Serum protein profiling in mice: identification of Factor XIIIa as a potential biomarker for muscular dystrophy

Protein profiling in blood serum by fractionation and MS analysis has been applied in mice to assess its applicability as a fast, economical alternative to current DNA and RNA analyses for diagnosis of neuromuscular disorders. Mass spectra of peptides and proteins were generated using serum from dystrophin-deficient mdx and control mice by WCX ClinProt bead fractionation, followed by MALDI-MS. Double cross-validatory linear discriminant and logistic regression data analysis methods were compared with a new Bayesian logistic regression method. These were evaluated on their ability to discriminate between healthy and dystrophic samples, and to identify the discriminatory peaks in the mass spectra. All three approaches classified the spectra with comparable misclassification rates (between 18.4 and 20.6%), with much overlap between the differential peaks identified between the methods. The differential peak pattern from the Bayesian method was sparser and easier to interpret than from the other two methods, without compromising classifying strength. One of the two main differentiating peaks at m/z 3908 was identified as an N-terminal peptide of coagulation Factor XIIIa, previously identified in human serum. This work underlines the translational aspect of serum protein profiling in mice and supports a further study with serum from patients with neuromuscular disorders.     

Label‐free quantitative analysis of the membrane proteome of Bace1 protease knock‐out zebrafish brains

The aspartyl protease BACE1 cleaves neuregulin 1 and is involved in myelination and is a candidate drug target for Alzheimer's disease, where it acts as the β‐secretase cleaving the amyloid precursor protein. However, little is known about other substrates in vivo. Here, we provide a proteomic workflow for BACE1 substrate identification from whole brains, combining filter‐aided sample preparation, strong‐anion exchange fractionation, and label‐free quantification. We used bace1‐deficient zebrafish and quantified differences in protein levels between wild‐type and bace1 ?/? zebrafish brains. Over 4500 proteins were identified with at least two unique peptides and quantified in both wild‐type and bace1 ?/? zebrafish brains. The majority of zebrafish membrane proteins did not show altered protein levels, indicating that Bace1 has a restricted substrate specificity. Twenty‐four membrane proteins accumulated in the bace1 ?/? brains and thus represent candidate Bace1 substrates. They include several known BACE1 substrates, such as the zebrafish homologs of amyloid precursor protein and the cell adhesion protein L1, which validate the proteomic workflow. Additionally, several candidate substrates with a function in neurite outgrowth and axon guidance, such as plexin A3 and glypican‐1 were identified, pointing to a function of Bace1 in neurodevelopment. Taken together, our study provides the first proteomic analysis of knock‐out zebrafish tissue and demonstrates that combining gene knock‐out models in zebrafish with quantitative proteomics is a powerful approach to address biomedical questions.     

Proteome analysis of the dystrophin-deficient MDX diaphragm reveals a drastic increase in the heat shock protein cvHSP

Duchenne muscular dystrophy is the most commonly inherited neuromuscular disorder in humans. Although the primary genetic deficiency of dystrophin in X-linked muscular dystrophy is established, it is not well-known how pathophysiological events trigger the actual fibre degeneration. We have therefore performed a DIGE analysis of normal diaphragm muscle versus the severely affected x-linked muscular dystrophy (MDX) diaphragm, which represents an established animal model of dystrophinopathy. Out of 2398 detectable 2-D protein spots, 35 proteins showed a drastic differential expression pattern, with 21 proteins being decreased, including Fbxo11-protein, adenylate kinase, beta-haemoglobin and dihydrolipoamide dehydrogenase, and 14 proteins being increased, including cvHSP, aldehyde reductase, desmin, vimentin, chaperonin, cardiac and muscle myosin heavy chain. This suggests that lack of sarcolemmal integrity triggers a generally perturbed protein expression pattern in dystrophin-deficient fibres. However, the most significant finding was the dramatic increase in the small heat shock protein cvHSP, which was confirmed by 2-D immunoblotting. Confocal fluorescence microscopy revealed elevated levels of cvHSP in MDX fibres. An immunoblotting survey of other key heat shock proteins showed a differential expression pattern in MDX diaphragm. Stress response appears to be an important cellular mechanism in dystrophic muscle and may be exploitable as a new approach to counteract muscle degeneration.     

