Factors

We need to know every factor which determines lifespan.

Lifespan factors often but not always originate from defined genetic elements. They are not just genes, by definition they can be anything for which a Classifications schema can be build for that is related to the regulation of lifespan, such entities may include Single-Nucleotide Polymorphism, transcript variants, proteins and their complexes, compounds (i.e. small molecules like metabolites and drugs), etc. A factor should be based on a defined molecular entity or genomic position and been classified. It shall be highly flexible and scalable Concept.

While individual lifespan factors within each species or precise defined molecular entities will be captured within the Lifespan App, Data Entries of the Data App may summarize for instance the relevance of each factor class (e.g. homologous group; chemical derivate of related structure and properties, etc.) as well as draw overall conclusions. o

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  • Types: + -
    Gene (1)  
  • symbol name observation species
    CCR4 Carbon Catabolite Repression 4 Deletion of CCR4 increases mean chronological lifespan by 20 - 41% (20, 33, 41) in diploid cells [21447998]. In W303R CCR4 deletion shortens replicative lifespan by approximately 80% and results in temperature sensitivity that is suppressed by SSD1-V. SSD1-V partially suppresses the short-lifespan of ccr4 mutant. CCR4 mutation is synthetically lethal in combination with deletion of MPT5 in the absence of SSD1-V [11805047]. Budding yeast
    RPL6A Ribosomal Protein of the Large subunit 6A Deletion of RPL6A decrease mean replicative lifespan by 25% in the alpha strain [18340043; 18423200], but increases mean replicative lifespan by 40% in the remade strain. Its deletion non-significantly increases mean replicative lifespan in the ORF collection [22377630]. Budding yeast
    GTS1 Glycine Threonine Serine repeat protein 1 Deletion or overexpression of GTS1 shortens replicative lifespan significantly and slightly, respectively (wt:26, Delta:16 and OE:24) [8573138]. Budding yeast
    PMR1 High affinity Ca2+/Mn2+ P-type ATPase required for Ca2+ and Mn2+ transport into Golgi; involved in Ca2+ dependent protein sorting and processing; mutations in human homolog ATP2C1 cause acantholytic skin condition Hailey-Hailey disease Deletion of PMR1 increses the replicative lifespan by 40% in the alpha strain and by 15% in the a strain. Overexpression of PMR1 extends the lifespan [21918615]. Budding yeast
    NDE1 NADH Dehydrogenase, External 1 Overexpression of NDE1 and NDE2 increases intracellular NAD/NADH ratio by lowering NADH concentration and increases replicative lifespan by 20-25%. This lifespan extension is non-additive 0.5% glucose restriction [14724176]. Deletion of NDE1 extends chronological lifespan [16436509]. Budding yeast
    IPT1 InositolPhosphoTransferase 1 Transposon-mediated mutation of IPT1 increases oxidative stress resistance and chronological lifespan by 40% [16527275]. IPT1 deletion decreases replicative lifespan by 30% in the alpha strain [19030232]. Budding yeast
    GCN4 Transcriptional activator of amino acid biosynthetic genes in response to amino acid starvation; expression is tightly regulated at both the transcriptional and translational levels Deletion of GCN4 increases the replicative lifespan by 10% in the alpha strain [19030232]. GCN4 deletion decreases the lifespan in the alpha and a strain [20657825]. The chronological lifespan of GCN4 deletion is strongly decreased in the a strain [20421943]. Budding yeast
    ERG5 ERGosterol biosynthesis 5 Deletion of ERG5 decreases replicative lifespan by 35% in the a strain [18340043], but increases mean chronological lifespan by 26 - 116% (26, 40, 43, 62, 116) in diploid cells [21447998]. Deletion of ERG5 cancels out the replicative lifespan extension of 0.5% glucose restriction [18690010]. Budding yeast
