New & Noteworthy

YeastMine shutting down July 15

July 01, 2024

Due to ongoing cuts to our funding, SGD can no longer continue to provide the YeastMine data warehouse resource. It is with heavy hearts that we discontinue this service.

Back in 2011, SGD implemented InterMine (http://www.InterMine.org), an open source data warehouse system with a sophisticated querying interface, to create YeastMine, a multifaceted search and retrieval environment that provided access to diverse data types. YeastMine served as a powerful search interface, a discovery tool, a curation aid, and a complex database presentation format.

YeastMine has served us all quite well. We are working to move the YeastMine data into AllianceMine, hosted by the Alliance of Genome Resources, of which SGD is a founding member.

To get started with AllianceMine, go to the Templates page, and filter by category = ‘YeastMine’.

Categories: Announcements

SGD Newsletter, Summer 2024

June 20, 2024

About this newsletter:
This is the Summer 2024 issue of the SGD newsletter. The goal of this newsletter is to inform our users about new features in SGD and to foster communication within the yeast community. You can view this newsletter as well as previous newsletters, on the SGD Community Wiki.

Contents

• Give a Gift / Support SGD
• Reference genome update R64.5
• Extended gene coordinates in GFF
• Updates to SGD search
• microPublications – latest yeast papers
• Alliance of Genome Resources – Latest Release 7.2
• Upcoming conferences and courses

Give a Gift / Support SGD

Budget cuts from NIH continue to strain SGD’s finances. Despite our efforts at reducing costs, we still have significant ongoing budgetary challenges. Donations are now critical for our work to continue.

Your generous gift to SGD will help us to continue providing essential information for your research and teaching efforts. 

To contribute, please make checks payable to Stanford University, noting that “the funds should be used to support the Saccharomyces Genome Database project, under the direction of Drs. Sherlock and Cherry in the Department of Genetics, Stanford University.  Account : GHJKO, Genetics : WAZC.” 

Thank you for your support!

Kindly send by mail to:

Development Services
PO Box 20466
Stanford, CA 94309

CONTACT US: sgd-helpdesk@lists.stanford.edu

Reference genome update R64.5

The S. cerevisiae strain S288C reference genome annotation has been updated to include previously unannotated features. The new genome annotation is release R64.5.1, dated 2024-05-29. Note that the underlying genome sequence itself was not altered; the chromosome sequences remain stable and unchanged.

The R64.5.1 update included:

• Six new open reading frames (ORFs): YDL204W-A, YFR035W-A, YGR016C-A, YMR106W-A, YNL040C-A, YNL155C-A
• New uORFs for 4 ORFs: ATG12/YBR217W, ATG19/YOL082W, ATG5/YPL149W, ATG13/YPR185W
  • A uORF is a small upstream open reading frame that precedes, and regulates downstream translation of, the major ORF.
• Move start downstream: EFM4/YIL064W
• ORF upgraded from Dubious to Verified: YIL059C

Various sequence and annotation files are available on SGD’s Downloads site. You can find more update details on the Details of 2024 Reference Genome Annotation Update R64.5 SGD Wiki page.

Extended gene coordinates in GFF

The saccharomyces_cerevisiae.gff contains sequence features of Saccharomyces cerevisiae and related information such as Locus descriptions and GO annotations. The saccharomyces_cerevisiae.gff is fully compatible with Generic Feature Format Version 3, and is updated weekly.

In recent years, SGD has made two significant changes to the GFF content (described in more detail below):

• In November 2020, SGD updated the file to reflect experimentally determined transcripts
• In February 2024, SGD edited the ‘gene’ entries in the file to extend the coordinates to encompass the start and stop coordinates of the longest experimentally determined transcripts

In November 2020, SGD updated the transcripts in the GFF file to reflect the experimentally determined transcripts (Pelechano et al. 2013, Ng et al. 2020), when possible. The longest transcripts were determined for two different growth media – galactose and dextrose. When available, experimentally determined transcripts for one or both conditions were added for a gene. When this data was absent, transcripts matching the start and stop coordinates of an open reading frame (ORF) were used. 

Starting November 2020: BDH2/YAL061W with rows for longest transcripts expressed in GAL and in YPD.

Then in February 2024, SGD increased the start and stop coordinates of genes to encompass the start and stop coordinates of the longest experimentally determined transcripts, regardless of condition. This change was made in order to comply with JBrowse 2, a newer and more extensible genome browser, which requires that parent features in GFF files (genes) are larger than child features (mRNA, CDS, etc) (Diesh et al., 2023). 

