A novel family of ubiquitin-specific proteases in chick skeletal muscle with distinct N- and C-terminal extensions

Ubiquitin ligase enzymes and de-ubiquitinating enzymes regulate innate immunity in the TLR, NLR, RLR, and cGAS-STING pathways

Ubiquitination (or ubiquitylation) and de-ubiquitination, which are both post-translational modifications (PTMs) of proteins, have become a research hotspot in recent years. Some ubiquitinated or de-ubiquitinated signaling proteins have been found to promote or suppress innate immunity through Toll-like receptor (TLR), RIG-like receptor (RIG-I-like receptor, RLR), NOD-like receptor (NLR), and the cyclic guanosine monophosphate (GMP)-adenosine monophosphate (AMP) synthase (cGAS)-STING pathway. This article aimed to provide a review on the role of ubiquitination and de-ubiquitination, especially ubiquitin ligase enzymes and de-ubiquitinating enzymes, in the above four pathways. We hope that our work can contribute to the research and development of treatment strategies for innate immunity-related diseases such as inflammatory bowel disease.

Using Activity-Based Proteomics for the Quantification of Deubiquitinases in Animal Tissue

Ubiquitination is a post-translational modification, that regulates essential cellular functions, and the enzymes that control the removal of this modification, deubiquitinases (DUBs), have been well described for the model organisms. However, the information about DUBs is still largely lacking for the non-model organisms, such as agriculturally relevant animals. To understand the expression of these enzymes in animal tissues, we have used chemical proteomics which can be used to identify biologically active DUBs present in tissues based on their reactivity with the activity-based probes (ABPs). Here we describe a sample preparation protocol for ABP-based purification of DUBs from animal tissue using two approaches to homogenize and lyse the animal tissue compatible with ABP labeling of DUBs, including an ultrasonication-based tissue processing method and bead-beating method. Both of these methods retain the enzymatic activity of DUBs. In addition, we describe a protocol for ABP labeling of DUBs in tissue lysates and the immunoprecipitation of the probe-reactive DUBs that can be used along with mass spectrometric identification of proteins and the detection of these DUBs by Western blotting.

Identification of active deubiquitinases in the chicken tissues

The existing protein annotation in chicken is mostly limited to computational predictions based on orthology to other proteins, which often leads to a significant underestimation of the function of these proteins. Genome-scale experimental annotation can provide insight into the actual enzymatic activities of chicken proteins. Amongst post-translational modifications, ubiquitination is of interest as anomalies in ubiquitination are implicated in such diseases as inflammatory disorders, infectious diseases, or malignancies. Ubiquitination is controlled by deubiquitinases (DUBs), which remove ubiquitin from protein substrates. However, the DUBs have not been systematically annotated and quantified in chicken tissues. Here we used a chemoproteomics approach, which is based on active-site probes specific to DUBs, and identified 26 active DUBs in the chicken spleen, cecum, and liver.

Identification of candidate substrates of ubiquitin-specific protease 13 using 2D-DIGE

The present study aimed to identify candidate substrates of ubiquitin-specific protease (USP)13 using two-dimensional fluorescence difference gel electrophoresis (2D-DIGE). USP13 is a well-characterized member of the USP family, which regulates diverse cellular functions by cleaving ubiquitin from ubiquitinated protein substrates. However, existing studies indicate that USP13 has no detectable hydrolytic activity in vitro. This finding implies that USP13 likely has different substrate specificity. In this study, a USP cleavage assay was performed using two different types of model substrates (glutathione S-transferase-Ub52 and ubiquitin-β-galactosidase) to detect the deubiquitinating enzyme (DUB) activity of USP13. In addition, a proteomic approach was taken by using 2D-DIGE to detect cellular proteins whose expressoin is significantly altered in 293T cell lines following the overexpression of USP13 or its C345S mutant (the catalytically inactive form). The data indicated that USP13 still has no detectable DUB activity in vitro nor does C345S. The results of 2D-DIGE demonstrated that the expression of several proteins increased or decreased significantly in 293T cells following the overexpression of USP13. Mass spec troscopy analysis of gel spots identified 7 proteins, including 4 proteins with an increased expression, namely vinculin, thimet oligopeptidase, cleavage and polyadenylation specific factor 3, and methylosome protein 50, and 3 proteins with a decreased expression, namely adenylosuccinate synthetase, annexin and phosphoglycerate mutase. In addition, in the samples of 293T cell lines after the overexpression of USP13 and USP13 C345S, vinculin exhibited an increased expression, suggesting that it may be a candidate substrate of USP13. However, sufficient follow-up validation studies are required in order to determine whether vinculin protein directly interacts with USP13.