Comparative phosphoproteomic analysis of mammalian glomeruli reveals conserved podocin C‐terminal phosphorylation as a determinant of slit diaphragm complex architecture

Glomerular biology is dependent on tightly controlled signal transduction networks that control phosphorylation of signaling proteins such as cytoskeletal regulators or slit diaphragm proteins of kidney podocytes. Cross‐species comparison of phosphorylation events is a powerful mean to functionally prioritize and identify physiologically meaningful phosphorylation sites. Here, we present the result of phosphoproteomic analyses of cow and rat glomeruli to allow cross‐species comparisons. We discovered several phosphorylation sites with potentially high biological relevance, e.g. tyrosine phosphorylation of the cytoskeletal regulator synaptopodin and the slit diaphragm protein neph‐1 (Kirrel). Moreover, cross‐species comparisons revealed conserved phosphorylation of the slit diaphragm protein nephrin on an acidic cluster at the intracellular terminus and conserved podocin phosphorylation on the very carboxyl terminus of the protein. We studied a highly conserved podocin phosphorylation site in greater detail and show that phosphorylation regulates affinity of the interaction with nephrin and CD2AP. Taken together, these results suggest that species comparisons of phosphoproteomic data may reveal regulatory principles in glomerular biology. All MS data have been deposited in the ProteomeXchange with identifier PXD001005 ( http://proteomecentral.proteomexchange.org/dataset/PXD001005 ).     

Proteomic analysis of livers from fat‐fed mice deficient in either PKCδ or PKCε identifies Htatip2 as a regulator of lipid metabolism

Insulin resistance contributes to the development of Type 2 diabetes, and is associated with lipid oversupply. Deletion of isoforms of the lipid‐activated protein kinase C (PKC) family, PKCδ or PKCε, improves insulin action in fat‐fed mice, but differentially affects hepatic lipid metabolism. To investigate the mechanisms involved, we employed an in vivo adaptation of SILAC to examine the effects of a fat diet together with deletion of PKCδ or PKCε on the expression of liver proteins. We identified a total of 3359 and 3488 proteins from the PKCδ and PKCε knockout study groups, respectively, and showed that several enzymes of lipid metabolism were affected by the fat diet. In fat‐fed mice, 23 proteins showed changes upon PKCδ deletion while 19 proteins were affected by PKCε deletion. Enzymes of retinol metabolism were affected by the absence of either PKC. Pathway analysis indicated that monosaccharide metabolism was affected only upon PKCδ deletion, while isoprenoid biosynthesis was affected in a PKCε‐specific manner. Certain proteins were regulated inversely, including HIV‐1 tat interactive protein 2 (Htatip2). Overexpression or knockdown of Htatip2 in hepatocytes affected fatty acid storage and oxidation, consistent with a novel role in mediating the differential effects of PKC isoforms on lipid metabolism. All MS data have been deposited in the ProteomeXchange with identifier PXD000971 ( http://proteomecentral.proteomexchange.org/dataset/PXD000971 ).     

Cognitive flexibility deficits in a mouse model for the absence of full‐length dystrophin

Duchenne muscular dystrophy (DMD) is a progressive muscle‐wasting disorder, caused by mutations in the DMD gene and the resulting lack of dystrophin. The DMD gene has seven promoters, giving rise to multiple full‐length and shorter isoforms. Besides the expression of dystrophin in muscles, the majority of dystrophin isoforms is expressed in brain and dystrophinopathy can lead to cognitive deficits, including intellectual impairments and deficits in executive function. In contrast to the muscle pathology, the impact of the lack of dystrophin on the brain is not very well studied. Here, we study the behavioral consequences of a lack of full‐length dystrophin isoforms in mdx mice, particularly with regard to domains of executive functions and anxiety. We observed a deficit in cognitive flexibility in mdx mice in the absence of motor dysfunction or general learning impairments using two independent behavioral tests. In addition, increased anxiety was observed, but its expression depended on the context. Overall, these results suggest that the absence of full‐length dystrophin in mice has specific behavioral effects that compare well to deficits observed in DMD patients.     