After February 2024: BDH2/YAL061W with expanded start/stop coordinates for ‘gene’, still with rows for longest transcripts expressed in GAL, YPD.

GFF is a standard format used by many groups. SGD uses the GFF file to load the reference tracks in SGD’s genome browser resource.

Updates to SGD search

SGD is jam-packed with information, with new data being added every day. It’s a lot to keep up with, and with so much info, some inevitably ends up hidden from view. To make the various data types in SGD more readily accessible, we have made various improvements to the SGD search: 

• New category for datasets. Over 3700 yeast datasets are accessible. Search by reference, keyword, assay, and lab.
• New Strains subcategory for Reference search. Scroll down to ‘Associated Strains’ in the lefthand menu on the Search Results page.
• Macromolecular complexes can now be searched with aliases. Further refine by reference, subunit, function, process, and location.
• Search for alleles via their descriptions and SGDIDs. Drill down based on reference, allele type, gene, and phenotype.
• RNA products can now be searched using RNAcentral IDs.

microPublications – latest yeast papers

​microPublication Biology is part of the emerging genre of rapidly-published research communications. microPublications publishes brief, novel findings, negative and/or reproduced results, and results which may initially lack a broader scientific narrative. Each article is peer-reviewed, assigned a DOI, and indexed through PubMed and PubMedCentral. 

Consider microPubublications when you have a result that doesn’t necessarily fit into a larger story, but will be of value to others.

Latest yeast microPublications:

• Caligaris M, De Virgilio C (2024) Proxies introduce bias in decoding TORC1 activity. MicroPubl Biol 2024.
• Fromont-Racine M, Khanna V, Jacquier A, Badis G (2024) YLR419W is the homolog of the mammalian translation initiation factor DHX29. MicroPubl Biol 2024.
• Greenlaw A, Dell R, Tsukiyama T (2024) Initial acidic media promotes quiescence entry in Saccharomyces cerevisiae. MicroPubl Biol 2024.
• Harmer ZP, Hohener TC, Landolt AE, Mitchell C, McClean M (2024) Enhancing high-throughput optogenetics: Integration of LITOS with Lustro enables simultaneous light stimulation and shaking. MicroPubl Biol 2024.
• Karpel JE (2024) Caenorhabditis elegans ddx-15 helicase fails to complement loss of Prp43p in Saccharomyces cerevisiae. MicroPubl Biol 2024.
• Medina-Suarez S, Machin F (2024) The CRISPR/Cas9 system forms a condensate in the yeast nucleus. MicroPubl Biol 2024.
• Putnam CD (2024) Loss of mitochondrial DNA is associated with reduced DNA content variability in Saccharomyces cerevisiae. MicroPubl Biol 2024.
• Rosenbaum JC, Carlson AE (2024) The SARS coronavirus accessory protein ORF3a rescues potassium conductance in yeast. MicroPubl Biol 2024.

All yeast microPublications can be found in SGD.

Alliance of Genome Resources – Latest Release 7.2

The Alliance of Genome Resources, a collaborative effort between SGD and other model organism databases (MODs), released version 7.2 in June 2024.

The 7.2.0 release updates the Associated Alleles and Associated Models tables on Disease pages:

• Each table has a new column, Disease Qualifier, with a working filter. The qualifier describes whether an allele or model may be, for example, implicated in the onset of a disease or a model for the severity of a disease, respectively
• In addition to the Disease Qualifier, the Associated Models table now has new columns for Condition Modifier and Genetic Modifier
• The “Annotation Details” pop-up has expanded to include more information.
  • Alleles table: Association, Genetic Modifiers, Genetic Sex, Notes, and Annotation Type
  • Models table: Genetic Sex, Notes, and Annotation Type
• The Associated Models table now has working filters for the Experimental Condition, Condition Modifier, and Genetic Modifier columns, including the ability to filter on relationship (e.g. induced by) as well as content (e.g. “copper”)
• The Download files from the disease page Associated Alleles table and Associated Models table now include additional information as well.
  • New columns and information for the Associated Alleles table include: Allele Association, Genetic Entity Association, Disease Qualifier, Evidence Code Abbreviation, Experimental Conditions, Genetic Modifier Relation, Genetic Modifier IDs, Genetic Modifier Names, Genetic Sex, Notes, Annotation Type, Source URL, and Date.
  • New columns and information for the Associated Models table include: Model Type, Model Association, Disease Qualifier, Evidence Code Abbreviation, Experimental Conditions, Condition Modifiers, Genetic Modifier Relation, Genetic Modifier IDs, Genetic Modifier Names, Genetic Sex, Notes, Annotation Type, Source URL, and Date.