USP2-45 Is a Circadian Clock Output Effector Regulating Calcium Absorption at the Post-Translational Level

The mammalian circadian clock influences most aspects of physiology and behavior through the transcriptional control of a wide variety of genes, mostly in a tissue-specific manner. About 20 clock-controlled genes (CCGs) oscillate in virtually all mammalian tissues and are generally considered as core clock components. One of them is Ubiquitin-Specific Protease 2 (Usp2), whose status remains controversial, as it may be a cogwheel regulating the stability or activity of core cogwheels or an output effector. We report here that Usp2 is a clock output effector related to bodily Ca²⁺ homeostasis, a feature that is conserved across evolution. Drosophila with a whole-body knockdown of the orthologue of Usp2, CG14619 (dUsp2-kd), predominantly die during pupation but are rescued by dietary Ca²⁺ supplementation. Usp2-KO mice show hyperabsorption of dietary Ca²⁺ in small intestine, likely due to strong overexpression of the membrane scaffold protein NHERF4, a regulator of the Ca²⁺ channel TRPV6 mediating dietary Ca²⁺ uptake. In this tissue, USP2-45 is found in membrane fractions and negatively regulates NHERF4 protein abundance in a rhythmic manner at the protein level. In clock mutant animals (Cry1/Cry2-dKO), rhythmic USP2-45 expression is lost, as well as the one of NHERF4, confirming the inverse relationship between USP2-45 and NHERF4 protein levels. Finally, USP2-45 interacts in vitro with NHERF4 and endogenous Clathrin Heavy Chain. Taken together these data prompt us to define USP2-45 as the first clock output effector acting at the post-translational level at cell membranes and possibly regulating membrane permeability of Ca²⁺.

Electroacupuncture suppresses myostatin gene expression: cell proliferative reaction in mouse skeletal muscle

Complementary and alternative medicine (CAM) may provide patients with an alternative to traditional medicine, but an assessment of its efficacy is required. One CAM method, electroacupuncture (EA) treatment, is a maneuver that utilizes stimulation of acupuncture needles with a low-frequency microcurrent. To study the effect of short-term EA, we evaluated the differential expression of genes induced by EA in mouse skeletal muscle for up to 24 h. We then used RT-PCR to confirm the expression patterns of six differentially expressed genes. Bioinformatics analysis of their transcription control regions showed that EA-inducible genes have numerous common binding motifs that are related to cell differentiation, cell proliferation, muscle repair, and hyperplasia. These results suggested that EA treatment may induce cell proliferation in skeletal muscle. To verify this possibility, we used EA to stimulate mouse skeletal muscle daily for up to 1 mo and examined the long-term effects. Immunohistochemical analysis showed that nuclei of muscle cells treated with EA for 1 mo, especially nuclei of satellite cells, reacted with anti-human PCNA. Also, expression of the gene encoding myostatin, which is a growth repressor in muscle satellite cells, was suppressed by daily EA treatment for 1 wk; EA treatment for 1 mo resulted in more marked suppression of the gene. These molecular findings constitute strong evidence that EA treatment suppresses myostatin expression, which leads to a satellite cell-related proliferative reaction and repair in skeletal muscle.