Proteomic analysis revealed the altered tear protein profile in a rabbit model of Sjögren's syndrome‐associated dry eye

Sjögren's syndrome (SS) is an autoimmune disease that results in pathological dryness of mouth and eye. The diagnosis of SS depends on both clinical evaluation and specific antibodies. The goal of this study was to use quantitative proteomics to investigate changes in tear proteins in a rabbit model of SS‐associated dry eye, induced autoimmune dacryoadenitis (IAD). Proteomic analysis was performed by iTRAQ and nano LC‐MS/MS on tears collected from the ocular surface, and specific proteins were verified by high resolution MRM. It was found that in the tears of IAD rabbits at 2 and 4 weeks after induction, S100 A6, S100 A9, and serum albumin were upregulated, whereas serotransferrin (TF), prolactin‐inducible protein (PIP), polymeric immunoglobulin receptor (pIgR), and Ig gamma chain C region were downregulated. High resolution MRM with mTRAQ labeling verified the changes in S100 A6, TF, PIP, and pIgR. Our results indicated significant changes of tear proteins in IAD rabbits, suggesting these proteins could potentially be used as biomarkers for the diagnosis and prognosis of dry eye. Several of these proteins were also found in the tears of non‐SS dry eye patients indicating a common basis of ocular surface pathology, however, pIgR appears to be unique to SS.     

Protein interactome analysis of 12 mitogen‐activated protein kinase kinase kinase in rice using a yeast two‐hybrid system

The mitogen‐activated protein kinase (MAPK) cascade is composed at least of MAP3K (for MAPK kinase kinase), MAP2K, and MAPK family modules. These components together play a central role in mediating extracellular signals to the cell and vice versa by interacting with their partner proteins. However, the MAP3K‐interacting proteins remain poorly investigated in plants. Here, we utilized a yeast two‐hybrid system and bimolecular fluorescence complementation in the model crop rice (Oryza sativa) to map MAP3K‐interacting proteins. We identified 12 novel nonredundant interacting protein pairs (IPPs) representing 11 nonredundant interactors using 12 rice MAP3Ks (available as full‐length cDNA in the rice KOME ( http://cdna01.dna.affrc.go.jp/cDNA/ ) at the time of experimental design and execution) as bait and a rice seedling cDNA library as prey. Of the 12 MAP3Ks, only six had interacting protein partners. The established MAP3K interactome consisted of two kinases, three proteases, two forkhead‐associated domain‐containing proteins, two expressed proteins, one E3 ligase, one regulatory protein, and one retrotransposon protein. Notably, no MAP3K showed physical interaction with either MAP2K or MAPK. Seven IPPs (58.3%) were confirmed in vivo by bimolecular fluorescence complementation. Subcellular localization of 14 interactors, together involved in nine IPPs (75%) further provide prerequisite for biological significance of the IPPs. Furthermore, GO of identified interactors predicted their involvement in diverse physiological responses, which were supported by a literature survey. These findings increase our knowledge of the MAP3K‐interacting proteins, help in proposing a model of MAPK modules, provide a valuable resource for developing a complete map of the rice MAPK interactome, and allow discussion for translating the interactome knowledge to rice crop improvement against environmental factors.     

By‐passing the nonsense mutation in the 4CV mouse model of muscular dystrophy by induced exon skipping

Background

Duchenne muscular dystrophy (DMD), a severe neuromuscular disorder, is caused by protein‐truncating mutations in the dystrophin gene. Absence of functional dystrophin renders muscle fibres more vulnerable to damage and necrosis. We report antisense oligomer (AO) induced exon skipping in the B6Ros.Cg‐Dmd^mdx–4Cv/J (4^CV) mouse, a muscular dystrophy model arising from a nonsense mutation in dystrophin exon 53. Both exons 52 and 53 must be excised to remove the mutation and maintain the reading frame.

