Gene Ontology - yeast cell cycle examples

Exercise written by: Rasmus Wernersson

Purpose of this exercise:

• Understand how Gene Ontology terms are defined and organized:
  • The relationship between GO terms (IS A, PART OF, etc)
  • The three main trunks of GO: BIOLOGICAL PROCESS, MOLECULAR FUNCTION and CELLULAR COMPONENT.
• Learn how to query the Gene Ontology database.
  • Using the official online GO query system: AmiGO
  • Using links from Saccharomyces Genome Database (SGD).
  • Using links from UniProt.
• Understand the theory behind GO over-representation analysis
• Learn how to perform GO over-representation analysis:
  • Using the R package "fgsea"

Part 1a: using the Gene Ontology terms and tools

The Gene Ontology database contains a collection of strict definitions of biological terms, and information about how the terms relate to each other (for example DNA replication is a biosynthetic process which in turn is a biological process). The Gene Ontology system is divided into three main trunks:

1. Biological Process (e.g. DNA replication)
2. Molecular Function (e.g. DNA binding)
3. Cellular Component (e.g. Nucleus).

Each term has a UNIQUE IDENTIFIER - much in the same way, as we have it with gene identifiers in SGD (e.g. YDR224C) and protein identifiers in UniProt (e.g. POLD1_HUMAN). The Gene Ontology was created to provide a standardized way to characterize the functionality of genes (hence the name) and gene products (protein). The idea is much the same as with UniProt keywords (see the 27611 UniProt exercise for details): to have a standard set of labels that can be used to describe the gene/protein functionality: this will both 1) make it much easier to search gene/protein databases, and 2) make it much easier to perform large scale comparisons of genes/proteins.

LINKS:

• Database look-up:
  • http://www.geneontology.org - the home of the Gene Ontology project
  • http://amigo.geneontology.org - the AmiGO search system (the official search engine for the project)
  • http://www.ebi.ac.uk/QuickGO - An alternative search system for Gene Ontology, created and maintained by the EBI. They provide a nice graphical representation of the GO trees.
• Overrepresentation analysis:
  • The R package "fgsea" for over representation analysis, and the R package "msigdbr" for retrieving genesets

Example: "Cell division"

Gene Ontology provides a wealth of information, to the point where it can be a bit intimidating at first (it can be difficult to see the forest for all the trees). Before we start browsing the full online database, we will start out with a simple example, where we'll highlight some of the most important features, and for a moment hide the rest:

Term: Cell division

Accession	GO:0051301
Ontology	Biological Process
Definition	The process resulting in the physical partitioning and separation of a cell into daughter cells.
Comment	Note that this term differs from 'cytokinesis ; GO:0000910' in that cytokinesis excludes nuclear division; in prokaryotes, there is little difference between cytokinesis and cell division. Note that there is no relationship between this term and 'nuclear division ; GO:0000280' because cell division can take place without nuclear division (as in prokaryotes) and vice versa (as in syncytium formation by mitosis without cytokinesis.

Example of the definition of a GO term ("Cell division" ; GO id: 0051301) in the biological process category, and a graph showing it's relationship to other GO terms. Note that there are 7 different types of relationships defined. The most common one is the IS A relationship.

TASK: investigate "cell division" using AmiGO 2

• Select Search -> Ontology from the top menu.
• Search for the term "cell division", and click on the entry for "cell division" at the top of the results list.
• Spend some time getting familiar with the entry page:
  • The top part contains the definition(s) related to this particular entry.
  • The lower part contains information about how this entry relates to OTHER entries. Try clicking on the various tabs, such as "Graph Views".

REPORT QUESTION #1:

• How many ancestor terms are defined? With how many different types of relationships?
• How many children terms are defined? With how many different types of relationships?

Cellular Component examples

The "Cellular Component" part of Gene Ontology is good for illustrating the concept of nested terms in more details, since it's easy to visualize the boxes-in-boxes concept here.

