Characterization of the expression of dystrophins and dystrophin-associated proteins during embryonic neural stem/progenitor cell differentiation.

Duchenne muscular dystrophy (DMD) is a genetic disease caused by mutations in the dystrophin gene. Dystrophin is required for the organization of a complex consisting of dystroglycans, sarcoglycans, dystrobrevins and syntrophins, known as the dystrophin-associated proteins complex (DAPC). In addition to muscle degeneration, cognitive impairment has been reported in DMD patients. To characterize a suitable model for studying the embryonic cerebral functions of dystrophin, we analyzed the expression patterns of dystrophins/DAPC in undifferentiated and differentiated embryonic neural stem/progenitor cells (NSPC). We found that NSPC express mRNAs for dystrophins Dp427, Dp140, Dp71 and Dp40; ß-dystroglycan; α- and ß-dystrobrevin; α1-, ß1-, ß2- and γ2-syntrophin; and ß-, γ-, δ- and ε-sarcoglycan. Some of these were differentially regulated during neuronal or astrocytic differentiation. Interestingly, the protein expression levels of Dp140, ß-dystroglycan and α2-dystrobrevin were also differentially regulated. Additionally, we found that proliferating NSPC and differentiated neurons and astrocytes show immuno-positive staining for dystrophins and ß-dystroglycan. Our results show that dystrophins and DAPC components are expressed and regulated during the neuronal or astrocytic differentiation of NSPC, suggesting that these proteins may have different roles in the brain development.

The role of AMP-activated protein kinase in the expression of the dystrophin-associated protein complex in skeletal muscle.

Stimulation of AMPK induces the expression of dystrophin-associated protein complex (DAPC) components in skeletal muscle, whereas reductions in AMPK are associated with DAPC dysfunction. We sought to determine whether AMPK was necessary for the maintenance of DAPC expression in skeletal muscle. Fast, glycolytic extensor digitorum longus (EDL) and slow, oxidative soleus (Sol) muscles from wild-type mice and from littermates with skeletal muscle-specific knockout of the AMPK ß1 and ß2 subunits (AMPK ß1 ß2M-KO; MKO) were analyzed. DAPC mRNA and protein expression were similar between genotypes, with the exception of elevated neuronal nitric oxide synthase expression at the sarcolemma in MKO muscles. The content of transcriptional and post-transcriptional regulators of the DAPC was also not affected by the loss of AMPK. However, MyoD and myogenin expression was diminished in MKO muscles, consistent with previous reports of myopathy in these animals. Furthermore, we observed decrements in extrasynaptic utrophin expression selectively in MKO Sol muscles, likely due to the adaptive accumulation of peroxisome proliferator-activated receptor γ coactivator-1α at the sarcolemma of MKO EDL muscles. Collectively, the evidence indicates that AMPK is sufficient but not essential for the maintenance of DAPC expression in skeletal muscle, yet it is required for preserving extrasynaptic utrophin levels in slow oxidative muscles.-Dial, A. G., Rooprai, P., Lally, J. S., Bujak, A. L., Steinberg, G. R., Ljubicic, V. The role of AMP-activated protein kinase in the expression of the dystrophin-associated protein complex in skeletal muscle.

Dysbindin as a novel biomarker for pancreatic ductal adenocarcinoma identified by proteomic profiling.

Pancreatic adenocarcinoma (PDAC) is known to have a poor prognosis partly because of lack of effective biomarkers. In the test set, we investigated dysbindin (DTNBP1) as a potential biomarker for PDAC by comparing preoperative and postoperative serum mass spectrometry (MS) proteomic profilings. Of the included 50 PDAC patients, 42 (positivity of 84.0%) detected a lower MS peak in postoperative serums than preoperative ones which was then identified as dysbindin. In the verification set, receiver operating characteristics (ROC) were used to assess diagnostic efficiency. 550 participants were included in the verification set [250 with PDAC, 80 with benign biliary obstruction (BBO), 70 with chronic pancreatitis (CP) and 150 healthy donors (HD)]. Dysbindin was increased in PDAC patient sera than in all controls. ROC curves revealed the optimum diagnostic cutoff for dysbindin was 699.16 pg/ml [area under curve (AUC) 0.849 (95% CI 0.812-0.885), sensitivity 81.9% and specificity 84.7%]. Raised concentration of dysbindin in sera could differentiate PDAC from BBO, CP and HD. Moreover, dysbindin maintained its diagnostic accuracy for PDAC patients who were CA19-9 negative [AUC 0.875 (95% CI 0.804-0.945), sensitivity 83.0%, specificity 89.0%] and for patients with benign biliary obstruction [AUC 0.849 (95% CI 0.803-0.894), sensitivity 82.3%, specificity 84.0%].Our discovery of dysbindin may complement measurement of CA19-9 in the diagnosis of PDAC and help to discriminate PDAC from other pancreatic diseases or begin biliary obstruction.

