Abstract
We developed an integrated proteomic approach to decipher in vivo protein-protein interactions and applied this strategy to globally map the 26 S proteasome interaction network in yeast. We termed this approach QTAX for quantitative analysis of tandem affinity purified in vivo cross-linked (X) protein complexes. For this work, in vivo formaldehyde cross-linking was used to freeze both stable and transient interactions occurring in intact cells prior to lysis. To isolate cross-linked protein complexes with high purification efficiency under fully denaturing conditions, a new tandem affinity tag consisting of a hexahistidine sequence and an in vivo biotinylation signal was adopted for affinity-based purification. Tandem affinity purification after in vivo cross-linking was combined with tandem mass spectrometry coupled with a quantitative SILAC (stable isotope labeling of amino acids in cell culture) strategy to carry out unambiguous protein identification and quantification of specific protein interactions. Using this method, we captured and identified the full composition of yeast 26 S proteasome complex as well as the two known ubiquitin receptors, Rad23 and Dsk2. Quantitative mass spectrometry analysis allowed us to distinguish specific proteasome-interacting proteins (PIPs) from background proteins and led to the identification of a total of 64 potential PIPs of which 42 are novel interactions. Among the 64 putative specific PIPs, there are ubiquitin pathway components, ubiquitinated substrates, chaperones, and transcription and translation regulators, demonstrating the efficacy of the developed approach in capturing in vivo protein interactions. The method offers an advanced technical approach to elucidate the dynamic protein interaction networks of the proteasome and can find a wide range of applications in the studies of other macromolecular protein complex interaction networks.
Highlights
Proteins—The last groups of proteins with relative abundance ratios ranging from 0.8 to 1.5, i.e. close to 1, are considered background proteins due to nonspecific interactions
To use a tandem affinity purification compatible with in vivo crosslinking under fully denaturing conditions, we adapted a new tandem affinity tag (HB tag) that has been developed to purify covalently linked proteins such as ubiquitinated or sumoylated proteins
We have presented a novel integrated proteomics approach, QTAX, for the analysis of protein complexes including transient and weak interaction partners that has been successfully applied to decipher the 26 S proteasome interaction networks from budding yeast in vivo
Summary
Proteins—The last groups of proteins with relative abundance ratios ranging from 0.8 to 1.5, i.e. close to 1, are considered background proteins due to nonspecific interactions. The first peptide sequence was determined as EGDDVADAFQR and matched to pyruvate carboxylase Pyc with a ratio of 1.12 (Fig. 4E), and the second was identified as YAQDGAGIER and matched to the 60 S ribosomal subunit Rpl with a ratio of 1.16 (Fig. 4F). Our results show that the ratios of different peptides resulting from the same proteins and the ratios from different proteins in this group are reproducible within experimental error. Based on the relative abundance ratio (ϳ1), it is easy to identify these background proteins. It is worth mentioning that three previously reported putative PIPs, Acc, Ilv, and Shm2 [7], had relative abundance ratios close to 1, indicating that under our experimental conditions they are likely nonspecific interacting proteins
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