Did the early full genome sequencing of yeast boost gene function discovery?

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Did the early full genome sequencing of yeast boost gene function discovery? / Tantoso, Erwin; Eisenhaber, Birgit; Sinha, Swati; Jensen, Lars Juhl; Eisenhaber, Frank.

In: Biology Direct, Vol. 18, 46, 2023.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Tantoso, E, Eisenhaber, B, Sinha, S, Jensen, LJ & Eisenhaber, F 2023, 'Did the early full genome sequencing of yeast boost gene function discovery?', Biology Direct, vol. 18, 46. https://doi.org/10.1186/s13062-023-00403-8

APA

Tantoso, E., Eisenhaber, B., Sinha, S., Jensen, L. J., & Eisenhaber, F. (2023). Did the early full genome sequencing of yeast boost gene function discovery? Biology Direct, 18, [46]. https://doi.org/10.1186/s13062-023-00403-8

Vancouver

Tantoso E, Eisenhaber B, Sinha S, Jensen LJ, Eisenhaber F. Did the early full genome sequencing of yeast boost gene function discovery? Biology Direct. 2023;18. 46. https://doi.org/10.1186/s13062-023-00403-8

Author

Tantoso, Erwin ; Eisenhaber, Birgit ; Sinha, Swati ; Jensen, Lars Juhl ; Eisenhaber, Frank. / Did the early full genome sequencing of yeast boost gene function discovery?. In: Biology Direct. 2023 ; Vol. 18.

Bibtex

@article{a85f583dddc7434081ddd2651c79dc8b,
title = "Did the early full genome sequencing of yeast boost gene function discovery?",
abstract = "BACKGROUND: Although the genome of Saccharomyces cerevisiae (S. cerevisiae) was the first one of a eukaryote organism that was fully sequenced (in 1996), a complete understanding of the potential of encoded biomolecular mechanisms has not yet been achieved. Here, we wish to quantify how far the goal of a full list of S. cerevisiae gene functions still is. RESULTS: The scientific literature about S. cerevisiae protein-coding genes has been mapped onto the yeast genome via the mentioning of names for genomic regions in scientific publications. The match was quantified with the ratio of a given gene name's occurrences to those of any gene names in the article. We find that ~ 230 elite genes with ≥ 75 full publication equivalents (FPEs, FPE = 1 is an idealized publication referring to just a single gene) command ~ 45% of all literature. At the same time, about two thirds of the genes (each with less than 10 FPEs) are described in just 12% of the literature (in average each such gene has just ~ 1.5% of the literature of an elite gene). About 600 genes have not been mentioned in any dedicated article. Compared with other groups of genes, the literature growth rates were highest for uncharacterized or understudied genes until late nineties of the twentieth century. Yet, these growth rates deteriorated and became negative thereafter. Thus, yeast function discovery for previously uncharacterized genes has returned to the level of ~ 1980. At the same time, literature for anyhow well-studied genes (with a threshold T10 (≥ 10 FPEs) and higher) remains steadily growing. CONCLUSIONS: Did the early full genome sequencing of yeast boost gene function discovery? The data proves that the moment of publishing the full genome in reality coincides with the onset of decline of gene function discovery for previously uncharacterized genes. If the current status of literature about yeast molecular mechanisms can be extrapolated into the future, it will take about another ~ 50 years to complete the yeast gene function list. We found that a small group of scientific journals contributed extraordinarily to publishing early reports relevant to yeast gene function discoveries.",
keywords = "Gene function discovery rate, Gene function space, Protein function, Saccharomyces cerevisiae, Uncharacterized genes, Yeast",
author = "Erwin Tantoso and Birgit Eisenhaber and Swati Sinha and Jensen, {Lars Juhl} and Frank Eisenhaber",
note = "Publisher Copyright: {\textcopyright} 2023. BioMed Central Ltd., part of Springer Nature.",
year = "2023",
doi = "10.1186/s13062-023-00403-8",
language = "English",
volume = "18",
journal = "Biology Direct",
issn = "1745-6150",
publisher = "BioMed Central Ltd.",

}

RIS

TY - JOUR

T1 - Did the early full genome sequencing of yeast boost gene function discovery?

AU - Tantoso, Erwin

AU - Eisenhaber, Birgit

AU - Sinha, Swati

AU - Jensen, Lars Juhl

AU - Eisenhaber, Frank

N1 - Publisher Copyright: © 2023. BioMed Central Ltd., part of Springer Nature.