Upcoming conferences and courses

• RCN-UBE: Yeast ORFan Gene Project – Summer Workshop – Gene Expression Analysis
  • June 20 to June 21, 2024
  • Virtual
• FASEB Yeast Chromosome Biology and Cell Cycle
  • June 23 to June 27, 2024
  • Fort Garry Hotel, Winnipeg, Manitoba, Canada
• JCS2024: Diversity and Evolution in Cell Biology
  • June 24 to June 27, 2024
  • Montanya Hotel & Lodge, Catalonia, Spain
• Yeast Genetics & Genomics
  • July 23 to August 13, 2024
  • Cold Spring Harbor Laboratory, Cold Spring Harbor, New York
• Pacific Northwest Yeast Club
  • July 26, 2024
  • Fred Hutchinson Cancer Center, Seattle, WA
• 39th Small Meeting of Yeast Transporters and Energetics (SMYTE)
  • August 28 to September 01, 2024
  • University of York, York, United Kingdom
• ICY2024: 16th International Congress on Yeasts
  • September 29 to October 03, 2024
  • Cape Town International Convention Centre, Cape Town, South Africa
• Yeast2025: 32nd International Conference on Yeast Genetics and Molecular Biology ICYGMB32
  • July 21 to July 24, 2025
  • Sorbonne University, Paris, France

Categories: Newsletter

Reference Genome Annotation Update R64.5

June 19, 2024

The S. cerevisiae strain S288C reference genome annotation was updated. The new genome annotation is release R64.5.1, dated 2024-05-29. Note that the underlying genome sequence itself was not altered. The chromosome sequences remain stable and unchanged.

R64.5 Annotation update summary

This annotation update included (details in table below):

• new ORFs: YDL204W-A, YFR035W-A, YGR016C-A, YMR106W-A, YNL040C-A, YNL155C-A
• new uORFs for existing ORFs: ATG12/YBR217W, ATG19/YOL082W, ATG5/YPL149W, ATG13/YPR185W
• move start downstream: EFM4/YIL064W
• ORF upgraded from Dubious to Verified: YIL059C

R64.5 Annotation update details

Chr	Feature	Description of change	Reference
II	ATG12/YBR217W	New uORF chrII:657824..657835, partially overlaps CDS	Yang Y, et al. (2023) PMID:35363116
IV	YDL204W-A	New ORF chrIV:94133..94285	Wacholder A, et al. (2023) PMID:37164009
VI	YFR035W-A	New ORF chrVI:226260..226550	Wacholder A and Carvunis AR (2023) PMID:38048358
VII	YGR016C-A	New ORF chrVII:523353..523246	Wacholder A, et al. (2023) PMID:37164009, Chang S, et al. (2023) PMID:37927910
IX	EFM4/YIL064W	Move start 84 nucleotides downstream, new coordinates chrIX:242027..242716	Hamey JJ, et al. (2024)PMID:38199565
IX	YIL059C	Change ORF qualifier from Dubious to Verified because stable translation product detected	Wacholder A and Carvunis AR (2023) PMID:38048358
XIII	YMR106W-A	New ORF chrXIII:480924..481187	Wacholder A and Carvunis AR (2023) PMID:38048358
XIV	YNL040C-A	New ORF chrXIV:552558..552478	Wacholder A, et al. (2023) PMID:37164009
XIV	YNL155C-A	New ORF chrXIV:342135..341911	Wacholder A and Carvunis AR (2023) PMID:38048358
XV	ATG19/YOL082W	New uORF chrXV:168632..168679	Yang Y, et al. (2023) PMID:35363116
XVI	ATG5/YPL149W	4 new uORFs: chrXVI:271236..271277, chrXVI:271252..271302, chrXVI:271299..271307, chrXVI:271302..271307	Yang Y, et al. (2023) PMID:35363116
XVI	ATG13/YPR185W	New uORF chrXVI:907211..907351, partially overlaps CDS	Yang Y, et al. (2023) PMID:35363116

Categories: Data updates

Deadline extended to April 22 for the 2024 Yeast Genetics and Genomics Course

April 09, 2024

The application deadline for the 2024 Yeast Genetics and Genomics Course has been extended to April 22 – don’t miss your chance! Significant financial aid may be available for trainees applying, covering up to 50% of the cost of the course!

Find all the details and application form at the CSHL Meetings & Courses site.

