Towards the analysis of protein species: an overview about strategies and methods

The deciphering of the relationship between function and exact chemical composition of a defined protein species in the context of the proteome is one of the major challenges in proteomics and molecular cell physiology. In the Special Issue of Amino Acids about the analysis of protein species current approaches are reviewed and new methods described focusing on the investigation of protein species. On the basis of the articles in this Special Issue it can be summarized that first important and promising steps towards the comprehensive analysis of protein species have been done. It is already possible to obtain full (100%) sequence coverage of proteins by mass spectrometry, if the amount of proteins available for their analysis allows their proteolytic degradation by more than one protease and the subsequent mass spectrometric analysis of the resulting peptides. Employing affinity chromatography helps to analyse proteins with defined post-translational modifications thus opening a targeted view on e.g. the phosphoproteome. In the future the aim to identify the exact chemical composition including not one but every posttranslational modification and complete sequence coverage on the protein species level should be achievable with further progress in sample preparation techniques, especially concerning separation techniques on the protein level, mass spectrometry and algorithms for mass spectrometric data processing. For determining the function of defined protein species a closer cooperation between cell biologists and proteomics experts is desirable.     

Human DHHC proteins: a spotlight on the hidden player of palmitoylation

Palmitoylation is one of the most common posttranslational lipid modifications of proteins and we now know quite a lot about it. However, the state of knowledge about the enzymes that catalyze this process is clearly insufficient. This review is focused on 23 human DHHC genes and their products - protein palmitoyltransferases. Here we describe mainly the structure and function of these proteins, but also, to a lesser degree, what the substrates of the enzymes are and whether they are related to various diseases. The main aim of this review was to catalogue existing information concerning the human DHHC family of genes/proteins, making them and their functions easier to understand.     

Precise and parallel characterization of coding polymorphisms, alternative splicing, and modifications in human proteins by mass spectrometry

The human proteome is a highly complex extension of the genome wherein a single gene often produces distinct protein forms due to alternative splicing, RNA editing, polymorphisms, and posttranslational modifications. Such biological variation compounded by the high sequence identity within gene families currently overwhelms the complete and routine characterization of mammalian proteins by MS. A new data base of human proteins (and their possible variants) was created and searched using tandem mass spectrometric data from intact proteins. This first application of top down MS/MS to wild-type human proteins demonstrates both gene-specific identification and the unambiguous characterization of multifaceted mass shifts (Deltam values). Such Deltam values found from the precise identification of 45 protein forms from HeLa cells reveal 34 coding single nucleotide polymorphisms, two protein forms from alternative splicing, and 12 diverse modifications (not including simple N-terminal processing), including a previously unknown phosphorylation at 10% occupancy. Automated protein identification was achieved with a median expectation value of 10(-13) and often occurred simultaneously with dissection of diverse sources of protein variability as they occur in combination. Top down MS therefore has a bright future for enabling precise annotation of gene products expressed from the human genome by non-mass spectrometrists.     

Optimization of apolipoprotein-B-100 sequence coverage by liquid chromatography-tandem mass spectrometry for the future study of its posttranslational modifications

Proteomic applications have been increasingly used to study posttranslational modifications of proteins (PTMs). For the purpose of identifying and localizing specific but unknown PTMs on huge proteins, improving their sequence coverage is fundamental. Using liquid chromatography coupled to mass spectrometry (LC–MS/MS), peptide mapping of the native apolipoprotein-B-100 was performed to further document the effects of oxidation. Apolipoprotein-B-100 is the main protein of low-density lipoprotein particles and its oxidation could play a role in atherogenesis. Because it is one of the largest human proteins, the sequence recovery rate of apolipoprotein-B-100 only reached 1% when conventional analysis parameters were used. The different steps of the peptide mapping process—from protein treatment to data analysis—were therefore reappraised and optimized. These optimizations allowed a protein sequence recovery rate of 79%, a rate which has never been achieved previously for such a large human protein. The key points for improving peptide mapping were optimization of the data analysis software; peptide separation by LC; sample preparation; and MS acquisition. The new protocol has allowed us to increase by a factor of 4 the detection of modified peptides in apolipoprotein-B-100. This approach could easily be transferred to any study of PTMs using LC–MS/MS.     

