GUS1/YGL245W Summary

Standard Name	GUS1
Systematic Name	YGL245W
Alias	GSN1
Feature Type	ORF, Verified
Description	Glutamyl-tRNA synthetase (GluRS); forms a complex with methionyl-tRNA synthetase (Mes1p) and Arc1p; complex formation increases the catalytic efficiency of both tRNA synthetases and ensures their correct localization to the cytoplasm; protein abundance increases in response to DNA replication stress (1, 2, 3 and see Summary Paragraph)
Name Description	GlUtamyl-tRNA Synthetase
Gene Product Alias	GluRS

Chromosomal Location	ChrVII:39023 to 41149 \| ORF Map \| GBrowse

Gene Ontology Annotations All GUS1 GO evidence and references

	View Computational GO annotations for GUS1
Molecular Function
Manually curated	glutamate-tRNA ligase activity (IDA)
Biological Process
Manually curated	glutamyl-tRNA aminoacylation (IDA)
Cellular Component
Manually curated	methionyl glutamyl tRNA synthetase complex (IDA) mitochondrion (IDA)
High-throughput	cytoplasm (IDA)

Mutant phenotypes All GUS1 Phenotype evidence and references

Large-scale survey
conditional	colony sectoring: increased heat sensitivity: increased
null	filamentous growth: decreased haploproficient invasive growth: absent inviable
overexpression	resistance to sirolimus: increased
reduction of function	competitive fitness: decreased
Resources	PROPHECY \| SCMD \| ScreenTroll \| Yeast Fitness Database

interactions All GUS1 Interaction evidence and references

	132 total interaction(s) for 108 unique genes/features.
Physical Interactions	Affinity Capture-MS: 69 Affinity Capture-RNA: 5 Affinity Capture-Western: 2 Biochemical Activity: 22 Co-crystal Structure: 1 Protein-peptide: 3 Protein-RNA: 2 Reconstituted Complex: 6 Two-hybrid: 1
Genetic Interactions	Negative Genetic: 9 Positive Genetic: 10 Synthetic Growth Defect: 1 Synthetic Lethality: 1
Resources	BioGRID \| BOND \| BioPIXIE \| CYC2008 (complexes) \| Complexome \| DIP \| DRYGIN \| GeneMANIA \| InterologFinder \| YeastRC Mass Spec

Expression Summary


Resources	Expression Summary \| Cell cycle and metabolic oscillation \| Cell cycle transcript profile \| Cyclebase \| Genevestigator \| GermOnline \| SPELL \| YMGV \| YeastFunc

Protein Information All GUS1 Protein evidence and references

Localization	YeastRC \| Organelle DB (UMich) \| YPL+ \| YeastGFP
Phosphorylation	PhosphoGRID \| PhosphoPep Database
Structure	GPMDB \| SCOP \| YeastRC
Homologs	Ashbya (AGD) \| CGD Homologs \| CandidaDB Homologs \| Fungal Orthogroups Repository \| P-POD \| PDB Homologs \| PhylomeDB \| YGOB \| YOGY

sequence information

ChrVII:39023 to 41149 | |

Last Update

Coordinates: 2003-09-22 | Sequence: 2003-09-22

Subfeature details

	Relative Coordinates	Chromosomal Coordinates	Most Recent Updates
	Relative Coordinates	Chromosomal Coordinates	Coordinates	Sequence
CDS	1..2127	39023..41149	2003-09-22	2003-09-22

Retrieve sequences

Analyze Sequence

S288C only	BLASTP \| ATCC/WashU Clones \| BLASTN \| Design Primers \| Restriction Fragment Map \| Restriction Fragment Sizes \| Six-Frame Translation
S288C vs. other species	Fungal Alignment \| BLASTN vs. fungi \| BLASTP at NCBI \| BLASTP vs. fungi \| Synteny Viewer
S288C vs. other strains	Strain Alignment

Resources

External Links	All Associated Seq \| E.C. \| Entrez Gene \| Entrez RefSeq Protein \| MIPS \| Search all NCBI (Entrez) \| UniProtKB

Primary SGDID	S000003214

SUMMARY PARAGRAPH for GUS1

About aminoacyl-tRNA synthetases...

In a process critical for accurate translation of the genetic code, aminoacyl-tRNA synthetases (aka aminoacyl-tRNA ligases) attach amino acids specifically to cognate tRNAs, thereby "charging" the tRNAs. The catalysis is accomplished via a two-step mechanism. First, the synthetase activates the amino acid in an ATP-dependent reaction, producing aminoacyl-adenylate and releasing inorganic pyrophosphate (PPi). Second, the enzyme binds the correct tRNA and transfers the activated amino acid to either the 2' or 3' terminal hydroxyl group of the tRNA, forming the aminoacyl-tRNA and AMP (4, 5 and references therein).

Aminoacyl-tRNA synthetases possess precise substrate specificity and, despite their similarity in function, vary in size, primary sequence and subunit composition. Individual members of the aminoacyl-tRNA synthetase family can be categorized in one of two classes, depending on amino acid specificity. Class I enzymes (those specific for Glu, Gln, Arg, Cys, Met, Val, Ile, Leu, Tyr and Trp) typically contain two highly conserved sequence motifs, are monomeric or dimeric, and aminoacylate at the 2' terminal hydroxyl of the appropriate tRNA. Class II enzymes (those specific for Gly, Ala, Pro, Ser, Thr, His, Asp, Asn, Lys and Phe) typically contain three highly conserved sequence motifs, are dimeric or tetrameric, and aminoacylate at the 3' terminal hydroxyl of the appropriate tRNA (4, 5, 6 and references therein).

Last updated: 2008-07-14

References cited on this page View Complete Literature Guide for GUS1

1)	Galani K, et al. (2001) The intracellular location of two aminoacyl-tRNA synthetases depends on complex formation with Arc1p. EMBO J 20(23):6889-98
2)	Deinert K, et al. (2001) Arc1p organizes the yeast aminoacyl-tRNA synthetase complex and stabilizes its interaction with the cognate tRNAs. J Biol Chem 276(8):6000-8
3)	Tkach JM, et al. (2012) Dissecting DNA damage response pathways by analysing protein localization and abundance changes during DNA replication stress. Nat Cell Biol 14(9):966-76
4)	Delarue M (1995) Aminoacyl-tRNA synthetases. Curr Opin Struct Biol 5(1):48-55
5)	Arnez JG and Moras D (1997) Structural and functional considerations of the aminoacylation reaction. Trends Biochem Sci 22(6):211-6
6)	Eriani G, et al. (1990) Partition of tRNA synthetases into two classes based on mutually exclusive sets of sequence motifs. Nature 347(6289):203-6