Metal-coded affinity tag labeling: a demonstration of analytical robustness and suitability for biological applications.

Quantitative peptide and protein analysis is one of the most promising fields in modern life science. Besides stable isotope coded labeling, metal chelate complexes are an alternative tool for quantification. The development of metal-coded affinity tags (MeCAT) was aimed to provide a robust tool for the quantification of peptides and proteins by utilizing lanthanide-harboring metal tags. It was shown that MeCAT is suited for relative quantification of proteins via standard mass spectrometric methods. The approach of tagging biomolecules with MeCAT offers the unique advantage of absolute quantification via inductively coupled plasma mass spectrometry (ICPMS), a well-established technique for assessing concentrations down to low attomole ranges. This work investigates the compatibility of MeCAT labeling to analysis workflows such as nano liquid chromatography/electrospray ionization tandem mass spectrometry (nano-LC/ESI-MS(n)). Focus was given toward the separation behavior of labeled peptides and the dynamic range of detection and peptide charge distribution. Furthermore, the stability of MeCAT under harsh analytical conditions was investigated. With the application of the MeCAT technique to a standard analysis scheme in proteomics, such as the investigation of changes in an Escherichia coli proteome, we successfully addressed the suitability to utilize MeCAT on biological samples. Furthermore, we demonstrated that MeCAT complexes are stable under a variety of conditions and that by applying LC/ESI-MS it is possible to cover a dynamic range of 2 orders of magnitude down to the low femtomole range with an average standard deviation below 15%. Therefore, this technique is suitable to common proteomic workflows and enables relative as well as absolute differential peptide quantification.

Fragmentation behavior of metal-coded affinity tag (MeCAT)-labeled peptides.

Quantitative proteomics has become an important method in modern life sciences. Besides protein identification, the aspect of quantification is of rapidly increasing relevance. MeCAT (metal-coded affinity tagging) is able to provide a tool that enables relative as well as absolute quantification. For structural elucidation, knowledge on the fragmentation behavior of MeCAT-modified peptides is highly beneficial. Therefore, the fragmentation behavior of MeCAT-labeled peptides under collision induced dissociation (CID), electron capture dissociation (ECD) and infrared multiphoton dissociation (IRMPD) conditions was studied. Application of CID and ECD allowed a straight-forward sequence elucidation of MeCAT-labeled peptides. During IRMPD all MeCAT-labeled peptides form characteristic fragments resulting from the fragmentational cleavage of the tagging group, thus, providing a screening method for the identification of labeled compounds. Furthermore, occurring side reactions during the labeling process were investigated. By-products were structurally characterized and reaction conditions were optimized in order to prevent the formation of these.

Liquid chromatography-mass spectrometry-based quantitative proteomics.

During the last decades, molecular sciences revolutionized biomedical research and gave rise to the biotechnology industry. During the next decades, the application of the quantitative sciences--informatics, physics, chemistry, and engineering--to biomedical research brings about the next revolution that will improve human healthcare and certainly create new technologies, since there is no doubt that small changes can have great effects. It is not a question of "yes" or "no," but of "how much," to make best use of the medical options we will have. In this context, the development of accurate analytical methods must be considered a cornerstone, since the understanding of biological processes will be impossible without information about the minute changes induced in cells by interactions of cell constituents with all sorts of endogenous and exogenous influences and disturbances. The first quantitative techniques, which were developed, allowed monitoring relative changes only, but they clearly showed the significance of the information obtained. The recent advent of techniques claiming to quantify proteins and peptides not only relative to each other, but also in an absolute fashion, promised another quantum leap, since knowing the absolute amount will allow comparing even unrelated species and the definition of parameters will permit to model biological systems much more accurate than before. To bring these promises to life, several approaches are under development at this point in time and this review is focused on those developments.

Structural domains in the type III restriction endonuclease EcoP15I: characterization by limited proteolysis, mass spectrometry and insertional mutagenesis.

The Type III restriction endonuclease EcoP15I forms a hetero-oligomeric enzyme complex that consists of two modification (Mod) subunits and two restriction (Res) subunits. Structural data on Type III restriction enzymes in general are lacking because of their remarkable size of more than 400 kDa and the laborious and low-yield protein purification procedures. We took advantage of the EcoP15I-overexpressing vector pQEP15 and affinity chromatography to generate a quantity of EcoP15I high enough for comprehensive proteolytic digestion studies and analyses of the proteolytic fragments by mass spectrometry. We show here that in the presence of specific DNA the entire Mod subunit is protected from trypsin digestion, whereas in the absence of DNA stable protein domains of the Mod subunit were not detected. In contrast, the Res subunit is comprised of two trypsin-resistant domains of approximately 77-79 kDa and 27-29 kDa, respectively. The cofactor ATP and the presence of DNA, either specific or unspecific, are important stabilizers of the Res subunit. The large N-terminal domain of Res contains numerous functional motifs that are predicted to be involved in ATP-binding and hydrolysis and/or DNA translocation. The C-terminal small domain harbours the catalytic center. Based on our data, we conclude that both structural Res domains are connected by a flexible linker region that spans 23 amino acid residues. To confirm this conclusion, we have investigated several EcoP15I enzyme mutants obtained by insertion mutagenesis in and around the predicted linker region within the Res subunit. All mutants tolerated the genetic manipulation and did not display loss of function or alteration of the DNA cleavage position.

RNA self-processing towards changed topology and sequence oligomerization.

Reversible chemistry, allowing for chain-forming as well as chain-breaking steps, is important for biological self-organization. In this context, ribozymes, catalyzing both RNA cleavage and ligation, may have significantly contributed to extending the sequence space and length of RNA molecules in early life forms. Here we present an engineered RNA that self-processes by passing through a number of cleavage and ligation steps. Intermolecular reactions compete with intramolecular reactions, resulting in a variety of products. Our results demonstrate that RNA can undergo self-oligomerization, which may have been important for extending the RNA genome size in RNA world scenarios.

A metal-coded affinity tag approach to quantitative proteomics.

The quantitative analysis of protein mixtures is pivotal for the understanding of variations in the proteome of living systems. Therefore, approaches have been recently devised that generally allow the relative quantitative analysis of peptides and proteins. Here we present proof of concept of the new metal-coded affinity tag (MeCAT) technique, which allowed the quantitative determination of peptides and proteins. A macrocyclic metal chelate complex (1,4,7,10-tetraazacyclododecane-1,4,7,10-tetraacetic acid (DOTA)) loaded with different lanthanides (metal(III) ions) was the essential part of the tag. The combination of DOTA with an affinity anchor for purification and a reactive group for reaction with amino acids constituted a reagent that allowed quantification of peptides and proteins in an absolute fashion. For the quantitative determination, the tagged peptides and proteins were analyzed using flow injection inductively coupled plasma MS, a technique that allowed detection of metals with high precision and low detection limits. The metal chelate complexes were attached to the cysteine residues, and the course of the labeling reaction was followed using SDS-PAGE and MALDI-TOF MS, ESI MS, and inductively coupled plasma MS. To limit the width in isotopic signal spread and to increase the sensitivity for ESI analysis, we used the monoisotopic lanthanide macrocycle complexes. Peptides tagged with the reagent loaded with different metals coelute in liquid chromatography. In first applications with proteins, the calculated detection limit for bovine serum albumin for example was 110 amol, and we have used MeCAT to analyze proteins of the Sus scrofa eye lens as a model system. These data showed that MeCAT allowed quantification not only of peptides but also of proteins in an absolute fashion at low concentrations and in complex mixtures.