Normalized cDNA libraries improve the quality of yeast two-hybrid screens
Abundant housekeeping genes are removed from the library
Lowered occurrence of false positives in screens
Increased chances of identifying rare interactors of your protein of interest
A few abundant transcripts dominate RNA populations
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Typical eukaryotic mRNA populations consist of three abundance classes:
High abundance transcripts
High abundance transcripts include mainly housekeeping genes, such as GAPDH, actins and components of the transcriptional and translational machinery. They are expressed at very high levels - housekeeping genes make up 80-90% of all mRNAs in a cell. They represent the most frequent class of false positive interactions in yeast two-hybrid screens.
Medium abundance transcripts
These transcripts vary depending on the cell type and make up 10-20% of all mRNAs.
Low abundance transcripts
Low abundance transcripts encode many of the key signalling proteins of a cell. They are transcribed at very low levels, making up less than 1% of the total mRNA population. Yet, they encode key components and are often the main targets of protein interaction hunts.
Constructing cDNA libaries which represent low abundance transcripts is the central challenge of yeast two-hybrid screening.
Normalization of mRNA samples
A double stranded cDNA sample is normalized based on differential re-association kinetics after denaturation, since abundant transcripts re-associate faster than rare ones. Transcripts are denatured and then reannealed under carefully controlled conditions. The reannealing process is stopped after a short time, when the majority of abundant transcripts have reformed into double stranded cDNA, whereas rare transcripts are still single stranded.
Subsequently, double stranded cDNA is removed by digestion, the remaining transcripts are denatured again, and annealed to double stranded cDNA. The resulting cDNA population is normalized, i.e. the majority of abundant transcripts has been removed.
Finally, the normalized cDNA sample is size selected and ligated into the appropriate yeast two-hybrid vector.
Yeast two-hybrid screen using a normalized human universal cDNA library
Two sets of yeast two-hybrid screens were carried out using an N-terminally truncated form of human p53 as a bait. For screening, we used two libraries:
- A standard (non-normalized) human colon library
- A normalized human universal library
The parameters of the screens and the resulting interactors are shown in the table below.
Parameter | Non-normalized screen | Normalized screen |
|---|---|---|
Bait | human p53 | human p53 |
Library | human colon | human universal normalized |
Screens carried out | 3 | 1 |
Number of clones screened | 43 million | 3.5 million |
Number of interactors | 436 | 43 |
High stringency interactions | 0 | 12 |
Known interactors | 1 | 3 |
The results show that significantly fewer clones have to be screened with a normalized library to identify relevant, high stringency interactions. Simultaneously, many low stringency false positive interactions are removed (compare the number of primary interactions), resulting in an overall "cleaner" screen.
Despite a significantly lower coverage (3.5 million clones vs. 43 million clones), three known interactors of p53 were identified from the normalized cDNA library:
- Protein tyrosine phosphatase type IVA 2
- E3 SUMO ligase PIAS2
- E3 SUMO ligase Topors