For example: The Nucleolus (the organelle for synthesis and maturation of Ribosomal RNA) is located WITHIN the nucleus which is located WITHIN the cell. While this seems trivial and evidently true, it's important to realize the concept of inherited properties within a hierarchical structure.

It's much the same case as we have previously seen with taxonomy in course 27611 - for example, if you look up Human (Homo sapiens) and Mouse (Mus musculus) in NCBI Taxonomy, the abbreviated lineages look like this:

Eukaryota › Metazoa › Chordata › Craniata › Vertebrata › Mammalia › Primates › Hominidae › Homo
Eukaryota › Metazoa › Chordata › Craniata › Vertebrata › Mammalia › Eutheria › Muroidea ›  Mus

In the GO terminology these are IS A relationships: From this we can see that all humans are primates, and all primates are mammals, but all mammals are NOT (necessarily) human.

TASK: investigate the nucleus in GO

• Look up "nucleus" (GO:0005634) in AmiGO.
  • Hint: if you get a lot of hits that are not what you are looking for, try putting your query inside quotation marks ("").

REPORT QUESTION #2:

• Is "nucleus" a membrane-bound, or non membrane-bound organelle? On which linked GO terms do you base this conclusion?
• What types of relationships are found?

IS A vs. PART OF: So far we have been focusing on the "IS A" relationship (nucleus IS A organelle which in turn IS A cellular component). However, things get a bit more complicated, when we bring the "PART OF" relationship into the picture, as the next example will show.

Molecular Function examples

Continuing with our focus on cell cycle and DNA replication, investigate the following terms:

1. DNA Polymerase Activity
2. Helicase Activity

REPORT QUESTION #3: answer the following questions:

• Can the activities described be directed towards both DNA and RNA? Remember add your arguments
• At which node does the "tree" branch out of the "Molecular Function" ontology and into a different ontology? With what type of relationship? Does this make biological sense?

(A few more) Biological Process examples

Next up we'll investigate how the different phases of the cell cycle have been categorized in GO.

• Start out by looking up the entry for the G1 phase: GO:0051318

From here you'll need to investigate the "neighborhood" of terms to answer the questions below - ask the instructor for help if you get stuck.

REPORT QUESTION #4: Mitosis related questions: (ignore meiosis for now)

• How many (if any) cell cycle sub-phases are defined for:
  • G1 phase
  • S phase
  • G2 phase
  • M phase
• Which phases are grouped together into the "interphase" term?

REPORT QUESTION #5: Meiosis related question: During meiosis the sister chromatids can exchange DNA in a process called "homologous chromosome pairing at meiosis" - you may have heard this described as "Chromosome Crossover" as well (technically crossing over is the method by with the process happens).

• In which meiotic cell cycle phase does homologous chromosome pairing at meiosis happen?

Part 1b: GO annotations on Genes and Proteins

As was mentioned earlier, Gene Ontology was created to provide a standardized set of "keywords" for annotating the function of genes and proteins. We'll now have a look at how GO is actually used in large sequence databases.

Saccharomyces Genome Database

TASK/REPORT QUESTION #6: Look the entry for POL1 (YNL102W) in SGD

• Notice that all Saccharomyces Genome Database (SGD) entries have an entire section on Gene Ontology annotations; click on the "Gene Ontology" tab for full details. This actually include a bit of extra information about the evidence for annotations.
• What is the Molecular Function for POL1?
• Click on the link for this term to see how SGD describes the GO term, and how the evidence is presented.
  • How many other yeast genes are ALSO annotated to have "DNA-directed DNA polymerase activity"?

IMPORTANT: SGD also offers the possibility to jump from their website to the same GO term inside AmiGO. This is very useful for investigating the hierarchy of GO terms "above" - SGD has limited functionality for this.

TASK/REPORT QUESTION #7: Follow the link to AmiGO

• Follow the link to AmiGO for the Molecular Function term found above, and answer the following question:
  • Does POL1 have "Transferase Activity"? (Which GO term).

UniProt

UniProt uses a lot of its own annotation - for example the UniProt keywords we learned to use in course 22111. However, the protein entries are also annotated with GO terms.

