Paul L. McNeil

Defective membrane repair in dysferlin-deficient muscular dystrophy

Muscular dystrophy includes a diverse group of inherited muscle diseases characterized by wasting and weakness of skeletal muscle. Mutations in dysferlin are linked to two clinically distinct muscle diseases, limb-girdle muscular dystrophy type 2B and Miyoshi myopathy, but the mechanism that leads to muscle degeneration is unknown. Dysferlin is a homologue of the Caenorhabditis elegans fer-1 gene, which mediates vesicle fusion to the plasma membrane in spermatids. Here we show that dysferlin-null mice maintain a functional dystrophin–glycoprotein complex but nevertheless develop a progressive muscular dystrophy. In normal muscle, membrane patches enriched in dysferlin can be detected in response to sarcolemma injuries. In contrast, there are sub-sarcolemmal accumulations of vesicles in dysferlin-null muscle. Membrane repair assays with a two-photon laser-scanning microscope demonstrated that wild-type muscle fibres efficiently reseal their sarcolemma in the presence of Ca2+. Interestingly, dysferlin-deficient muscle fibres are defective in Ca2+-dependent sarcolemma resealing. Membrane repair is therefore an active process in skeletal muscle fibres, and dysferlin has an essential role in this process. Our findings show that disruption of the muscle membrane repair machinery is responsible for dysferlin-deficient muscle degeneration, and highlight the importance of this basic cellular mechanism of membrane resealing in human disease.

Contraction-Induced Cell Wounding and Release of Fibroblast Growth Factor in Heart

The heart hypertrophies in response to certain forms of increased mechanical load, but it is not understood how, at the molecular level, the mechanical stimulus of increased load is transduced into a cell growth response. One possibility is that mechanical stress provokes the release of myocyte-derived autocrine growth factors. Two such candidate growth factors, acidic and basic fibroblast growth factor (aFGF and bFGF, respectively), are released via mechanically induced disruptions of the cell plasma membrane. In the present study, we demonstrate that transient, survivable disruption (wounding) of the cardiac myocyte plasma membrane is a constitutive event in vivo. Frozen sections of normal rat heart were immunostained to reveal the distribution of the wound event marker, serum albumin. Quantitative image analysis of these sections indicated that an average of 25% of the myocytes contained cytosolic serum albumin; ie, this proportion had suffered a plasma membrane wound. Wounding frequency increased approximately threefold after beta-adrenergic stimulation of heart rate and force of contraction. Heparin-Sepharose chromatography, enzyme-linked immunosorbent assay, growth assay coupled with antibody neutralization, and two-dimensional SDS-PAGE followed by immunoblotting were used to demonstrate that both aFGF and bFGF were released from an ex vivo beating rat heart. Importantly, beta-adrenergic stimulation of heart rate and force of contraction increased FGF release. Cell wounding is a fundamental but previously unrecognized aspect of the biology of the cardiac myocyte. We propose that contraction-induced cardiac myocyte wounding releases aFGF and bFGF, which then may act as autocrine growth-promoting stimuli.

Requirement for Annexin A1 in Plasma Membrane Repair

Ca2+ entering a cell through a torn or disrupted plasma membrane rapidly triggers a combination of homotypic and exocytotic membrane fusion events. These events serve to erect a reparative membrane patch and then anneal it to the defect site. Annexin A1 is a cytosolic protein that, when activated by micromolar Ca2+, binds to membrane phospholipids, promoting membrane aggregation and fusion. We demonstrate here that an annexin A1 function-blocking antibody, a small peptide competitor, and a dominant-negative annexin A1 mutant protein incapable of Ca2+ binding all inhibit resealing. Moreover, we show that, coincident with a resealing event, annexin A1 becomes concentrated at disruption sites. We propose that Ca2+ entering through a disruption locally induces annexin A1 binding to membranes, initiating emergency fusion events whenever and wherever required.

