Results and Discussion

To evaluate the quantitative merits of the multiplexed global proteomics approach, and to justify its utility in quantitative translation needed for system pharmacokinetics, we compared transporter protein levels in human liver samples acquired from TMT data to the abundances determined by validated targeted proteomic methods. For this comparison, TMT data obtained from two independent laboratories with different sample processing protocols were used.

Surrogate peptide abundance levels of the major hepatic uptake transporters involved in drug disposition, namely NTCP, OAT2, OAT7, OATP1B1, OATP1B3, OATP2B1, and OCT1, were measured in four human liver tissue samples. All these transporters were detected in the liver tissue samples analyzed with measured abundances within the ranges observed in previous studies (Kimoto et al., 2012; Qiu et al., 2013; Peng et al., 2015; Wang et al., 2015). For the four samples included in this study, NTCP showed ∼6-fold intersubject variability, whereas the variability of the other transporters was ∼2- to 3-fold (Table 1).

Human liver tissue samples from the same donors included in the targeted proteomic quantification were analyzed in two separate TMT experiments, performed in two independent laboratories. The samples were analyzed in technical duplicates. Very high correlations (Pearson r > 0.99) in MS3 intensities for the replicate measurements were observed, indicating a good precision of the TMT method. More than 5000 proteins were identified in each TMT experiment, demonstrating a sufficient depth of analysis for the TPA-based quantification of protein abundances (Wiśniewski, 2017). Among the identified proteins were the seven uptake transporters of interest (Table 1). For laboratory 1, however, NTCP was not detected in MS3 mode and, thus, MS2 data were used instead. The lack of NTCP detection in MS3 mode was likely a result of the shorter MS acquisition time for this TMT experiment compared with the other one (24-hour compared with 36-hour). Moreover, because of the stochastic element of precursor ion fragmentation in data-dependent acquisition mode, proteins of interest are not always identified in complex samples (Tabb et al., 2010). This is especially true for less abundant proteins, such as NTCP, when the selection criterion for fragmentation is chosen on the basis of peptides with the highest signal abundances. To increase the probability of identifying the proteins of interest, enrichment through subcellular fractionation is possible, although isolated fractions are reported to be associated with lower yields than expected (Wiśniewski et al., 2016; Wegler et al., 2017). Another option is to perform data-independent acquisition on the proteome-scale using a recently introduced technique known as SWATH-MS (Gillet et al., 2012).

The calculated protein abundances from the TMT experiments were compared with the targeted protein quantifications (Fig. 1). For this comparison, a membrane-to-total protein ratio of 0.233 (in-house data, n = 42) was used to convert the measured abundances to the same unit. The TMT data showed good-to-excellent correlations (Pearson r = 0.74–1.00) to the targeted proteomic data (Fig. 1, A–G). We attribute this cross-laboratory agreement to the confident identification of peptides in the TMT experiments and to the thorough analytical validation of the targeted proteomic assays to avoid false positive identifications caused by matrix interference (Balogh et al., 2012; Qiu et al., 2013; Carr et al., 2014). The good correlations observed in our study are in stark contrast to the predominantly poor correlations of transporter and enzyme protein levels across laboratories reported elsewhere (Achour et al., 2017; Wegler et al., 2017). In such cases, correlations with activity measurements are necessary to determine which proteomic methodology results in expression data that align with functional activity. Unfortunately, it is not possible to measure transport activities in frozen liver tissue samples.

• Download figure
• Open in new tab
• Download powerpoint

Fig. 1.

Comparison of protein quantifications by multiplexed global proteomics (y-axis) and targeted proteomics (x-axis). Cross-laboratory correlation analysis of protein abundance measurements for NTCP (A), OAT2 (B), OAT7 (C), OCT1 (D), OATP1B1 (E), OATP1B3 (F), and OATP2B1 (G). Data are presented as arithmetic means with standard deviations (n = 3 for the targeted proteomic data, n = 2 for the TMT data). r = Pearson correlation coefficient. Quantitative agreement of protein abundances calculated from the multiplexed global proteomic data to those measured by targeted proteomics (H). The solid line represents the line of unity, dotted lines represent 2-fold deviations, dashed lines represent 3-fold deviations, and the dot-dash lines represent 5-fold deviations. LC-MS/MS/MS run time was 24 hours for laboratory 1 and 48 hours for laboratory 2. NTCP was not detected in MS3 mode for laboratory 1, and hence, MS2 data were used instead.

In addition to the excellent correlations of measured protein concentrations across methods observed in our study, the transporter abundances calculated from the TMT data resulted in values comparable to those measured by targeted proteomics with absolute fold errors within 3-fold for 71% and 86% of the data set for the two TMT experiments, respectively (Fig. 1H). Furthermore, the range (interindividual variability) in protein expression was very similar across methods (Table 1), suggesting that the multiplexed global proteomic approach can be used to reliably detect differences in protein levels across samples.

The better quantitative agreement for laboratory 2 suggests that longer run-times are required for more reliable quantifications. This observation is in agreement with the finding that higher quantification accuracy is obtained when proteins are identified by a larger number of peptides (Wiśniewski and Rakus, 2014). Differences in the sample processing protocols, including the use of sequential enzymatic digestion with Lys-C and trypsin (laboratory 2) compared with digestion with trypsin alone (laboratory 1), can also add to the quantitative differences observed, when the former is expected to reduce missed cleavages and enhance protein sequence coverage (Guo et al., 2014).

To further assess the accuracy of the TPA-based quantifications, we compared the abundances of cytochrome P450 (CYP) and UDP-glucuronosyltransferase (UGT) drug-metabolizing enzymes with literature data (Fig. 2). Most of the enzyme quantifications fell within the ranges reported in literature. In addition, there was a good quantitative agreement between the two different TMT experiments with an average absolute fold error of 2.1 for the CYP enzymes and 3.5 for the UGT enzymes, respectively.

• Download figure
• Open in new tab
• Download powerpoint

Fig. 2.

Comparison of cytochrome P450 (A) and UGT (B) enzyme abundances, quantified by multiplexed global proteomics, to the range (white bars) and weighed mean (solid gray line) from two recent meta-analyses (Achour et al., 2014a,b).

In summary, our results suggest that multiplexed global proteomic experiments with sufficient proteome coverage can provide reasonable estimates of protein concentrations, as demonstrated with a set of major hepatic uptake transporters, as well as drug-metabolizing enzymes. More importantly, such experiments accurately capture differences in protein levels across samples and may thus be used to compare in vitro and in vivo expression for IVIVE exercises. The global proteomic approach also supports the simultaneous quantification of thousands of other proteins, thus providing a much larger dataset than that obtained by targeted proteomics. Such data can, for example, be useful when studying the age-, gender-, ethnicity-, disease-, and drug-dependent expression of transporters and other drug disposition-related proteins in various tissues or when assessing the appropriateness of an in vitro model compared with the in vivo counterpart. Our study is the first to present evidence suggesting that MS3 intensities from TMT experiments can be applied to TPA-based protein quantifications. Additional validation employing the multiplexed global proteomic approach presented herein can further strengthen its application in quantitative proteomics.