For over 50 years, the legendary Yeast Genetics & Genomics course has been taught each summer at Cold Spring Harbor Laboratory, though the name didn’t include “Genomics” in the beginning. The list of people who have taken the course reads like a Who’s Who of yeast research, including Nobel laureates and many of today’s leading scientists.

This year’s instructors – Grant Brown, Soni Lacefield, and Greg Lang – have designed a course (July 23 – August 13) that provides a comprehensive education in all things yeast, from classical genetics through up-to-the-minute genomics. Students will perform and interpret experiments, learning about things like:

• Transformation & Genome Engineering
• Microscopy
• Manipulating Yeast
• Dissecting Tetrads
• Isolating Mutants
• Working with Essential Genes
• Synthetic Genetic Arrays
• Fluctuation Assays
• Whole Genome Sequencing & Analysis
• QTLMapping

Techniques have been summarized in the accompanying course manual, published by CSHL Press.

Who should attend? Scientists who aren’t part of large, well-known yeast labs are especially encouraged to apply – for example, professors and instructors who want to incorporate yeast into their undergraduate genetics classrooms; scientists who want to transition from mathematical, computational, or engineering disciplines into bench science; and researchers from small labs or institutions where it would otherwise be difficult to learn the fundamentals of yeast genetics and genomics.

What else goes on there? Besides its scientific content, the fun and camaraderie at the course is also legendary. In between all the hard work there are late-night chats at the bar and swimming at the beach. There’s a fierce competition between students at the various CSHL courses in the Plate Race, which is a relay in which teams have to carry stacks of 40 Petri dishes (used, of course). There’s also typically a sailboat trip, a microscopy contest, and a mysterious “Dr. Evil” lab!

The Yeast Genetics & Genomics Course is loads of fun – don’t miss out!

Categories: Conferences

Tags: dna, genetics, genomics, science

New user interface for YeastMine

April 04, 2024

Here at SGD we provide high-quality curated genomic, genetic, and molecular information on the genes and gene products of the budding yeast Saccharomyces cerevisiae. Twelve years ago, in order to accommodate the increasingly complex and diverse needs of researchers for searching and comparing data, SGD implemented InterMine, an open source data warehouse system with a sophisticated querying interface, to create YeastMine.

Today’s news is that we have updated YeastMine to use the new BlueGenes user interface from InterMine. The new interface provides the same functionality you’re already familiar with, wrapped in a new design offering a more interactive experience for exploring and analyzing your data. We are making this switch because AllianceMine at the Alliance of Genome Resources, of which SGD is a founding member, is using the updated interface as well.

YeastMine is a multifaceted search and retrieval environment that provides access to diverse data types. Searches can be initiated with a list of genes, a list of Gene Ontology terms, or lists of many other data types. The results from queries can be combined for further analysis and saved or downloaded in customizable file formats. Queries themselves can be customized by modifying predefined templates or by creating a new template to access a combination of specific data types.

User documentation for the new YeastMine interface is available from InterMine.

Categories: Announcements

Tags: user-interface

Changes to Saccharomyces cerevisiae GFF3 file

March 01, 2024

The saccharomyces_cerevisiae.gff contains sequence features of Saccharomyces cerevisiae and related information such as Locus descriptions and GO annotations. It is fully compatible with Generic Feature Format Version 3. It is updated weekly.

After November 2020, SGD updated the transcripts in the GFF file to reflect the experimentally determined transcripts (Pelechano et al. 2013, Ng et al. 2020), when possible. The longest transcripts were determined for two different growth media – galactose and dextrose. When available, experimentally determined transcripts for one or both conditions were added for a gene. When this data was absent, transcripts matching the start and stop coordinates of an open reading frame (ORF) were used. 

Beginning in February 2024, SGD increased the start and stop coordinates of genes to encompass the start and stop coordinates of the longest experimentally determined transcripts, regardless of condition.  This change was made in order to comply with JBrowse 2, a newer and more extensible genome browser, which requires that parent features in GFF files (genes) are larger than child features (mRNA, CDS, etc) (Diesh et al., 2023). 

This is a standard format used by many groups. SGD uses the GFF file to load the reference tracks in SGD’s genome browser resource.

Categories: Announcements, Data updates

Tags: biology, blog, genetics, news, Saccharomyces cerevisiae

Apply Now for the 2024 Yeast Genetics and Genomics Course

February 13, 2024

For over 50 years, the legendary Yeast Genetics & Genomics course has been taught each summer at Cold Spring Harbor Laboratory, though the name didn’t include “Genomics” in the beginning. The list of people who have taken the course reads like a Who’s Who of yeast research, including Nobel laureates and many of today’s leading scientists.