Strategies for assaying deubiquitinating enzymes

A general method for assaying deubiquitinating enzymes (DUBs) has been developed. This new method employs an indirect enzyme assay for determining the activity of DUBs using a linear fusion of polyHis-glutathione-S-transferase-ubiquitin-ecotin (His-GST-Ub-ecotin) as a substrate. Because ecotin, a trypsin inhibitor protein from Escherichia coli, is heat stable, the activity of DUBs can be assayed indirectly by determining the ability of ecotin to inhibit trypsin after incubation of any DUB with His-GST-Ub-ecotin followed by heating at 100 degrees. In the substrate construction, His-GST fusion to Ub was used for facilitation of the substrate purification as well as for assisting the heat precipitation of His-GST-Ub and uncleaved His-GST-Ub-ecotin, as Ub itself is also heat stable. This method can also be used for assaying the proteases that process Ub-like proteins (Ubls) using the substrates, in which Ub is replaced by Ubls.

Small ubiquitin-like modifying protein isopeptidase assay based on poliovirus RNA polymerase activity

The ubiquitin-proteasome pathway is the major nonlysosomal proteolytic system in eukaryotic cells responsible for regulating the level of many key regulatory molecules within the cells. Modification of cellular proteins by ubiquitin and ubiquitin-like proteins, such as small ubiquitin-like modifying protein (SUMO), plays an essential role in a number of biological schemes, and ubiquitin pathway enzymes have become important therapeutic targets. Ubiquitination is a dynamic reversible process; a multitude of ubiquitin ligases and deubiquitinases (DUBs) are responsible for the wide-ranging influence of this pathway as well as its selectivity. The DUB enzymes serve to maintain adequate pools of free ubiquitin and regulate the ubiquitination status of cellular proteins. Using SUMO fusions, a novel assay system, based on poliovirus RNA-dependent RNA polymerase activity, is described here. The method simplifies the isopeptidase assay and facilitates high-throughput analysis of these enzymes. The principle of the assay is the dependence of the viral polymerase on a free N terminus for activity; accordingly, the polymerase is inactive when fused at its N terminus to SUMO or any other ubiquitin-like protein. The assay is sensitive, reproducible, and adaptable to a high-throughput format for use in screens for inhibitors/activators of clinically relevant SUMO proteases and deubiquitinases.

Assessment of dietary amino acid scarcity on growth and blood plasma proteome status of broiler chickens

Dietary Lys needs for chicks were studied. A titration diet consisting of progressive amounts of dietary Lys from 0.95% up to 1.40% was fed to broiler chicks from 0 to 18 d of age. Optimal dietary Lys level was calculated using regression analysis. Body weight gain and feed conversion were maximized at Lys levels of 1.24% (1.10% digestible) and 1.27% (1.13% digestible) of diet, respectively. Blood samples were then collected from 2 groups: birds fed the lowest Lys level and birds fed dietary Lys nearest the determined requirement level (1.25% Lys). Plasma was analyzed for protein spectra via mass spectrometry and then classified by their functional characteristics. The number of proteins was similar between the 2 samples, but there was a tendency toward increased peptides for specific proteins in plasma from chicks fed adequate Lys levels. Furthermore, after these proteins were classified, more muscle-related proteins were found in plasma samples of birds fed Lys-adequate diets. It would appear that an individual dietary amino acid deficiency does not necessarily translate into decreasing protein synthesis proportionate to body weight, but rather significant changes may be occurring within the types of proteins undergoing anabolism. In conclusion, results herein illustrate the potential for using functional genomics in nutritionally related responses of poultry.

Biotin-ubiquitin tagging of mammalian proteins in Escherichia coli

Ubiquitin has been used in protein expression for enhancing yields and biological activities of recombinant proteins. Biotin binds tightly and specifically to avidin and has been widely utilized as a tag for protein purification and monitoring. Here, we report a versatile system that takes the advantages of both biotin and ubiquitin for protein expression, purification, and monitoring. The tripartite system contained coding sequences for a leader biotinylation peptide, ubiquitin, and biotin holoenzyme synthetase in two reading frames under the control of T7 promoter. The expression and purification of several large mammalian enzymes as biotin-ubiquitin fusions were accomplished including human ubiquitin activating enzyme, SUMO activating enzymes, and aspartyl-tRNA synthetase. Expressed proteins were purified by one-step affinity column chromatography on monomeric avidin columns and purified proteins exhibited active function. Additionally, the ubiquitin protein hydrolase UBP41, expressed and purified as biotin-UBP41, efficiently and specifically cleaved off the biotin-ubiquitin tag from biotin-ubiquitin fusions to produce unmodified proteins. The present expression system should be useful for the expression, purification, and functional characterization of mammalian proteins and the construction of protein microarrays.

