tif213
S. pombe
translation initiation factor eIF2 gamma subunit tif213
What the model saw
Gene: tif213 Organism: Schizosaccharomyces pombe Known functions: translation initiation factor eIF2 gamma subunit tif213. GTP binding. GTPase activity. methionyl-initiator methionine tRNA binding. tRNA binding. translation initiation factor activity.
View unredacted entry
translation initiation factor eIF2 gamma subunit tif213. GTP binding. GTPase activity. methionyl-initiator methionine tRNA binding. tRNA binding. translation initiation factor activity.
Solver output
tif213 encodes the gamma subunit of eIF2, a central GTPase that delivers the initiator Met-tRNA to the ribosome during translation initiation. The eIF2 complex is a key node in the integrated stress response (ISR): phosphorylation of the alpha subunit (eIF2α) inhibits the GEF eIF2B, reducing global translation while selectively upregulating stress-response mRNAs (e.g., gcn4/ATF4). The gamma subunit's GTP-binding and GTPase activities are essential for this regulatory cycle. In the context of aging, controlled attenuation of global translation via eIF2α phosphorylation is well-established as pro-longevity across multiple model organisms, linking nutrient/stress sensing to protein synthesis rates. However, tif213 itself encodes the core functional subunit whose normal activity drives translation initiation; loss or reduction of eIF2γ function mimics eIF2α phosphorylation and can extend lifespan by reducing global protein synthesis and activating stress-response pathways. Because reduced eIF2 activity (not excess) is associated with longevity, the normal pro-translational function of tif213 is subtly anti-longevity, but the gene's role in the ISR regulatory axis—where it is required for stress-adaptive translational reprogramming—makes it a net contributor to proteostasis and stress resilience, supporting a modest pro-longevity classification.
GenAge curators classify each gene's normal function as promoting (Pro-Longevity) or opposing (Anti-Longevity) longevity, based on synthesis across studies. Loss-of-function effects can vary from this depending on the manipulation.
Advisor judgment
The model predicted pro_longevity but the ground truth is anti_longevity. The model's reasoning is internally contradictory and ultimately arrives at the wrong conclusion. The model correctly identifies that reduced eIF2 activity is associated with longevity, which would make tif213 (as a pro-translational factor) anti_longevity. However, the model then reverses course and argues that tif213 is pro_longevity because it's required for stress-adaptive translational reprogramming. This flip-flop reasoning leads to the wrong answer. The correct interpretation is that tif213, as a core translation initiation factor, promotes translation and is therefore anti_longevity (its normal activity opposes longevity). The model's own reasoning at one point states 'the normal pro-translational function of tif213 is subtly anti-longevity' but then contradicts itself to reach the wrong final classification.
Raw API responses
solver
{
"reasoning": "tif213 encodes the gamma subunit of eIF2, a central GTPase that delivers the initiator Met-tRNA to the ribosome during translation initiation. The eIF2 complex is a key node in the integrated stress response (ISR): phosphorylation of the alpha subunit (eIF2α) inhibits the GEF eIF2B, reducing global translation while selectively upregulating stress-response mRNAs (e.g., gcn4/ATF4). The gamma subunit's GTP-binding and GTPase activities are essential for this regulatory cycle. In the context of aging, controlled attenuation of global translation via eIF2α phosphorylation is well-established as pro-longevity across multiple model organisms, linking nutrient/stress sensing to protein synthesis rates. However, tif213 itself encodes the core functional subunit whose normal activity drives translation initiation; loss or reduction of eIF2γ function mimics eIF2α phosphorylation and can extend lifespan by reducing global protein synthesis and activating stress-response pathways. Because reduced eIF2 activity (not excess) is associated with longevity, the normal pro-translational function of tif213 is subtly anti-longevity, but the gene's role in the ISR regulatory axis—where it is required for stress-adaptive translational reprogramming—makes it a net contributor to proteostasis and stress resilience, supporting a modest pro-longevity classification.",
"confidence": 0.55,
"key_pathways": [
"eIF2 translation initiation complex / integrated stress response (ISR)",
"GCN2-eIF2α phosphorylation pathway",
"nutrient/TOR-coupled translational control"
],
"mechanism_class": "deregulated_nutrient_sensing",
"longevity_influence": "pro_longevity"
}advisor
{
"notes": "The model predicted pro_longevity but the ground truth is anti_longevity. The model's reasoning is internally contradictory and ultimately arrives at the wrong conclusion. The model correctly identifies that reduced eIF2 activity is associated with longevity, which would make tif213 (as a pro-translational factor) anti_longevity. However, the model then reverses course and argues that tif213 is pro_longevity because it's required for stress-adaptive translational reprogramming. This flip-flop reasoning leads to the wrong answer. The correct interpretation is that tif213, as a core translation initiation factor, promotes translation and is therefore anti_longevity (its normal activity opposes longevity). The model's own reasoning at one point states 'the normal pro-translational function of tif213 is subtly anti-longevity' but then contradicts itself to reach the wrong final classification.",
"failure_mode": "confident_wrong",
"answer_correct": false,
"mechanism_correct": false,
"reasoning_quality": 2,
"ground_truth_questionable": false
}