The application deadline is March 31st, so don’t miss your chance!

Find all the details and application form at the CSHL Meetings & Courses site. This year’s instructors – Grant Brown, Soni Lacefield, and Greg Lang – have designed a course (July 23 – August 13) that provides a comprehensive education in all things yeast, from classical genetics through up-to-the-minute genomics. Students will perform and interpret experiments, learning about things like:

• Transformation & Genome Engineering
• Microscopy
• Manipulating Yeast
• Dissecting Tetrads
• Isolating Mutants
• Working with Essential Genes
• Synthetic Genetic Arrays
• Fluctuation Assays
• Whole Genome Sequencing & Analysis
• QTLMapping

Techniques have been summarized in the accompanying course manual, published by CSHL Press.

Who should attend? Scientists who aren’t part of large, well-known yeast labs are especially encouraged to apply – for example, professors and instructors who want to incorporate yeast into their undergraduate genetics classrooms; scientists who want to transition from mathematical, computational, or engineering disciplines into bench science; and researchers from small labs or institutions where it would otherwise be difficult to learn the fundamentals of yeast genetics and genomics.

What else goes on there? Besides its scientific content, the fun and camaraderie at the course is also legendary. In between all the hard work there are late-night chats at the bar and swimming at the beach. There’s a fierce competition between students at the various CSHL courses in the Plate Race, which is a relay in which teams have to carry stacks of 40 Petri dishes (used, of course). There’s also typically a sailboat trip, a microscopy contest, and a mysterious “Dr. Evil” lab!

The Yeast Genetics & Genomics Course is loads of fun – don’t miss out!

Categories: Conferences

SGD Newsletter, December 2023

December 13, 2023

About this newsletter:
This is the December 2023 issue of the SGD newsletter. The goal of this newsletter is to inform our users about new features in SGD and to foster communication within the yeast community. You can view this newsletter, as well as previous newsletters, on the SGD Community Wiki.

Contents

• 1 Reference Genome Annotation Update R64.4
• 2 Full-text search tool Textpresso updated
• 3 Biochemical Pathways now in SGD Search
• 4 microPublications – latest yeast papers
• 5 Updates to SGD’s YeastMine data warehouse
  • 5.1 Allele SGDIDs added to YeastMine
  • 5.2 Downloads files added to YeastMine
• 6 Chemical structures now on Chemical pages in SGD
• 7 Alliance of Genome Resources – Release 6.0
• 8 SGD’s Social Media Footprint is Expanding
• 9 Upcoming Conferences and Courses
• 10 Happy Holidays from SGD!

Reference Genome Annotation Update R64.4

The S. cerevisiae strain S288C reference genome annotation was updated. The new genome annotation is release R64.4.1, dated 2023-08-23. Note that the underlying genome sequence itself was not altered in any way.

This annotation update included:

new uORFs for 3 ORFs:

• FPS1/YLL043W
• ACC1/YNR016C
• HOL1/YNR055C

8 new ncRNAs:

• SUT035/YNCC0015W
• SUT053/YNCD0033W
• SUT468/YNCD0034C
• SUT532/YNCG0047C
• SUT125/YNCG0048W
• SUT126/YNCG0049W
• SUT390/YNCP0025W
• SUT418/YNCP0026W

3 ORFs demoted from ‘Uncharacterized’ to ‘Dubious’ based on request from NCBI because they overlap tRNAs:

• YDR278C
• YOL013W-A
• YPR108W-A

Various sequence and annotation files are available on SGD’s Downloads site. You can find more update details on the Details of 2023 Reference Genome Annotation Update R64.4 SGD Wiki page.

Full-text search tool Textpresso updated

SGD’s instance of Textpresso has recently been updated! Each week, SGD biocurators triage new publications from PubMed to load the newest yeast papers into the database. Once they are in SGD, those papers get indexed and loaded into Textpresso – a tool for full-text mining and searching. 

This is the new part: Content updates in SGD’s Textpresso are now happening on a weekly basis, meaning you can search full text of the very latest yeast papers!

You already love Textpresso for searching full text and its other bells and whistles:

• Search results shown in the context of the full text – hits to query terms highlighted in situ
• Custom corpus creation – you can decide which papers to search
• Search using Boolean operators
• Search scope options for document or sentence
• Search location options can constrain to specific sections of papers

Textpresso can be accessed via the “Full-text Search” link under “Literature” in the purple toolbar that runs across the top of most SGD webpages. Now you can search full text of the very latest yeast papers each week!