    ATP1 ATP synthase 1 Deletion of ATP1 increases chronological lifespan by up to 50% [17492370], but decreases replicative lifespan by 70% in the alpha strain [18340043]. Budding yeast
    AFG3 ATPase Family Gene 3 Deletion of the mitochondrial AAA protease AFG3 increases replicative lifespan by 20% in the alpha and a strains [18340043], but decreases chronological lifespan by 37 - 51% in diploid cells [21447998]. AFG3 deletion changes mean, median and maximum lifespan by 15 to 26% 17 to 30% and -25 to +58%, respectively. AFG3 deletion leads to reduced cytoplasmic mRNA translation and its lifespan extension is independent of Sir2 and Hac1, but requires Gcn4. AFG3 deletion further extends the lifespan of cell deficient in both SIR2 and FOB1, but fails to extend the lifespan of dietary restricted cells or cells lacking GCN4. Gcn4 protein levels are increased in afg3 mutants. The deletion of AFG3 fails to extend the replicative lifespan in the W303AR strain. AFG3 deletion does deletion extend the replicative lifespan at 15°C. Budding yeast
    SSD1 Suppressor of SIT4 Deletion 1 Overexpression of SSD1 (addition of a SSD1-V allele) increases replicative lifespan by 50%, independently of SIR2 and SIR2 further extends the lifespan, although SIR2 is necessary for SSD1-V cells to attain maximal lifespan [15126388]. SSD1-V also dramatically increases chronological lifespan with lifespan twice as long as ssd1-d cells [19570907]. Deletion of SSD1 increases replicative lifespan by 50% [Li et al., 2009]. Addition of SSD1-V allele to an ssd1-d strain suppresses the short lifespan of an MPT5 deletion mutant [11805047] and extend wild-type lifespan [Kaeberlein and Guarente, unpublished]. SSD1-V slightly extends the lifespan of swi4 and ccr4 mutant strains and suppresses the temperature sensitive growth phenotype of mpt5, ccr3, swi4, and swi6 single mutants [11805047]. SSD1-V also suppresses the synthetic lethality caused by deletion of MPT5 in combination with a mutation in SWI4, SWI6, or CCR4 [11805047]. SSD1-V suppresses mutations that affect cell wall stability [1545797; 8386319], RNA polymerase III activity [8510644], RNA splicing [10446233], and PKA activity [1848673; 8200529]. Budding yeast
    SNF1 Sucrose NonFermenting 1 Forced overexpression (high-copy 2 micro expression) of SNF1 shortens replicative lifespan to 75% of wild-type and is accompanied by signs of premature ageing, including progressive sterility, enlargement and fragmentation of the nucleus, redistribution of Sir3 to the nucleus, and more rapid accumulation of extrachromosomal rDNA circles [10921902]. SNF1 overexpression also reduced chronological lifespan [19164565]. Deletion of SNF1 increases replicative lifespan by 50% in the alpha strain [19030232], but decreases chronological lifespan [21076178]. Budding yeast
    RAS2 Ras-like protein 2 Overexpression of RAS2 causes a 43% increase in mean and 18% increase in maximum lifespan as well as postpones the age-related increase in generation time. RAS2 deletion causes a 23% decrease in mean and a 30% decrease in maximum lifespan [8034612]. Deletion of RAS2 leads to a longer chronological lifespan [21076178]. Deletion of the RAS2 gene, which functions upstream of CYR1, doubles the mean chronological lifespan by a mechanism that requires Msn2/4 and Sod2 [12586694]. DR further extends chronological lifespan of ras2Delta [18225956]. Budding yeast
    GLN3 GLutamiNe metabolism 3 Deletion of GLN3 extends chronological lifespan [16418483]. GLN3 deletion decreases replicative lifespan by 20% in the alpha strain [19030232]. GLN3 deletion in the vineyard strain dramatically shortens chronological lifespan, while extends that of the laboratory strain [21901113]. Budding yeast
    • 14 factors
    Factors are an extension of GenAge and GenDR.

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