Muscle structure influences utrophin expression in mdx mice.

Duchenne muscular dystrophy (DMD) is a severe muscle wasting disorder caused by mutations in the dystrophin gene. To examine the influence of muscle structure on the pathogenesis of DMD we generated mdx4cv:desmin double knockout (dko) mice. The dko male mice died of apparent cardiorespiratory failure at a median age of 76 days compared to 609 days for the desmin-/- mice. An ∼ 2.5 fold increase in utrophin expression in the dko skeletal muscles prevented necrosis in ∼ 91% of 1a, 2a and 2d/x fiber-types. In contrast, utrophin expression was reduced in the extrasynaptic sarcolemma of the dko fast 2b fibers leading to increased membrane fragility and dystrophic pathology. Despite lacking extrasynaptic utrophin, the dko fast 2b fibers were less dystrophic than the mdx4cv fast 2b fibers suggesting utrophin-independent mechanisms were also contributing to the reduced dystrophic pathology. We found no overt change in the regenerative capacity of muscle stem cells when comparing the wild-type, desmin-/-, mdx4cv and dko gastrocnemius muscles injured with notexin. Utrophin could form costameric striations with α-sarcomeric actin in the dko to maintain the integrity of the membrane, but the lack of restoration of the NODS (nNOS, α-dystrobrevin 1 and 2, α1-syntrophin) complex and desmin coincided with profound changes to the sarcomere alignment in the diaphragm, deposition of collagen between the myofibers, and impaired diaphragm function. We conclude that the dko mice may provide new insights into the structural mechanisms that influence endogenous utrophin expression that are pertinent for developing a therapy for DMD.

Molecular scaffolds underpinning macroglial polarization: an analysis of retinal Müller cells and brain astrocytes in mouse.

Key roles of macroglia are inextricably coupled to specialized membrane domains. The perivascular endfoot membrane has drawn particular attention, as this domain contains a unique complement of aquaporin-4 (AQP4) and other channel proteins that distinguishes it from perisynaptic membranes. Recent studies indicate that the polarization of macroglia is lost in a number of diseases, including temporal lobe epilepsy and Alzheimer's disease. A better understanding is required of the molecular underpinning of astroglial polarization, particularly when it comes to the significance of the dystrophin associated protein complex (DAPC). Here, we employ immunofluorescence and immunogold cytochemistry to analyze the molecular scaffolding in perivascular endfeet in macroglia of retina and three regions of brain (cortex, dentate gyrus, and cerebellum), using AQP4 as a marker. Compared with brain astrocytes, Müller cells (a class of retinal macroglia) exhibit lower densities of the scaffold proteins dystrophin and α-syntrophin (a DAPC protein), but higher levels of AQP4. In agreement, depletion of dystrophin or α-syntrophin--while causing a dramatic loss of AQP4 from endfoot membranes of brain astrocytes--had only modest or insignificant effect, respectively, on the AQP4 pool in endfoot membranes of Müller cells. In addition, while polarization of brain macroglia was less affected by dystrophin depletion than by targeted deletion of α-syntrophin, the reverse was true for retinal macroglia. These data indicate that the molecular scaffolding in perivascular endfeet is more complex than previously assumed and that macroglia are heterogeneous with respect to the mechanisms that dictate their polarization.

Modulation of the dystrophin-associated protein complex in response to resistance training in young and older men.