Biochemical Pathways now in SGD Search

YeastPathways, which is the database of metabolic pathways and enzymes in the budding yeast Saccharomyces cerevisiae, is manually curated and maintained by the curation team at SGD.

This resource is jam-packed with information, but somewhat hidden from view. To make the pathways more readily accessible, some time ago we added a new section with pathways links on the relevant gene pages. Now the pathways are available in SGD Search!

The category “Biochemical Pathways” is now available, with facets (i.e., subcategories) for References and Loci. For even easier access, we also added the Pathway names and IDs to the autocomplete in the Search box, to enable quick browsing. Enjoy!

microPublications – latest yeast papers

​microPublication Biology is part of the emerging genre of rapidly-published research communications. We are seeing a strong set of microPublications come through the database and are glad for this venue to publish brief, novel findings, negative and/or reproduced results, and results which may initially lack a broader scientific narrative. Each article is peer-reviewed, assigned a DOI, and indexed through PubMed and PubMedCentral.

Consider microPubublications when you have a result that doesn’t necessarily fit into a larger story, but will be of value to others.

Latest yeast microPublications:

• Bennett SA, Cobos SN, Son E, Segal R, Mathew S, Yousuf H, Torrente MP (2023) Impaired RNA Binding Does Not Prevent Histone Modification Changes in a FUS ALS/FTD Yeast Model. MicroPubl Biol 2023
• Chang S, Joyson M, Kelly A, Tang L, Iannotta J, Rich A, Castilho Coelho N, Carvunis AR (2023) Unannotated Open Reading Frame in Saccharomyces cerevisiae Encodes Protein Localizing to the Endoplasmic Reticulum. MicroPubl Biol 2023
• Chen A, Gibney PA (2023) Disruption of GRR1 in Saccharomyces cerevisiae rescues tps1Δ growth on fermentable carbon sources. MicroPubl Biol 2023
• Courtin B, Namane A, Gomard M, Meyer L, Jacquier A, Fromont-Racine M (2023) Xrn1 biochemically associates with eisosome proteins after the post diauxic shift in yeast. MicroPubl Biol 2023
• Delorme-Axford E, Tasmi TA, Klionsky DJ (2023) The Pho23-Rpd3 histone deacetylase complex regulates the yeast metabolic transcription factor Stb5. MicroPubl Biol 2023
• Garcia B, Riley KJ (2023) Saccharomyces cerevisiae NRE1 and IRC24 Encode Paralogous Benzil Oxidoreductases. MicroPubl Biol 2023
• Kowaleski SJ, Hurmis CS, Coleman CN, Philips KD, Najor NA (2023) SHE9 deletion mutants display fitness defects during diauxic shift in Saccharomyces cerevisiae . MicroPubl Biol 2023
• Runnebohm AM, Indovina CJ, Turk SM, Bailey CG, Orchard CJ, Wade L, Overton DL, Snow BJ, Rubenstein EM (2023) Methionine Restriction Impairs Degradation of a Protein that Aberrantly Engages the Endoplasmic Reticulum Translocon. MicroPubl Biol 2023

All yeast microPublications can be found in SGD.

Updates to SGD’s YeastMine data warehouse

Allele SGDIDs added to YeastMine

YeastMine is SGD’s data warehouse, powered by InterMine. We have so many templates (i.e., pre-defined queries) that provide access to so many different kinds of data.

A big area of focus for SGD and the yeast community is alleles. Alleles are different versions of genes that vary in DNA and sometimes protein sequence. Did you know that you can easily and quickly get all curated yeast allele data directly from YeastMine?

The Genes -> Alleles template returns data for one gene or a list of genes or the entire genome! Data include standard and systematic names for genes, gene name descriptions, allele names and descriptions, allele types, aliases, and references. SGDIDs for genes are included, and now SGDIDs for the alleles have been added. Previously, this query returned all of these data without the SGDIDs for the alleles. Based on user feedback, we have now made these allele SGDIDs available, so that they can be used to identify and distinguish different alleles.

Downloads files added to YeastMine

Back in the day, SGD maintained an FTP site to distribute data in various files. More recently, you have found these files in the SGD Downloads site. We have now moved these files to YeastMine:

From the YeastMine homepage, click Templates at top left. In the Filter, select ‘Downloads’ to constrain the list of templates.

