Unexpected tryptic cleavage has been characterized at modified K48 residues in polyubiquitins. In particular, the tryptic products of all seven of the lysine-linked dimers of ubiquitin and of three trimers—linear Ub–48Ub–48Ub, linear Ub–63Ub–63Ub, and the branched trimer [Ub]2–6,48Ub—have been analyzed. In addition to the peptide products expected under commonly used tryptic conditions, we observe that peptides are formed with an unexpected ε-glycinylglycinyl-Lys carboxyl terminus when the site of linkage is Lys48. Trypsin from three different commercial sources exhibited this aberration. Initial cleavage at R74 is proposed in a distal ubiquitin to produce a glycinylglycinyl-lysine residue which is bound by trypsin.
The profound effects of ubiquitination on the movement and processing of cellular proteins depend exquisitely on the structures of mono and polyubiquitin modifications. Unconjugated polyubiquitins also have a variety of intracellular functions. Structures and functions are not well correlated yet, because the structures of polyubiquitins and polyubiquitin modifications of proteins are difficult to decipher. We are moving towards a robust strategy to provide that structural information. In this report electron transfer dissociation mass spectra of six synthetic ubiquitin trimers (multiply branched proteins with molecular masses exceeding 25,600 Da) are examined using an Orbitrap Fusion Lumos instrument to determine how top-down mass spectrometry can characterize the chain topology and linkage sites in a single, facile workflow. The efficacy of this method relies on the formation, detection, and interpretation of extensive fragmentation.
The characterization of polyubiquitin chains has been an analytical challenge for several decades. It has been shown that anchored and unanchored polyubiquitin chains with different isopeptide linkages and lengths exhibit a wide range of profoundly different cellular functions. However, structure function studies have been hindered by the difficulty of characterizing these complex chain structures. This report presents a broadly applicable workflow to characterize ubiquitin tetramers without the need for genetic mutations or reiterative immunoprecipitations. We use a top-down proteomic strategy that exploits ETciD activation on an orbitrap Fusion Lumos, and manual interpretation aided by graphical interpretation of mass shifts to facilitate characterization of chain topography and lysine linkage sites. Our workflow differentiates all topological features of the numerous isomers of tetraubiquitin, which have molecular masses in excess of 34,000 Da, and identifies linkage sites in these branched proteins.
The primary benefits of in utero hematopoietic cellular transplantation (IUHCT) arise from transplanting curative cells prior to the immunologic maturation of the fetus. However, this approach has been routinely successful only in the treatment of congenital immunodeficiency diseases that include an inherent NK cell deficiency despite the existence of normal maternal immunity in either setting. These observations raise the possibility that fetal NK cells function as an early barrier to allogeneic IUHCT. Herein, we summarize the findings of previous studies of prenatal NK cell allospecific tolerance in mice and in humans. Cumulatively, this new information reveals the complexity of the fetal immune response in the setting of rejection or tolerance and illustrates the role for fetal NK cells in the final endorsement of allospecific prenatal tolerance.
The small protein ubiquitin and its multiple polymers are encountered free in cells and as posttranslational modifications on all proteins. Different polyubiquitin three dimensional structures are shown to correlate uniquely with different cellular functions as part of the diverse ubiquitin signaling. At the same time, this multiplicity of structures provides serious challenges to the analytical biochemist. Globally applicable strategies are presented here for the analyses of polyubiquitins and of ubiquitinated proteins, which take advantage of the speed, specificity and sensitivity of top-down tandem mass spectrometry. Particular attention is given to the supervised interpretation of fragmentation as revealed in the MS/MS spectra of these branched proteins. The strategy is compatible with any MS activation technology, is applicable to all polyubiquitin linkage and chain types, can be extended to ubiquitin-like proteins, and will be compatible with and enhanced by continuing advances in LC-MS/MS instrumentation and interpretation software.
Multiple studies demonstrate that ubiquitination of proteins codes for regulation of cell differentiation, apoptosis, endocytosis, and many other cellular functions. There is great interest in, and considerable effort being given to defining the relationships between the structures of polyubiquitin modifications and the fates of the modified proteins. Does each ubiquitin modification achieve a specific effect, much like phosphorylation, or is ubiquitin like glycosylation, where there is heterogeneity and redundancy in the signal? The sensitive analytical tools needed to address such questions readily are not yet mature. To lay the foundation for mass spectrometry-based studies of the ubiquitin code we have assembled seven isomeric diubiquitins with all-native sequences and isopeptide linkages. Using these compounds as standards enables the development and testing of a new mass spectrometry-based strategy tailored specifically to characterize the number and sites of isopeptide linkages in polyubiquitin chains. Here we report the use of Asp-selective acid cleavage, separation by reverse phase HPLC, and characterization by tandem mass spectrometry to distinguish and characterize all seven isomeric lysine-linked ubiquitin dimers.
Little is known about how the prenatal interaction between NK cells and alloantigens shapes the developing NK cell repertoire towards tolerance or immunity. Specifically, the effect on NK cell education arising from developmental co-recognition of alloantigens by activating and inhibitory receptors with shared specificity is uncharacterized. Using a murine prenatal transplantation model, we examined the manner in which this seemingly conflicting input affects NK cell licensing and repertoire formation in mixed hematopoietic chimeras. We found that prenatal NK cell tolerance arose from the elimination of phenotypically “hostile” NK cells that express an allospecific activating receptor without co-expressing any allospecific inhibitory receptors. Importantly, the checkpoint for the system appeared to occur centrally within the bone marrow during the final stage of NK cell maturation and hinged on the instructive recognition of allogeneic ligand by the activating receptor rather than through the inhibitory receptor as classically proposed. Residual non-deleted hostile NK cells expressing only the activating receptor exhibited an immature, anergic phenotype but retained the capacity to upregulate inhibitory receptor expression in peripheral sites. However, the potential for this adaptive change to occur was lost in developmentally mature chimeras. Collectively, these findings illuminate the intrinsic process in which developmental allorecognition through the activating receptor regulates the emergence of durable NK cell tolerance and establishes a new paradigm to fundamentally guide future investigations of prenatal NK cell allospecific education.
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