Methods

A series of 2′‐O‐methyl modified oligomers on a phosphorothioate backbone (2OMeAOs) were designed and evaluated for the removal of each exon, and the most effective compounds were then combined to induce dual exon skipping in both myoblast cultures and in vivo. Exon skipping efficiency of 2OMeAOs and phosphorodiamidate morpholino oligomers (PMOs) was evaluated both in vitro and in vivo at the RNA and protein levels.

Results

Compared to the original mdx mouse studies, induction of exon skipping from the 4^CV dystrophin mRNA was far more challenging. PMO cocktails could restore synthesis of near‐full length dystrophin protein in cultured 4^CV myogenic cells and in vivo, after a single intramuscular injection.

Conclusions

By‐passing the protein‐truncating mutation in the 4^CV mouse model of muscular dystrophy could not be achieved with single oligomers targeting both exons and was only achieved after the application of AO cocktails to remove exons 52 and 53. As in previous studies, the stability and efficiency of PMOs proved superior to 2OMeAOs for consistent and sustained protein induction in vivo. Copyright © 2008 John Wiley & Sons, Ltd.     

Quantitative proteome analysis of detergent‐resistant membranes identifies the differential regulation of protein kinase C isoforms in apoptotic T cells

Several lines of evidence suggest that detergent‐resistant membranes (DRMs) (also known as lipid rafts and glycosphingolipid‐enriched microdomains) may have a role in signaling pathways of apoptosis. Here, we developed a method that combines DRMs isolation and methanol/chloroform extraction with stable isotope labeling with amino acids in cell culture‐based quantitative proteome analysis of DRMs from control and cisplatin‐induced apoptotic Jurkat T cells. This approach enabled us to enrich proteins with a pivotal role in cell signaling of which several were found with increased or decreased amounts in DRMs upon induction of apoptosis. Specifically, we show that three isoforms of protein kinase C (PKC) are regulated differently upon apoptosis. Although PKCα which belongs to the group of conventional PKCs is highly up‐regulated in DRMs, the levels of two novel PKCs, PKCη and PKCθ, are significantly reduced. These alterations/differences in PKC regulation are verified by immunoblotting and confocal microscopy. In addition, a specific enrichment of PKCα in apoptotic blebs and buds is shown. Furthermore, we observe an increased expression of ecto‐PKCα as a result of exposure to cisplatin using flow cytometry. Our results demonstrate that in‐depth proteomic analysis of DRMs provides a tool to study differential localization and regulation of signaling molecules important in health and disease.     

Expression of scFv‐Mel‐Gal4 triple fusion protein as a targeted DNA‐carrier in Escherichia Coli

Liver‐directed gene therapy has become a promising treatment for many liver diseases. In this study, we constructed a multi‐functional targeting molecule, which maintains targeting, endosome‐escaping, and DNA‐binding abilities for gene delivery. Two single oligonucleotide chains of Melittin (M) were synthesized. The full‐length cDNA encoding anti‐hepatic asialoglycoprotein receptor scFv C1 (C1) was purified from C1/pIT2. The GAL4 (G) gene was amplified from pSW50‐Gal4 by polymerase chain reaction. M, C1 and G were inserted into plasmid pGC4C26H to product the recombinant plasmid pGC‐C1MG. The fused gene C1MG was subsequently subcloned into plasmid pET32c to product the recombinant plasmid C1MG/pET32c and expressed in Escherichia coli BL21. The scFv‐Mel‐Gal4 triple fusion protein (C1MG) was purified with a Ni²⁺ chelating HiTrap HP column. The fusion protein C1MG of roughly 64 kD was expressed in inclusion bodies; 4.5 mg/ml C1MG was prepared with Ni²⁺ column purification. Western blot and immunohistochemistry showed the antigen‐binding ability of C1MG to the cell surface of the liver‐derived cell line and liver tissue slices. Hemolysis testing showed that C1MG maintained membrane‐disrupting activity. DNA‐binding capacity was substantiated by luciferase assay, suggesting that C1MG could deliver the DNA into cells efficiently on the basis of C1MG. Successful expression of C1MG was achieved in E. coli, and C1MG recombinant protein confers targeting, endosome‐escaping and DNA‐binding capacity, which makes it probable to further study its liver‐specific DNA delivery efficacy in vivo. Copyright © 2013 John Wiley & Sons, Ltd.     