Mass spectrometric analysis of integral membrane proteins at the subpicomolar level: application to rhodopsin

Integral membrane proteins are among the most interesting molecules for biomedical research, as some of the most important cellular functions are inherently tied to biological membranes. One such example is the vast expanse of receptors on cell surfaces. However, due to difficulties in the biochemical purification and structure/function analysis of membrane proteins, caused by their hydrophobic or amphophilic nature, membrane proteins are still much less studied than soluble proteins. Our laboratory has successfully developed and applied a methodology for the mass spectrometric analysis of integral membrane proteins. Here, we present an improvement in the sensitivity of detection made possible by the advancement of mass spectrometric instrumentation and refinement of the chromatographic analysis. Subpicomolar samples of bovine rhodopsin purified from native membranes were successfully analyzed, obtaining complete sequence coverage and the detection and localization of posttranslational modifications. Therefore, it is demonstrated that the detection limits and sequence coverage for soluble and membrane proteins can be comparable. The methodology presented here allows mass spectrometric analysis of subpicomolar levels of photopigments or other integral membrane proteins either from their native membranes or as products of expression systems.     

Mass spectrometrical analysis of the processed metastasis-inducing <Emphasis Type="Italic">anterior gradient protein 2 homolog</Emphasis> reveals 100% sequence coverage

Anterior gradient protein 2 homolog is a metastasis-inducing protein in a rat model of rat breast cancer and prognostic for outcome in hormonally treated breast cancer patients. Carrying out protein profiling in several mammalian cells and tissues, we detected this protein (synonym: secreted cement gland protein XAG-2 homolog) that was originally described in toad skin, in human bronchial epithelia. Tissues obtained from biopsies were homogenised and extracted proteins were run on two-dimensional gel electrophoresis. Following in-gel digestion with proteases trypsin, AspN, LysC and chymotrypsin, mass spectrometrical analysis was carried out by MALDI-TOF/TOF. The use of MS following multi-enzyme digestion of the protein resulted into 100% sequence coverage. MS/MS analysis enabled sequencing of 87% of the protein structure. This percentage does not include the signal peptide that was not observed in our protein due to processing. No posttranslational modifications were detectable and no sequence conflicts were observed. Complete analysis, unambiguous identification and characterisation of this biologically important protein could be shown, which is relevant for the definition of a marker protein that has been described so far by immunochemical methods only. Complete analysis is of importance as it forms the basis for all future work on this protein and, moreover, may serve as an analytical tool for further studies.     

Sequencing of rat liver cytosolic proteins by matrix-assisted laser desorption ionization-quadrupole time-of-flight mass spectrometry following electrophoretic separation and extraction

A new technique is described that enables the direct determination of the complete or partial amino acid sequence of cytosolic proteins separated by gel electrophoresis and allows for the further observation of disease- or drug-induced posttranslational modifications. The procedure uses a two-phase extraction strategy (ethyl acetate/ammonium bicarbonate) for the efficient separation of proteins/peptides from an electrophoretic matrix and subsequent sequence analysis by matrix-assisted laser desorption ionization-quadrupole time-of-flight mass spectrometry. The method was tested using hepatocyte cytosolic proteins and compared to a complementary approach using direct solvent extraction from in-gel digests. Although the latter procedure identified the proteins, it did not enable complete amino acid sequence determination. In contrast, high sequence coverage was obtained using the peptide extraction procedure, without any apparent dependence on protein size. The technique minimized the chemically inconsistent modifications generated from in-gel digestion, thus aiding mass spectrometric interpretation and valid protein sequence identification.     

Investigation of human protein variants and their frequency in the general population

Genetic variations and posttranslational modifications give rise to structural diversity in fully expressed human proteins. Structural modifications can also be induced during the life cycle of a protein and can lead to impaired functioning and pathological conditions. Although a large number of protein modifications have been discovered thus far, their incidence among the general population has not been determined. Here we show that human proteins exhibit a wide range of modifications present at various frequencies in the general population. The screening of 1,000 individuals from four geographical regions in the United States for five plasma proteins revealed the existence of 27 protein modifications. Some variants, such as those resulting from oxidation and single amino acid terminal truncations, were observed in the majority of individuals, whereas point mutations and extensive sequence truncations were detected in only a few individuals. Gender correlations were observed for two protein modifications. The data obtained reveal the extent of structural diversity in the general populace and represent the first such catalogue of structural protein modifications. Systematic studies of this kind will help redefine the normal human proteome and reveal the effects of these modifications in pathological processes.     