PY - 2023

Y1 - 2023

N2 - BACKGROUND: Although the genome of Saccharomyces cerevisiae (S. cerevisiae) was the first one of a eukaryote organism that was fully sequenced (in 1996), a complete understanding of the potential of encoded biomolecular mechanisms has not yet been achieved. Here, we wish to quantify how far the goal of a full list of S. cerevisiae gene functions still is. RESULTS: The scientific literature about S. cerevisiae protein-coding genes has been mapped onto the yeast genome via the mentioning of names for genomic regions in scientific publications. The match was quantified with the ratio of a given gene name's occurrences to those of any gene names in the article. We find that ~ 230 elite genes with ≥ 75 full publication equivalents (FPEs, FPE = 1 is an idealized publication referring to just a single gene) command ~ 45% of all literature. At the same time, about two thirds of the genes (each with less than 10 FPEs) are described in just 12% of the literature (in average each such gene has just ~ 1.5% of the literature of an elite gene). About 600 genes have not been mentioned in any dedicated article. Compared with other groups of genes, the literature growth rates were highest for uncharacterized or understudied genes until late nineties of the twentieth century. Yet, these growth rates deteriorated and became negative thereafter. Thus, yeast function discovery for previously uncharacterized genes has returned to the level of ~ 1980. At the same time, literature for anyhow well-studied genes (with a threshold T10 (≥ 10 FPEs) and higher) remains steadily growing. CONCLUSIONS: Did the early full genome sequencing of yeast boost gene function discovery? The data proves that the moment of publishing the full genome in reality coincides with the onset of decline of gene function discovery for previously uncharacterized genes. If the current status of literature about yeast molecular mechanisms can be extrapolated into the future, it will take about another ~ 50 years to complete the yeast gene function list. We found that a small group of scientific journals contributed extraordinarily to publishing early reports relevant to yeast gene function discoveries.

AB - BACKGROUND: Although the genome of Saccharomyces cerevisiae (S. cerevisiae) was the first one of a eukaryote organism that was fully sequenced (in 1996), a complete understanding of the potential of encoded biomolecular mechanisms has not yet been achieved. Here, we wish to quantify how far the goal of a full list of S. cerevisiae gene functions still is. RESULTS: The scientific literature about S. cerevisiae protein-coding genes has been mapped onto the yeast genome via the mentioning of names for genomic regions in scientific publications. The match was quantified with the ratio of a given gene name's occurrences to those of any gene names in the article. We find that ~ 230 elite genes with ≥ 75 full publication equivalents (FPEs, FPE = 1 is an idealized publication referring to just a single gene) command ~ 45% of all literature. At the same time, about two thirds of the genes (each with less than 10 FPEs) are described in just 12% of the literature (in average each such gene has just ~ 1.5% of the literature of an elite gene). About 600 genes have not been mentioned in any dedicated article. Compared with other groups of genes, the literature growth rates were highest for uncharacterized or understudied genes until late nineties of the twentieth century. Yet, these growth rates deteriorated and became negative thereafter. Thus, yeast function discovery for previously uncharacterized genes has returned to the level of ~ 1980. At the same time, literature for anyhow well-studied genes (with a threshold T10 (≥ 10 FPEs) and higher) remains steadily growing. CONCLUSIONS: Did the early full genome sequencing of yeast boost gene function discovery? The data proves that the moment of publishing the full genome in reality coincides with the onset of decline of gene function discovery for previously uncharacterized genes. If the current status of literature about yeast molecular mechanisms can be extrapolated into the future, it will take about another ~ 50 years to complete the yeast gene function list. We found that a small group of scientific journals contributed extraordinarily to publishing early reports relevant to yeast gene function discoveries.

KW - Gene function discovery rate

KW - Gene function space

KW - Protein function

KW - Saccharomyces cerevisiae

KW - Uncharacterized genes

KW - Yeast

U2 - 10.1186/s13062-023-00403-8

DO - 10.1186/s13062-023-00403-8

M3 - Journal article

C2 - 37574542

AN - SCOPUS:85168067878

VL - 18

JO - Biology Direct

JF - Biology Direct

SN - 1745-6150

M1 - 46

ER -

ID: 363268981