Deubiquitinating enzymes--the importance of driving in reverse along the ubiquitin-proteasome pathway

Ubiquitination of proteins is now recognized to target proteins for degradation by the proteasome and for internalization into the lysosomal system, as well as to modify functions of some target proteins. Although much progress has been made in characterizing enzymes that link ubiquitin to proteins, our understanding of deubiquitinating enzymes is less developed. These enzymes are involved in processing the products of ubiquitin genes which all encode fusion proteins, in negatively regulating the functions of ubiquitination (editing), in regenerating free ubiquitin after proteins have been targeted to the proteasome or lysosome (recycling) and in salvaging ubiquitin from possible adducts formed with small molecule nucleophiles in the cell. A large number of genes encode deubiquitinating enzymes suggesting that many have highly specific and regulated functions. Indeed, recent findings provide strong support for the concept that ubiquitination is regulated by both specific pathways of ubiquitination and deubiquitination. Interestingly, many of these enzymes are localized to subcellular structures or to molecular complexes. These localizations play important roles in determining specificity of function and can have major influences on their catalytic activities. Future studies, particularly aimed at characterizing the interacting partners and potential substrates in these complexes as well as at determining the effects of loss of function of specific deubiquitinating enzymes will rapidly advance our understanding of the important roles of these enzymes as biological regulators.

Antagonistic regulation of myogenesis by two deubiquitinating enzymes, UBP45 and UBP69

Protein modification by ubiquitin is a dynamic and reversible process that is involved in the regulation of a variety of cellular processes. Here, we show that myogenic differentiation of embryonic muscle cells is antagonistically regulated by two deubiquitinating enzymes, UBP45 and UBP69, that are generated by alternative splicing. Both enzymes cleaved off ubiquitin from polyubiquitinated protein conjugates in vivo as well as from linear ubiquitin-protein fusions in vitro. In cultured myoblasts, the level of UBP69 mRNA markedly but transiently increased before membrane fusion, whereas that of UBP45 mRNA increased as the cells fused to form myotubes. Both myoblast fusion and accumulation of myosin heavy chain were dramatically stimulated by the stable expression of UBP69 but strongly attenuated by that of the catalytically inactive form of the protease, suggesting that the mutant enzyme acts dominant negatively on the function of the wild-type protease. In contrast, stable expression of UBP45 completely blocked both of the myogenic processes but that of inactive enzyme did not, indicating that the catalytic activity of the enzyme is essential for its inhibitory effects. These results indicate that differential expression of UBP45 and UBP69 is involved in the regulation of muscle cell differentiation.

A deubiquitinating enzyme, UCH/CeUBP130, has an essential role in the formation of a functional microtubule-organizing centre (MTOC) during early cleavage in C. elegans

BACKGROUND

Deubiquitinating enzymes generate monomeric ubiquitin in protein degradation pathways and are known to be important for the early development in many organisms.

RESULTS

RNA interference experiments targeted for a UBP homologue, UCH/CeUBP130, in C. elegans resulted in cell division defective embryos. Immunostaining localized UCH/CeUBP130 in the sperm and at the microtubule-organizing centre (MTOC) during early cleavage. Furthermore, the embryonic lethal phenotype was rescued by mating with wild-type males.

CONCLUSIONS

Since it is known that the MTOC in the fertilized embryo is contributed by sperm asters in C. elegans, we suggest that UCH/CeUBP130 and ubiquitin protein degradation pathways may be involved in microtubule-based sperm aster formation. Therefore UCH/CeUBP130 is necessary for the formation of a functional MTOC in the fertilized embryo of C. elegans.