Arraying proteins by cell-free synthesis

Recent advances in life science have led to great motivation for the development of protein arrays to study functions of genome-encoded proteins. While traditional cell-based methods have been commonly used for generating protein arrays, they are usually a time-consuming process with a number of technical challenges. Cell-free protein synthesis offers an attractive system for making protein arrays, not only does it rapidly converts the genetic information into functional proteins without the need for DNA cloning, but also presents a flexible environment amenable to production of folded proteins or proteins with defined modifications. Recent advancements have made it possible to rapidly generate protein arrays from PCR DNA templates through parallel on-chip protein synthesis. This article reviews current cell-free protein array technologies and their proteomic applications.     

Genome-wide evolutionary conservation of N-glycosylation sites

Although posttranslational protein modifications are generally thought to perform important cellular functions, recent studies showed that a large fraction of phosphorylation sites are not evolutionarily conserved. Whether the same is true for other protein modifications, such as N-glycosylation is an open question. N-glycosylation is a form of cotranslational and posttranslational modification that occurs by enzymatic addition of a polysaccharide, or glycan, to an asparagine (N) residue of a protein. Examining a large set of experimentally determined mouse N-glycosylation sites, we find that the evolutionary rate of glycosylated asparagines is significantly lower than that of nonglycosylated asparagines of the same proteins. We further confirm that the conservation of glycosylated asparagines is accompanied by the conservation of the canonical motif sequence for glycosylation, suggesting that the above substitution rate difference is related to glycosylation. Interestingly, when solvent accessibility is considered, the substitution rate disparity between glycosylated and nonglycosylated asparagines is highly significant at solvent accessible sites but not at solvent inaccessible sites. Thus, although the solvent inaccessible glycosylation sites were experimentally identified, they are unlikely to be genuine or physiologically important. For solvent accessible asparagines, our analysis reveals a widespread and strong functional constraint on glycosylation, unlike what has been observed for phosphorylation sites in most studies, including our own analysis. Because the majority of N-glycosylation occurs at solvent accessible sites, our results show an overall functional importance for N-glycosylation.     

Regulation of the water channel aquaporin-2 by posttranslational modification

The cellular functions of many eukaryotic membrane proteins, including the vasopressin-regulated water channel aquaporin-2 (AQP2), are regulated by posttranslational modifications. In this article, we discuss the experimental discoveries that have advanced our understanding of how posttranslational modifications affect AQP2 function, especially as they relate to the role of AQP2 in the kidney. We review the most recent data demonstrating that glycosylation and, in particular, phosphorylation and ubiquitination are mechanisms that regulate AQP2 activity, subcellular sorting and distribution, degradation, and protein interactions. From a clinical perspective, posttranslational modification resulting in protein misrouting or degradation may explain certain forms of nephrogenic diabetes insipidus. In addition to providing major insight into the function and dynamics of renal AQP2 regulation, the analysis of AQP2 posttranslational modification may provide general clues as to the role of posttranslational modification for regulation of other membrane proteins.     

Bcl-2 family members: integrators of survival and death signals in physiology and pathology [corrected

The members of the Bcl-2 family of proteins are crucial regulators of apoptosis. In order to determine cell fate, these proteins must be targeted to distinct intracellular membranes, including the mitochondrial outer membrane (MOM), the membrane of the endoplasmic reticulum (ER) and its associated nuclear envelope. The targeting sequences and mechanisms that mediate the specificity of these proteins for a particular cellular membrane remain poorly defined. Several Bcl-2 family members have been reported to be tail-anchored via their predicted hydrophobic COOH-terminal transmembrane domains (TMDs). Tail-anchoring imposes a posttranslational mechanism of membrane insertion on the already folded protein, suggesting that the transient binding of cytosolic chaperone proteins to the hydrophobic TMD may be an important regulatory event in the targeting process. The TMD of certain family members is initially concealed and only becomes available for targeting and membrane insertion in response to apoptotic stimuli. These proteins either undergo a conformational change, posttranslational modification or a combination of these events enabling them to translocate to sites at which they are functional. Some Bcl-2 family members lack a TMD, but nevertheless localize to the MOM or the ER membrane during apoptosis where they execute their functions. In this review, we will focus on the intracellular targeting of Bcl-2 family members and the mechanisms by which they translocate to their sites of action. Furthermore, we will discuss the posttranslational modifications which regulate these events.     

