The number of proteins identified and mapped without ambiguity in these studies is indicated below.
Only Swiss-Prot entries (reviewed) were considered for protein evidence assignation.

PublicationIdentification 1Uniprot mapping 2Not mapped /
Obsolete
TrEMBLSwiss-Prot
Goodman (2013)2289 (gene list)227853205992269
Lange (2014)123412347281224
Hegedus (2015)2638262202352387
Wilson (2016)165815281702911068
d'Alessandro (2017)18261817201815
Bryk (2017)20902060101081942
Chu (2018)18531804553621387

1 as available in the article and/or in supplementary material
2 uniprot mapping returns all protein isoforms as one entry

The compilation of older studies can be retrieved from the Red Blood Cell Collection database.

The data and differentiation stages presented below come from the proteomic study and analysis performed by our partners of the GReX consortium, more details are available in their published work.

No sequence conservation computed yet.

Interpro domains
Total structural coverage: 83%
Model score: 23

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The reference OMIM entry for this protein is 108410

Asparaginyl-trna synthetase; nars
Asnrs

CLONING

Cirullo et al. (1983) isolated hybrids between human peripheral leukocytes and a temperature-sensitive CHO cell line with a thermolabile asparaginyl-tRNA synthetase (EC 6.1.1.22), which they symbolized 'asnS.' Hybrids selected at 39 degrees C required the presence of human chromosome 18. Temperature-resistant hybrid cells contained 2 forms of ASNRS: 1 highly thermal resistant, like the human enzyme, and 1 highly thermolabile, like the CHO mutant enzyme. Beaulande et al. (1998) cloned a human cytosolic ASNRS cDNA from a liver cDNA library. The deduced 548-amino acid protein has a predicted molecular mass of 62.9 kD and shares 53% sequence identity with the S. cerevisiae homolog. Lo et al. (2014) reported the discovery of a large number of natural catalytic nulls for each human aminoacyl tRNA synthetase. Splicing events retain noncatalytic domains while ablating the catalytic domain to create catalytic nulls with diverse functions. Each synthetase is converted into several new signaling proteins with biologic activities 'orthogonal' to that of the catalytic parent. The recombinant aminoacyl tRNA synthetase variants had specific biologic activities across a spectrum of cell-based assays: about 46% across all species affect transcriptional regulation, 22% cell differentiation, 10% immunomodulation, 10% cytoprotection, and 4% each for proliferation, adipogenesis/cholesterol transport, and inflammatory response. Lo et al. (2014) identified in-frame splice variants of cytoplasmic aminoacyl tRNA synthetases. They identified 1 catalytic-null splice variant for AsnRS.

MAPPING

Using a DNA probe in human-rodent hybrid cells, Shows (1983) found that asparaginyl-tRNA synthetase segregated with peptidase A, a chromosome 18 marker.

GENE FUNCTION

By Western blot analysis, Beaulande et al. (1998) showed that a human autoimmune serum (anti-KS) neutralized human AsnRSc activity, suggesting that it is a class II aminoacyl-tRNA synthetase involved in autoimmune reactions. ... More on the omim web site

Subscribe to this protein entry history

Dec. 2, 2019: Protein entry updated
Automatic update: Entry updated from uniprot information.

Feb. 2, 2018: Protein entry updated
Automatic update: Uniprot description updated

Dec. 19, 2017: Protein entry updated
Automatic update: Uniprot description updated

Nov. 23, 2017: Protein entry updated
Automatic update: Uniprot description updated

June 20, 2017: Protein entry updated
Automatic update: comparative model was added.

March 16, 2016: Protein entry updated
Automatic update: OMIM entry 108410 was added.