The dystrophin-associated protein complex (DAPC) is a scaffold of proteins linking the intracellular cytoskeleton with the extracellular matrix that is integral to structural stability and integrity, signaling and mechanotransduction, and force transmission. We hypothesized that the expression of DAPC component proteins would be altered by resistance loading during progressive resistance training (PRT)-mediated myofiber hypertrophy, and we investigated whether aging influenced these changes. Seventeen young (27 yr) and 13 older (65 yr) men completed 16 wk of PRT with muscle biopsies at baseline (T1), 24 h after bout 1 (T2), and 24 h after the final bout at week 16 (T3). Myofiber hypertrophy in the young (type I 31%, P < 0.005; type II 40%, P < 0.001) far exceeded hypertrophy in the old (type II only, 19.5%, P < 0.05). PRT altered protein expression for caveolin-3 (decreased 24% by T3, P < 0.01), alpha(1)-syntrophin (increased 16% by T3, P < 0.05), alpha-dystrobrevin (fell 23% from T2 to T3, P < 0.01), and dystrophin [rose acutely (30% by T2, P < 0.05) and returned to baseline by T3]. The phosphorylation state of membrane neuronal nitric oxide synthase (Ser(1417)) decreased 70% (P < 0.005) by T3, particularly in the old (81%), whereas p38 MAPK phosphorylation increased twofold by T3 in the old (P < 0.01). We conclude that component proteins of the DAPC are modulated by PRT, which may serve to improve both structural and signaling functions during load-mediated myofiber hypertrophy. The blunted hypertrophic adaptation seen in old vs. young men may have resulted from overstress, as suggested by marked p38 MAPK activation in old men only.

Expression of multiple AQP4 pools in the plasma membrane and their association with the dystrophin complex.

Altered aquaporin-4 (AQP4) expression has been reported in brain edema, tumors, muscular dystrophy, and neuromyelitis optica. However, the plasma membrane organization of AQP4 and its interaction with proteins such as the dystrophin-associated protein complex are not well understood. In this study, we used sucrose density gradient ultracentrifugation and 2D blue native/sodium dodecyl sulfate-polyacrylamide gel electrophoresis and showed the expression of several AQP4 multi-subunit complexes (pools) of different sizes, ranging from >> 1 MDa to approximately 500 kDa and containing different ratios of the 30/32 kDa AQP4 isoforms, indicative of orthogonal arrays of particles of various sizes. A high molecular weight pool co-purified with dystrophin and beta-dystroglycan and was drastically reduced in the skeletal muscle of mdx3cv mice, which have no dystrophin. The number and size of the AQP4 pools were the same in the kidney where dystrophin is not expressed, suggesting the presence of dystrophin-like proteins for their expression. We found that AQP2 is expressed only in one major pool of approximately 500 kDa, indicating that the presence of different pools is a peculiarity of AQP4 rather than a widespread feature in the AQP family. Finally, in skeletal muscle caveolin-3 did not co-purify with any AQP4 pool, indicating the absence of interaction of the two proteins and confirming that caveolae and orthogonal arrays of particles are two independent plasma membrane microdomains. These results contribute to a better understanding of AQP4 membrane organization and raise the possibility that abnormal expression of specific AQP4 pools may be found in pathological states.

Impaired synaptogenesis and long-term modulation of behavior following postnatal elevation of GABA levels in mice.

Antiepileptic drugs acting through the potentiation of GABAergic pathways have adverse effects on brain development. Increased risk of impaired intellectual development has been reported in children born to women treated for epilepsy during pregnancy. We have previously shown, in mice, that treatment with the antiepileptic drug vigabatrin (GVG) on postnatal days 4-14 delays reflex development in the newborn and impairs learning and memory in the adult. Here, we report the time course in which postnatal GVG treatment induced behavioral changes in an open field test and had a detrimental developmental effect on recognition memory in mice. Furthermore, GVG treatment significantly modulated the expression of synaptobrevin/vesicle-associated membrane protein (VAMP) II and synaptotagmin (Synt) I. A short-term decrease in the expression of these proteins was followed by a long-term elevation in their expression in both the hippocampus and the cerebral cortex. In contrast, no changes were detected in the levels of Synt II or in the vesicular GABA transporter. The over-expression of VAMP II and Synt I in the GVG-treated mice was associated with a significant decrease in the basal field excitatory postsynaptic potentials (fEPSP) and modulated the response to repeated stimulation. The changes observed in synaptogenesis may explain the behavioral impairment induced by postnatal GVG treatment and may suggest a possible mechanism for the detrimental effect of antiepileptic drugs acting through elevation of GABA levels.

Gene regulation by IL-1beta independent of IL-1R1 in the mouse brain.