Immune function of a Rab‐related protein by modulating the JAK‐STAT signaling pathway in the silkworm,Bombyx mori

The Rab‐family GTPases mainly regulate intracellular vesicle transport, and play important roles in the innate immune response in invertebrates. However, the function and signal transduction of Rab proteins in immune reactions remain unclear in silkworms. In this study, we analyzed a Rab‐related protein of silkworm Bombyx mori (BmRABRP) by raising antibodies against its bacterially expressed recombinant form. Tissue distribution analysis showed that BmRABRP mRNA and protein were high expressed in the Malpighian tubule and fat body, respectively. However, among the different stages, only the fourth instar larvae and pupae showed significant BmRABRP levels. After challenge with four pathogenic microorganisms (Escherichia coli, BmNPV, Beauveria bassiana, Micrococcus luteus), the expression of BmRABRP mRNA in the fat body was significantly upregulated. In contrast, the BmRABRP protein was significantly upregulated after infection with BmNPV, while it was downregulated by E. coli, B. bassiana, and M. luteus. A specific dsRNA was used to explore the immune function and relationship between BmRABRP and the JAK‐STAT signaling pathway. After BmRABRP gene interference, significant reduction in the number of nodules and increased mortality suggested that BmRABRP plays an important role in silkworm's response to bacterial challenge. In addition, four key genes (BmHOP, BmSTAT, BmSOCS2, and BmSOCS6) of the JAK‐STAT signaling pathway showed significantly altered expressions after BmRABRP silencing. BmHOP and BmSOCS6 expressions were significantly decreased, while BmSTAT and BmSOCS2 were significantly upregulated. Our results suggested that BmRABRP is involved in the innate immune response against pathogenic microorganisms through the JAK‐STAT signaling pathway in silkworm.     

About three‐fourths of mouse proteins unexpectedly appear at a low position of SDS‐PAGE,often as additional isoforms,questioning whether all protein isoforms have been eliminated in gene‐knockout cells or organisms

Most genes in evolutionarily complex genomes are expressed to multiple protein isoforms, but there is not yet any simple high‐throughput approach to identify these isoforms. Using an oversimplified top‐down LC–MS/MS strategy, we detected, around the 26‐kD position of SDS‐PAGE, proteins produced from 782 genes in a Cdk4?/? mouse embryonic fibroblast cell line. Interestingly, only 213 (27.24%, about one‐fourth) of these 782 genes have their proteins with a theoretical molecular mass (TMM) 10% smaller or larger than 26 kD, that is, between 23 and 29 kD, the range set as allowed variation in SDS‐PAGE. These 213 proteins are considered as the wild type (WT). The remaining three‐fourths includes proteins from 66 (9.44%) genes with a TMM smaller than 23 kD and proteins from 503 (64.32%, nearly two‐thirds) genes with a TMM larger than 29 kD; these proteins are categorized into a larger‐group or a smaller‐group, respectively, for their appearance at a higher or lower position of SDS‐PAGE. For instance, at this 26‐kD position we detected proteins from the Rps27a, Snrpf, Hist1h4a, and Rps25 genes whose proteins' TMM is 8.6, 9.7, 11.4, and 13.7 kD, respectively, and detected proteins from the Plelc1 and Prkdc genes, whose largest isoform is 533.9 and 471.1 kD, respectively. We extrapolate that many of those proteins migrating unexpectedly in SDS‐PAGE may be isoforms besides the WT protein. Moreover, we also detected a Cdk4 protein in this Cdk4?/? cell line, thus wondering whether some of other gene‐knockout cells or organisms show similar incompleteness of the knockout.