Characterization of alternatively spliced products and tissue-specific isoforms of USP28 and USP25

BACKGROUND

The ubiquitin-dependent protein degradation pathway is essential for the proteolysis of intracellular proteins and peptides. Deubiquitinating enzymes constitute a complex protein family involved in a multitude of cellular processes. The ubiquitin-specific proteases (UBP) are a group of enzymes whose predicted function is to reverse the ubiquitinating reaction by removing ubiquitin from a large variety of substrates. We have lately reported the characterization of human USP25, a specific-ubiquitin protease gene at 21q11.2, with a specific pattern of expression in murine fetal brains and adult testis.

RESULTS

Database homology searches at the DNA and protein levels and cDNA library screenings led to the identification of a new UBP member in the human genome, named USP28, at 11q23. This novel gene showed preferential expression in heart and muscle. Moreover, cDNA, expressed sequence tag and RT-PCR analyses provided evidence for alternatively spliced products and tissue-specific isoforms. Concerning function, USP25 overexpression in Down syndrome fetal brains was shown by real-time PCR.

CONCLUSIONS

On the basis of the genomic and protein sequence as well as the functional data, USP28 and USP25 establish a new subfamily of deubiquitinating enzymes. Both genes have alternatively spliced exons that could generate protein isoforms with distinct tissue-specific activity. The overexpression of USP25 in Down syndrome fetal brains supports the gene-dosage effects suggested for other UBP members related to aneuploidy syndromes.

The ubiquitin-specific protease family from Arabidopsis. AtUBP1 and 2 are required for the resistance to the amino acid analog canavanine

Ubiquitin-specific proteases (UBPs) are a family of unique hydrolases that specifically remove polypeptides covalently linked via peptide or isopeptide bonds to the C-terminal glycine of ubiquitin. UBPs help regulate the ubiquitin/26S proteolytic pathway by generating free ubiquitin monomers from their initial translational products, recycling ubiquitins during the breakdown of ubiquitin-protein conjugates, and/or by removing ubiquitin from specific targets and thus presumably preventing target degradation. Here, we describe a family of 27 UBP genes from Arabidopsis that contain both the conserved cysteine (Cys) and histidine boxes essential for catalysis. They can be clustered into 14 subfamilies based on sequence similarity, genomic organization, and alignments with their closest relatives from other organisms, with seven subfamilies having two or more members. Recombinant AtUBP2 functions as a bona fide UBP: It can release polypeptides attached to ubiquitins via either alpha- or epsilon-amino linkages by an activity that requires the predicted active-site Cys within the Cys box. From the analysis of T-DNA insertion mutants, we demonstrate that the AtUBP1 and 2 subfamily helps confer resistance to the arginine analog canavanine. This phenotype suggests that the AtUBP1 and 2 enzymes are needed for abnormal protein turnover in Arabidopsis.

Tissue-specificity, functional characterization and subcellular localization of a rat ubiquitin-specific processing protease, UBP109, whose mRNA expression is developmentally regulated

A cDNA encoding an ubiquitin-specific processing protease, UBP109, in rat skeletal muscle was cloned and its product was characterized. Northern analysis revealed that UBP109 mRNA is highly expressed in testis and spleen, compared with other tissues. Furthermore, in situ hybridization showed that the level of UBP109 mRNA in liver, spinal cord and brain dramatically changed during embryonic development, indicating that the expression of UBP109 mRNA is developmentally regulated. UBP109 was expressed in Escherichia coli and purified to apparent homogeneity using a (125)I-labelled ubiquitin-peptide fusion as a substrate. The purified enzyme cleaved at the C-terminus of the ubiquitin moiety in natural and engineered fusions irrespective of their sizes. UBP109 also released free ubiquitin from poly-His-tagged penta-ubiquitin. Moreover, it released free ubiquitin from poly-ubiquitinated protein conjugates of rabbit reticulocytes. In addition, UBP109 localized to both the cytoplasm and the nucleus and, among three putative nuclear localization sequences, only the one located near the C-terminus is responsible for nuclear localization. These results suggest that UBP109 may play an important role in generation of free ubiquitin from its precursors and its recycling from poly-ubiquitinated protein conjugates, and hence in regulation of ubiquitin-mediated cellular processes, particularly related to embryonic development.

