Systematical evaluation of the effects of sample collection procedures on low-molecular-weight serum/plasma proteome profiling.

Blood is an ideal source for biomarker discovery. However, little has been done to address the effects of sampling, handling and storage procedures on serum/plasma proteomes. We used magnetic bead-based MALDI-TOF MS to systematically evaluate the influence of each procedure on low-molecular-weight serum/plasma proteome profiling on the basis of the whole spectra. We found that sampling procedures, including the selection of blood collection tubes and anticoagulants, variations in clotting time or time lag before centrifugation, and hemolysis, displayed significant effects on the proteomes. Moreover, serum and plasma were mutually incompatible for proteome comparison. By contrast, overnight fasting, handling procedures, including centrifugation speeds (1500 x g vs. 3000 x g) or time (15 min vs. 30 min), and storage conditions, such as at 4 degrees C or 25 degrees C for up to 24 h or at -80 degrees C for up to 3 months, and repeated freeze/thaw of up to ten cycles, had relatively minor effects on the proteomes based upon our analysis of about 100 peaks. We concluded that low-molecular-weight serum/plasma proteomes were diversely affected by sampling, handling and storage with most change from variations of sampling procedures. We therefore suggest the necessity of standardizing sampling procedure for proteome comparison and biomarker discovery.

Functional dissection of the XpsN (GspC) protein of the Xanthomonas campestris pv. campestris type II secretion machinery.

Type II secretion machinery is composed of 12 to 15 proteins for translocating extracellular proteins across the outer membrane. XpsL, XpsM, and XpsN are components of such machinery in the plant pathogen Xanthomonas campestris pv. campestris. All are bitopic cytoplasmic-membrane proteins, each with a large C-terminal periplasmic domain. They have been demonstrated to form a dissociable ternary complex. By analyzing the C-terminally truncated XpsN and PhoA fusions, we discovered that truncation of the C-terminal 103 residues produced a functional protein, albeit present below detectable levels. Furthermore, just the first 46 residues, encompassing the membrane-spanning sequence (residues 10 to 32), are sufficient to keep XpsL and XpsM at normal abundance. XpsN46(His6), synthesized in Escherichia coli, is able to associate in a membrane-mixing experiment with the XpsL-XpsM complex preassembled in X. campestris pv. campestris. The XpsN N-terminal 46 residues are apparently sufficient not only for maintaining XpsL and XpsM at normal levels but also for their stable association. The membrane-spanning sequence of XpsN was not replaceable by that of TetA. However, coimmunoprecipitation with XpsL and XpsM was observed for XpsN97::PhoA, but not XpsN46::PhoA. Only XpsN97::PhoA is dominant negative. Single alanine substitutions for three charged residues within the region between residues 47 and 97 made the protein nonfunctional. In addition, the R78A mutant XpsN protein was pulled down by XpsL-XpsM(His6) immobilized on an Ni-nitrilotriacetic acid column to a lesser extent than the wild-type XpsN. Therefore, in addition to the N-terminal 46 residues, the region between residues 47 and 97 of XpsN probably also plays an important role in interaction with XpsL-XpsM.