Interleukin-1 (IL-1) is a key pro-inflammatory cytokine that has diverse actions in the brain as a regulator of host defense responses and a mediator of inflammation. Two major agonists, IL-1alpha and IL-1beta, bind to a single known functional type-1 IL-1 receptor (IL-1RI) that associates with the accessory protein (IL-1RAcP), resulting in signal transduction. However, recent evidence suggests that some actions of IL-1 in the brain may be independent of IL-1R1 and the classical IL-1 signaling pathways, pointing to an as-yet unidentified functional receptor for IL-1. In this study, we have used cDNA microarray-based gene expression profiling to identify the possible genes induced by IL-1beta independently of IL-1R1. IL-1beta induced potential changes (greater than 2-fold vs. vehicle-treated) in the expression of up to 1285 candidate genes in wild-type primary mixed glia, and 404 candidate genes in IL-1R1-/- cells of the same type. Real-time quantitative polymerase chain reaction (PCR) on selected genes revealed that pentraxin-3, was upregulated by IL-1beta in wild-type, but not in IL-1R1-/- mixed glia. Amongst the other genes for which expression was modified by IL-1beta in IL-1R1-/- cells, we selected alpha-syntrophin and demonstrated by real-time quantitative PCR that expression of this gene is significantly downregulated by IL-1beta in primary mixed glia prepared from wild-type, IL-1R1-/-, IL-1RAcP-/- or MyD88-/- mice. In contrast, IL-1alpha fails to downregulate alpha-syntrophin expression in wild-type or IL-1R1-/- mixed glia. These results show that IL-1beta exclusively downregulates alpha-syntrophin expression independently of IL-1R1, and suggest the expression of additional functional IL-1 receptors in the CNS.

Association of alpha-dystrobrevin with reorganizing tight junctions.

Alpha-dystrobrevin (alpha-DB) has been described primarily as a cytoplasmic component of the dystrophin-glycoprotein complex in skeletal muscle cells. Isoforms of alpha-DB show different localization in cells and tissues; at basolateral membranes in epithelial cells, dystrobrevins mediate contact with the extracellular matrix, peripheral and transmembrane proteins and the filamentous actin cytoskeleton. Beside their structural role, alpha-DBs are assumed to be important in cell signalling and cell differentiation. We have primarily assessed the role of alpha-DB in two epithelial cell lines (MDCK I, HT 29), which represent different developmental stages and exhibit distinct permeability characteristics. Using a polyclonal anti-alpha-DB antibody, we have investigated its expression, localization and association with tight junction (TJ)- associated proteins (ZO-1, occludin) before and after protein kinase C (PKC) activation with phorbol myristate acetate. Distinct subsets of alpha-DB isoforms were detected in the two cell lines by immunoblotting. In both cell lines there was submembranous localization of alpha-DB both apically and basolaterally, shown with confocal imaging. PKC activation caused a reorganization of TJ, which was parallel to increased localization of alpha-DB to TJ areas, most pronounced in MDCK I cells. Moreover, actin and ZO-1 co-immunoprecipitated with a-DB, as displayed with immunoblotting. Our findings suggest that a-dystrobrevin specifically is associated with the tight junctions during their reorganization.

The role of utrophin and Dp71 for assembly of different dystrophin-associated protein complexes (DPCs) in the choroid plexus and microvasculature of the brain.

In the brain, utrophin is present in the choroid plexus epithelium and vascular endothelial cells, whereas the short C-terminal isoform of dystrophin (Dp71) is localized in the glial end-feet surrounding blood vessels. Both proteins serve as anchors for the so-called dystrophin-associated protein complex (DPC), composed of isoforms of syntrophin, dystroglycan and dystrobrevin. Numerous transporter proteins and channels have a polarized distribution in vascular endothelial cells and in glial end-feet, suggesting an association with the DPC. We investigated the composition and localization of the DPC in dependence on the anchoring proteins in mice lacking either utrophin (utrophin0/0) or dystrophin isoforms (mdx3Cv). Three distinct complexes were identified: (i) associated with utrophin in the basolateral membrane of the choroid plexus epithelium, (ii) associated with utrophin in vascular endothelial cells, and (iii) associated with Dp71 in the glial end-feet. Upon ablation of utrophin or Dp71, the corresponding DPCs were disrupted and no compensation of the missing protein by its homologue was observed. Association of the water channel aquaporin 4 with the glial DPC likewise was disrupted in mdx3Cv mice. These results demonstrate the essential role of utrophin and Dp71 for assembly of the DPC and suggest that these proteins contribute to the proper functioning of the cerebrospinal fluid and blood-brain barriers.