TASK/REPORT QUESTION #8: look up human POLD1 in UniProt:

• Entry name: DPOD1_HUMAN or P28340.
• Locate the "Function" and "Subcellular Location" sections.
• Gene Ontology:
  • Select a GO term you think looks interesting and click on it - this will take you to EBI's own interface to GO.
  • Click through the tabs, and see what type of information is there.
  • Notice that there is NO direct link to AmiGO, but you can always copy+paste the GO identifier into AmiGO, if you want to investigate the term using a more familiar interface.
• Questions (requires a bit of detective work - ask the instructor if you get stuck):
  • How many UniProt proteins are annotated with "GO:0045004 DNA replication proofreading"?
  • How many of these are human? (TaxID: 9606 - use the filtering function, if you don't want to count them).

Part 2: Gene Ontology overrepresentation analysis

In this part of the exercise, we focus on performing analysis for overrepresentation in GO. We are interested in knowing if a chosen subset of genes/proteins has any special characteristics, compared to what would be expected if we picked a similar sized subset randomly from the entire pool of genes/proteins.

Study group:

• The subset (study group) could be a set of overexpressed genes from a microarray experiment, or simply a list of genes which you for other reasons expect to be involved in the same biological process.

Population group:

• The population group would then be defined as the background to compare to - e.g. the entire list of genes, or in the case of gene expression all genes represented on the microarray. We can then ask if the frequency of proteins annotation to a GO term is different for the study group compared to the overall population.

Enrichment analysis - reexamining cluster #1

Before we move on to the more advanced statistical methods, we'll spend a moment answering the following questions:

• Is the observed frequency of a given characteristic different from the expected frequency ?

The steps to do this is simply to

1. Calculate the frequency across the entire population group (X number of genes with the characteristic in a total population of Y: FX = X/Y).
2. From this frequency calculate expected genes/protein with this characteristic in the study group (n = size of study group; exp = FX * n)
3. Compare to the observed frequency
4. The enrichment is then calculated as the ratio with observed/expected

We'll go through this with an example: in this case we want to examine whether the proteins in Cluster #1 (from last week's exercise) are overrepresented in any of the following three GO terms: "DNA replication", "DNA repair" and "Cell cycle".

All proteins in Cluster #1 are listed in the table below with a mark if they are associated with a GO term:

Systematic name	Gene name	Description	DNA replication (GO:0006260)	DNA repair (GO:0006281)	Cell cycle (GO:0007049)
YMR078C	CTF18	Chromosome transmission fidelity protein 18	X	X	X
YPR175W	DPB2	DNA polymerase epsilon subunit B	X	X	X
YBR278W	DPB3	DNA polymerase epsilon subunit C	X	X
YBL035C	POL12	DNA polymerase alpha subunit B	X
YNL102W	POL1	DNA polymerase alpha catalytic subunit A	X
YNL262W	POL2	DNA polymerase epsilon catalytic subunit A	X	X
YOR144C	ELG1	Telomere length regulation protein ELG1	X	X	X
YPR167C	MET16	Phosphoadenosine phosphosulfate reductase
YIR008C	PRI1	DNA primase small subunit	X
YKL045W	PRI2	DNA primase large subunit	X
YOR217W	RFC1	Replication factor C subunit 1	X	X	X
YJR068W	RFC2	Replication factor C subunit 2	X	X	X
YNL290W	RFC3	Replication factor C subunit 3	X	X	X
YOL094C	RFC4	Replication factor C subunit 4	X	X	X
YBR087W	RFC5	Replication factor C subunit 5	X	X	X
YCL042W	YCL042W	Putative uncharacterized protein YCL042W

In the table below are the total number of proteins listed that are involved in the three GO categories "DNA replication", "DNA repair" and "Cell cycle" across the entire yeast genome

GO term	# genes (including subgroups)
DNA replication (GO:0006260)	96
DNA repair (GO:0006281)	259
Cell cycle (GO:0007049)	313

TASK/REPORT QUESTION #9: Assuming yeast has 5500 annotated genes calculate/report the following values:

1. Population group size
2. Study group size
3. Genome wide frequency of each GO term
4. Expected number of genes annotated with each term in a random selection of yeast genes of the same size as cluster #1
5. The enrichment of observed GO terms compared to expected
6. The p-value for each GO term
7. The biological interpretation of the analysis

The p-values can be calculated using an online calculator such as this one.