Methods for analyzing peptides and proteins on a chromatographic timescale by electron-transfer dissociation mass spectrometry

Advancement in proteomics research relies on the development of new, innovative tools for identifying and characterizing proteins. Here, we describe a protocol for analyzing peptides and proteins on a chromatographic timescale by coupling nanoflow reverse-phase (RP) liquid chromatography (LC) to electron-transfer dissociation (ETD) mass spectrometry. For this protocol, proteins can be proteolytically digested before ETD analysis, although digestion is not necessary for all applications. Proteins 相似文献   

Analysis of ultra acidic proteins by the use of anodic acidic gels

Ultra acidic proteins, generated by posttranslational modifications, are becoming increasingly important due to recent evidence showing their function as regulatory elements or as intermediates in degradation pathways in bacteria. Such proteins are important in neurodegenerative diseases and embryonic development, and they include the Alzheimer-related tau (τ) protein (resulting from posttranslational modifications) and the phosphor-storage embryonic proteins. The ultra acidic proteins are difficult to study because standard two-dimensional gel electrophoresis is inadequate for their analysis. Here we describe a novel electrophoresis system of anodic acidic gels that can replace isoelectric focusing as the first dimension of separation in two-dimensional electrophoresis. The system is based on a sodium acetate buffer (pH 4.6), is compatible with traditional stains (e.g., Coomassie blue) as well as novel fluorescent dyes (e.g., Pro-Q Diamond), and is quantitative for the analysis of ultra acidic proteins. The anodic acidic gels were used for the functional classification of the ultra acidic part of the Bacillus subtilis proteome, showing significant improvement over traditional two-dimensional electrophoresis.     

Avidity-based extracellular interaction screening (AVEXIS) for the scalable detection of low-affinity extracellular receptor-ligand interactions

Extracellular protein:protein interactions between secreted or membrane-tethered proteins are critical for both initiating intercellular communication and ensuring cohesion within multicellular organisms. Proteins predicted to form extracellular interactions are encoded by approximately a quarter of human genes, but despite their importance and abundance, the majority of these proteins have no documented binding partner. Primarily, this is due to their biochemical intractability: membrane-embedded proteins are difficult to solubilise in their native conformation and contain structurally-important posttranslational modifications. Also, the interaction affinities between receptor proteins are often characterised by extremely low interaction strengths (half-lives < 1 second) precluding their detection with many commonly-used high throughput methods. Here, we describe an assay, AVEXIS (AVidity-based EXtracellular Interaction Screen) that overcomes these technical challenges enabling the detection of very weak protein interactions (t(1/2) ≤ 0.1 sec) with a low false positive rate. The assay is usually implemented in a high throughput format to enable the systematic screening of many thousands of interactions in a convenient microtitre plate format (Fig. 1). It relies on the production of soluble recombinant protein libraries that contain the ectodomain fragments of cell surface receptors or secreted proteins within which to screen for interactions; therefore, this approach is suitable for type I, type II, GPI-linked cell surface receptors and secreted proteins but not for multipass membrane proteins such as ion channels or transporters. The recombinant protein libraries are produced using a convenient and high-level mammalian expression system, to ensure that important posttranslational modifications such as glycosylation and disulphide bonds are added. Expressed recombinant proteins are secreted into the medium and produced in two forms: a biotinylated bait which can be captured on a streptavidin-coated solid phase suitable for screening, and a pentamerised enzyme-tagged (β-lactamase) prey. The bait and prey proteins are presented to each other in a binary fashion to detect direct interactions between them, similar to a conventional ELISA (Fig. 1). The pentamerisation of the proteins in the prey is achieved through a peptide sequence from the cartilage oligomeric matrix protein (COMP) and increases the local concentration of the ectodomains thereby providing significant avidity gains to enable even very transient interactions to be detected. By normalising the activities of both the bait and prey to predetermined levels prior to screening, we have shown that interactions having monomeric half-lives of 0.1 sec can be detected with low false positive rates.