Sequencing, tissue distribution and chromosomal assignment of a novel ubiquitin-specific protease USP23

We have identified human and mouse cDNAs encoding a novel ubiquitin-specific protease designated USP23. Both cDNAs encode a 62-kDa protein containing the highly conserved His and Cys domains characteristic of the C19 cysteine protease family of ubiquitin-specific processing proteases (UCH-2). Human tissue Northern blots revealed USP23 to be ubiquitously expressed, whereas USP12, its closest human paralogue, displayed a more restricted expression pattern. The human USP23 gene mapped to chromosome 1q22.

Deubiquitinating enzymes: their diversity and emerging roles

A growing number of important regulatory proteins within cells are modified by conjugation of ubiquitin, a well-conserved 76-amino-acid polypeptide. The ubiquitinated proteins are targeted to proteasome for degradation or alternative metabolic fates, such as triggering of plasma membrane endocytosis and trafficking to vacuoles or lysosomes. Deubiquitination, reversal of this modification, is being recognized as an important regulatory step. Deubiquitinating enzymes are cysteine proteases that specifically cleave off ubiquitin from ubiquitin-conjugated protein substrates as well as from its precursor proteins. Genome sequencing projects have identified more than 90 deubiquitinating enzymes, making them the largest family of enzymes in the ubiquitin system. This review will concentrate on recent important findings as well as new insights into the diversity and emerging roles of deubiquitinating enzymes in the ubiquitin-dependent pathway.

Molecular cloning of chick UCH-6 which shares high similarity with human UCH-L3: its unusual substrate specificity and tissue distribution

A full-length cDNA encoding ubiquitin C-terminal hydrolase-6 (UCH-6) was isolated from the chick skeletal muscle cDNA library. The sequence of two peptides generated from purified UCH-6 matched perfectly with the predicted amino acid sequence. Nucleotide sequence analysis of the cDNA containing an open reading frame of 690 base pairs revealed that the protease consists of 230 residues with a calculated molecular mass of 26,315 Da. UCH-6 belonged to members of the UCH family containing highly conserved Cys, His, and Asp domains and showed 86% amino acid identity to human UCH-L3. Interestingly, most tissues examined contained significant amounts of UCH-6 mRNA, while human UCH-L3 is expressed only in the brain, lungs, and red cells. Moreover, UCH-6, unlike other UCH family enzymes including UCH-L3, could release free ubiquitin from ubiquitin-beta-galactosidase fusion proteins both in vivo and in vitro. The ubiquitous expression pattern and unusual substrate specificity of UCH-6 suggest that the enzyme may represent a distinct subfamily of UCH-L3.

Identification, functional characterization, and chromosomal localization of USP15, a novel human ubiquitin-specific protease related to the UNP oncoprotein, and a systematic nomenclature for human ubiquitin-specific proteases

We have identified a novel gene, USP15, encoding a human ubiquitin-specific protease (USP). The USP15 protein consists of 952 amino acids with a predicted molecular mass of 109.2 kDa and contains the highly conserved Cys and His boxes present in all members of the UBP family of deubiquitinating enzymes. USP15 shares 60.5% sequence identity and 76% sequence similarity with the human homolog (UNP/Unph/USP4) of the mouse Unp proto-oncogene. Recombinant USP15 demonstrated ubiquitin-specific protease activity against engineered linear fusions of ubiquitin to beta-galactosidase and glutathione S-transferase. USP15 can also cleave the ubiquitin-proline bond, a property previously unique to Unp/UNP. Chromosomal mapping by fluorescence in situ hybridization and radiation hybrid analyses localized the USP15 gene to chromosome band 12q14, a different location than that of UNP (3p21.3). Analysis of expressed sequence tag databases reveals evidence of alternate polyadenylation sites in the USP15 gene and also indicates that the gene may possess an exon/intron structure similar to that of the Unp gene, suggesting they have descended from a common ancestor. A systematic nomenclature for the human USPs is proposed.