• 2021 update:: We are testing a new online calculator this year: https://www.medcalc.org/calc/fisher.php

Automated analysis using "fgsea" and "msigdbr"

Introducing over representation in R

For the final part of the exercise, we'll be using an automated tool for comparison of an input gene list (target list) against a background distribution consisting of the entire yeast genome (background list). The "fora" function from "fgsea" can be used to calculate p-values for all gene sets within a list of gene sets. We can use the "msigbdr" package to download gene sets for:

• Biological Processes
• Molecular Functions
• Cellular Components

The results are returned as tables with p-values, gene set size, and the size of the overlap between the gene set and the target list. Finally it's worth mentioning, that the "fora" function also takes care of multiple testing correction, an important problem for large scale data analysis, which we will re-visit in greater details in a later exercise.

Preparing input data

First we need to prepare our input data. An over representation analysis, we need three inputs 1) a target gene list of interest, 2) a background gene list, and 3) the gene sets we wish to examine for over representation.

Target gene list

we'll use Cluster #1 from last week's exercises as example. You can find clusters 1-8 in the node attribute table from last week's exercise, and clusters 9-10 in your solutions (also included in the Rdata object for this week's exercises).

Background list ("population group")

The background here will be the entire yeast genome - a list containing ALL yeast gene names. We have prepared such a list, and included it in the exercise5.Rdata object.

load("/home/projects/22140/exercise4.Rdata")
load("/home/projects/22140/exercise5.Rdata")

Gene ontology gene sets

The gene ontology gene sets can be downloaded from the "molecular signatures database" (msigdb) using the R package "msigdbr" using the following command:

library(msigdbr)
BP_df = msigdbr(species = "S. cerevisiae", category = "C5", subcategory = "BP")

This command retrieves biological process gene sets for yeast. The "C5" category is the msigdb annotation for the three gene ontologies. The subcategory is either "BP" (biological process), "MF" (molecular function), or "CC" (cellular component).

Before we proceed, take a moment to explore the functions "fora" and "msigdbr". In particular, take a look at what object class the "fora" function expects the gene sets to be, and what object class is produced by "msigdbr" with the command above?

TASK/REPORT QUESTION #11: Can you directly use the gene sets produced by the msigdbr function as input for the "fora" function of "fgsea"? Why/why not?

Run the following one-liner to prepare the biological process gene sets for over representation analysis using "fora".

BP_list = split(x = BP_df$ensembl_gene, f = BP_df$gs_name)

Running "fora" Take a look at the background list and any one of the gene sets of the BP_list. Then, extract cluster 1 genes from the node annotation table as your target list, taking care to include the gene identifier that matches the identifier used in the gene sets and background.

Take a look at the results. As mentioned, "fora" produces a table with p-values, adjusted p-values, gene set size, and the size of the overlap between the gene set and the target list, but not the enrichment.

Calculate the enrichment and add a column to your results table.

TASK/REPORT QUESTION #12: Run the analysis for cluster #1 for all three GO trunks (Biological Process, Molecular Function and Cellular Component), and include top 10 significantly enriched GO terms for each ontology. Add a section to your report discussing if the results fit with what we have previously learned about the function of cluster #1.

Repeat analysis on selected clusters

As the final task of today's exercise we'll be re-visiting the 10 clusters from last week's exercise. Pick the 3 clusters which appear the most interesting to you.

TASK/REPORT QUESTION #12: perform the following over-representation analysis and create a short report documenting you finding:

• Biological Process
• Molecular function
• Cellular component
• Question:
  • Do the results make biological sense?
  • How do these results compare to the broad categories we observed in the previous exercise?