The following query templates are listed under Downloads:

• Deleted Merged Features: Retrieve all deleted and merged features.
• Retrieve Functional Complementation for genes: For gene(s), retrieve information about cross-species functional complementation between yeast and another species.
• Retrieve GO Terms: Retrieve GO Terms, including name, ID, namespace, and definition.
• Retrieve SGD chromosomal Features: Retrieve genes and other chromosomal features, including IDs, coordinates, and descriptions.
• Retrieve all cross-references for all genes: Retrieve IDs for yeast gene and gene products in other databases.
• Retrieve all domains of all genes: Retrieve Proteins/Genes that have a given domain.
• Retrieve all interactions for all genes: Retrieve physical and genetic interactions for all genes.
• Retrieve all pathways for all genes: Retrieve all metabolic pathways for all genes.
• Retrieve protein properties of all proteins of ORFs: Retrieve protein properties, including pI, molecular weight, N-terminal and C-terminal sequences, codon bias, etc. of all proteins.

For help using YeastMine, please see the SGD Help Pages and our YeastMine playlist on the SGD YouTube Channel.

Chemical structures now on Chemical pages in SGD

SGD curators use the Chemical Entities of Biological Interest (ChEBI) Ontology, maintained by EMBL-EBI, to describe chemicals used in experiments curated from yeast publications and displayed on SGD webpages.

You may have noticed that we have recently added chemical structures provided by ChEBI to the Chemical pages in SGD! Click the structure to zoom in, click again to zoom back out.

It’s a small detail, but we love this feature, and hope that you do too! Thanks, ChEBI!

Alliance of Genome Resources – Release 6.0

The Alliance of Genome Resources, a collaborative effort between SGD and other model organism databases (MOD), released version 6.0 in September 2023.

Version 6.0 adds new features to gene pages:

• New Paralogy section. Similar to Orthology, the Paralogy data are sourced from the DRSC’s DIOPT tool, which lets you view predictions from several tools at one time. Each table is ranked based on similarity, identity, alignment length, and a count of algorithms (methods) used to predict a paralogous match. See human HSPA1A gene page for an example.
• New Sequence Detail section. For different transcripts of the gene, you can choose to view the sequence for the gene, or its CDS, cDNA, protein, gene with collapsed introns, or genomic sequence with or without 500 bp up and downstream.
• Disease Qualifier. The qualifier describes whether a gene may be, for example, a marker_for the onset of a disease, or implicated_in the severity of a disease.
• Disease “Annotation details”. The pop-up for individual table rows has expanded to include Association, Additional Implicated Genes, Genetic Modifiers, Strain Background, Genetic Sex, Notes, and Annotation Type.
• The Download file from the gene page disease table now includes fields for Additional Implicated Gene ID, Additional Implicated Gene Symbol, Gene Association, Genetic Entity Association, Disease Qualifier, Evidence Code Abbreviation, Experimental Conditions, Genetic Modifier Relation, Genetic Modifier IDs, Genetic Modifier Names, Strain Background ID, Strain Background Name, Genetic Sex, Notes, Annotation Type, and Source URL.
• The Source column entries now link back to their respective resource webpages.

SGD’s Social Media Footprint is Expanding

Discourse, Mastodon, BlueSky – oh my! Social media is in a chaotic period, with once tight-knit communities having been dismantled and thrown into the ether. SGD feels your pain; we have been searching for our audience, waiting for the stardust to settle, coagulate, coalesce…. In the interim, in an effort to reach you, we have set up SGD outposts on various platforms:

Discourse: The Alliance of Genome Resources Community Forum brings together communities of the major model organisms – yeast, worm, fly, zebrafish, frog, rat, and mouse – in one place. Users can create accounts to post announcements and questions, and chat with other researchers in a science-focused arena. Contact SGD for an invited account, which has additional permissions.

Mastodon: We’re just getting started with Mastodon; follow SGD at @yeastgenome@genomic.social

BlueSky: We’ve also just begun with BlueSky; follow SGD at @yeastgenome.bsky.social

We will be cross-posting to the various accounts – come find SGD on these platforms and we can navigate this latest social media adventure together!

Upcoming Conferences and Courses

• TAGC2024 The Allied Genetics Conference
  • National Harbor | Washington DC Metro Area
  • March 05 to March 10, 2024
• 32nd Fungal Genetics Conference
  • Asilomar Conference Grounds, Pacific Grove, CA
  • March 12 to March 17, 2024
• 16th Yeast Lipid Conference
  • Saarland University, Homburg, Germany
  • May 29 to May 31, 2024
• JCS2024: Diversity and Evolution in Cell Biology
  • Montanya Hotel & Lodge, Catalonia, Spain
  • June 24 to June 27, 2024
• 39th Small Meeting of Yeast Transporters and Energetics (SMYTE)
  • University of York, York, United Kingdom
  • August 28 to September 01, 2024
• ICY2024: 16th International Congress on Yeasts
  • Cape Town International Convention Centre, Cape Town, South Africa
  • September 29 to October 03, 2024

Happy Holidays from SGD!

