A rare and potentially damaging de novo missense variant in the EIF4G1 gene was identified in an ASD proband from the Simons Simplex Collection in Iossifov et al., 2014. Gonatopoulos-Pournatzis et al., 2020 demonstrated that microexon splicing in eIF4G translation initiation factors, a process involved in regulation of the neuronal proteome and higher order cognitive functions, was disrupted in post-mortem brain tissue from autistic patients; furthermore, mice that were deficient for the Eif4g1 microexon (Eif4g1MIC/MIC) displayed learning and memory deficits, altered synaptic plasticity, and autistic-like social behavior.
Molecular Function
The protein encoded by this gene is a component of the multi-subunit protein complex EIF4F. This complex facilitates the recruitment of mRNA to the ribosome, which is a rate-limiting step during the initiation phase of protein synthesis. The recognition of the mRNA cap and the ATP-dependent unwinding of 5'-terminal secondary structure is catalyzed by factors in this complex. The subunit encoded by this gene is a large scaffolding protein that contains binding sites for other members of the EIF4F complex. A domain at its N-terminus can also interact with the poly(A)-binding protein, which may mediate the circularization of mRNA during translation.
External Links
References
Type
Title
Type of Disorder
Associated Disorders
Author, Year
Primary
Autism-Misregulated eIF4G Microexons Control Synaptic Translation and Higher Order Cognitive Functions.
EIF4G1 microexon-deficient mice display deficits in social approach and social memory in the three-chambered assay, decreased social interaction in the reciprocal interaction test, impaired episodic memory measured by the fear conditioning test, and altered hippocampal synaptic plasticity as measured by LTP. Eif4g1^-/- mice have normal weight, motor coordination, locomotion, habituation, anxiety, aggression, hearing, response to light stimuli, cued fear conditioning. Eif4g1^-/- are born at Mendelian ratios and show no change in gross morphology. Eif4g1^-/- mice have increased expression of critical synaptic proteins, including GluN1.
References
Type
Title
Author, Year
Primary
Autism-Misregulated eIF4G Microexons Control Synaptic Translation and Higher Order Cognitive Functions.
Model Type:
Genetic
Model Genotype:
Homozygous
Mutation:
CRISPR-Cas9 editing was used to generate mice with deletion of eIF4G1 microexon overlapping prion-like domains (delMIC), GGFRSLQ, proximal to the N-terminus of eIF4G1. Heterozygous Eif4g1^+/delMIC animals were crossed to generate mice homozygously deleted for microexons (Eif4g1^delMIC/delMIC). PCR and Sanger sequencing confirmed successful deletions.
Allele Type: Knockout
Strain of Origin: C57BL/6J
Genetic Background: C57BL/6J
ES Cell Line: Not specified
Mutant ES Cell Line: Not specified
Model Source: PMID 31999954
Model Type:
Genetic
Model Genotype:
Heterozygous
Mutation:
CRISPR-Cas9 editing was used to generate mice with deletion of eIF4G1 microexon overlapping prion-like domains (delMIC), GGFRSLQ, proximal to the N-terminus of eIF4G1. Heterozygous Eif4g1^+/delMIC animals were crossed to generate mice homozygously deleted for microexons (Eif4g1^delMIC/delMIC). PCR and Sanger sequencing confirmed successful deletions.
Allele Type: Knockout
Strain of Origin: C57BL/6J
Genetic Background: C57BL/6J
ES Cell Line: Not specified
Mutant ES Cell Line: Not specified
Model Source: PMID 31999954
Description: Mutant ca3-ca1 hippocampal neurons show significant facilitation of protein-synthesis dependent ltp after induction with multiple tetani but not of protein-synthesis independent ltp after milder induction.
Exp Paradigm: NA
Spontaneous post synaptic event amplitude: inhibitory currents1
Increased
Description: Mutants show increase in the amplitude of spontaneous inhibitory postsynaptic currents (sipscs) in ca1 hippocampal neurons.
Exp Paradigm: NA