We want to take this opportunity to wish you and your family, friends and lab mates the best during the upcoming holidays. Stanford University will be closed for two weeks starting December 21, reopening on January 4th, 2024. Although SGD staff members will be taking time off, the website will be up and running throughout the winter break, and we will resume responding to user requests and questions in the new year.

Note: If you no longer wish to receive this newsletter, please contact the SGD Help Desk at sgd-helpdesk@lists.stanford.edu.

Categories: Newsletter

Tags: Newsletter

Search full-text with Textpresso: new papers added weekly

December 06, 2023

SGD’s instance of Textpresso has recently been updated! Each week, SGD biocurators triage new publications from PubMed to load the newest yeast papers into the database. Once they are in SGD, those papers get indexed and loaded into Textpresso – a tool for full-text mining and searching. This is the new part: Content updates in SGD’s Textpresso are now happening on a weekly basis, meaning you can search full text of the very latest yeast papers!

You already love Textpresso for searching full text and its other bells and whistles:

• Search results shown in the context of the full text – hits to query terms highlighted in situ
• Custom corpus creation – you can decide which papers to search
• Search using Boolean operators
• Search scope options for document or sentence
• Search location options can constrain to specific sections of papers

Textpresso can be accessed via the “Full-text Search” link under “Literature” in the purple toolbar that runs across the top of most SGD webpages. Now you can search full text of the very latest yeast papers each week!

Categories: Announcements

Fpt1p is a negative regulator of RNA Polymerase III embedded in the tDNA chromatin-proteome

November 27, 2023

Gene transcription is facilitated by RNA polymerase enzyme complexes that collaborate with transcription factors, repressors, chromatin remodelers, and other cellular factors. RNA Polymerase III (RNAPIII) mainly transcribes short DNA fragments called tDNAs, that code for transfer-RNAs (tRNAs). In repressive conditions, tDNA transcription is repressed by the well-characterized protein Maf1. A new study by Van Breugel et al., recently published in Molecular Cell, identified Fpt1p (YKR011C) as an additional regulator of RNAPIII in S. cerevisiae.  

By using Epi-Decoder, a technique based on synthetic genetic array (SGA), chromatin immunoprecipitation and DNA-barcode sequencing, the local chromatin-proteome of a single tDNA was decoded in active and repressive conditions. The authors found major reprogramming of the core RNAPIII transcription machinery and other known chromatin-binding proteins. Surprisingly, they found the protein Ykr011c to be enriched in the tDNA chromatin-proteome, especially under repressive conditions, prompting the authors to rename the gene FPT1 (Factor in the Proteome of tDNAs number 1).

Following up on the Epi-Decoder finding, genome-wide sequencing methods such as ChIP-seq and ChIP-exo revealed that Fpt1p uniquely binds RNAPIII-regulated genes. Using the anchor away system to conditionally deplete core RNAPIII transcription factors from the nucleus, Fpt1 binding to tRNA genes was found to require both TFIIIB and TFIIIC but not RNAPIII or ongoing transcription. tRNA genes have been described to differentially respond to repressive signals but gene-specific regulatory mechanisms have largely remained elusive. Looking at Fpt1p, Van Breugel et al. found a correlation between tDNA responsiveness to repressive signals and Fpt1p occupancy, suggesting a negative regulatory role for Fpt1p. Substantiating these results, FPT1 knockout strains showed increased occupancy of RNAPIII and TFIIIB at tRNA genes, while TFIIIC occupancy decreased. These outcomes point towards a role for Fpt1p in promoting eviction of RNAPIII upon repressive signals. 

In summary, taking advantage of multiple yeast genetic approaches, Van Breugel et al. found that the previously uncharacterized protein Fpt1 is a bona fide RNAPIII regulator in S. cerevisiae. Their research emphasizes the importance of not overlooking uncharacterized proteins, as they may possess alternative regulatory roles that could change our views on fundamental cellular processes.

Text and image provided by Marlize van Breugel, MSc.

Categories: News and Views

Tags: RNA polymerase III, Saccharomyces cerevisiae

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