Gastrointestinal Cell Plasma Membrane Wounding and Resealing In Vivo

Previous studies in vitro have shown that various mechanical methods used to wound plasma membranes allow normally impermeant, water-soluble markers, such as fluorescein dextran or horseradish peroxidase, to enter the cytosol. Subsequent membrane resealing traps these nontoxic fluorescent or electron microscopic markers within living, surviving wounded cells. The present report is the first, to our knowledge, to use this strategy to study cell membrane wounding and resealing in the intact animal. We show that gut cells wounded in vivo by mechanical forces are capable of resealing disruptions of their plasma membranes. More importantly, we show that wounding of cell membranes, followed by resealing, occurs not only in mechanically injured gut but also in normal, experimentally undisturbed gut. A variety of cell types were wounded and resealed membrane wounds in the mechanically injured stomach: surface mucous, endothelial, fibroblastic, parietal, and chief cells. Mucous cells successful at resealing membrane wounds apparently became active participants in the motile events of stomach repair. In undisturbed gut, cell membrane wounding and resealing was most frequently observed in the colon, but was also observed in the esophagus, stomach, duodenum, and ileum. Surface epithelial cells in undisturbed gut were retained for greater than 48 h after surviving membrane wounds. Two important roles are suggested for membrane resealing in gut: (a) preservation of motile cells nearest epithelial discontinuities requiring repair after injury, and (b) maintenance of epithelial integrity in normally functioning gut. Our finding of cell wounding in undisturbed gut may explain, in part, why rapid, continual cell turnover is characteristic of gut epithelia. We propose that membrane disruption, or wounding, is a normal and common occurrence in vivo, and that a biologically significant function of the plasma membrane is to reseal such wounds. The occurrence of in vivo cell membrane wounding and resealing suggests an unrecognized route for molecular traffic into and out of cytoplasm.

Dysferlin-mediated membrane repair protects the heart from stress-induced left ventricular injury

Dilated cardiomyopathy is a life-threatening syndrome that can arise from a myriad of causes, but predisposition toward this malady is inherited in many cases. A number of inherited forms of dilated cardiomyopathy arise from mutations in genes that encode proteins involved in linking the cytoskeleton to the extracellular matrix, and disruption of this link renders the cell membrane more susceptible to injury. Membrane repair is an important cellular mechanism that animal cells have developed to survive membrane disruption. We have previously shown that dysferlin deficiency leads to defective membrane resealing in skeletal muscle and muscle necrosis; however, the function of dysferlin in the heart remains to be determined. Here, we demonstrate that dysferlin is also involved in cardiomyocyte membrane repair and that dysferlin deficiency leads to cardiomyopathy. In particular, stress exercise disturbs left ventricular function in dysferlin-null mice and increases Evans blue dye uptake in dysferlin-deficient cardiomyocytes. Furthermore, a combined deficiency of dystrophin and dysferlin leads to early onset cardiomyopathy. Our results suggest that dysferlin-mediated membrane repair is important for maintaining membrane integrity of cardiomyocytes, particularly under conditions of mechanical stress. Thus, our study establishes what we believe is a novel mechanism underlying the cardiomyopathy that results from a defective membrane repair in the absence of dysferlin.

Basal lamina strengthens cell membrane integrity via the laminin G domain-binding motif of α-dystroglycan

Skeletal muscle basal lamina is linked to the sarcolemma through transmembrane receptors, including integrins and dystroglycan. The function of dystroglycan relies critically on posttranslational glycosylation, a common target shared by a genetically heterogeneous group of muscular dystrophies characterized by α-dystroglycan hypoglycosylation. Here we show that both dystroglycan and integrin α7 contribute to force-production of muscles, but that only disruption of dystroglycan causes detachment of the basal lamina from the sarcolemma and renders muscle prone to contraction-induced injury. These phenotypes of dystroglycan-null muscles are recapitulated by Largemyd muscles, which have an intact dystrophin–glycoprotein complex and lack only the laminin globular domain-binding motif on α-dystroglycan. Compromised sarcolemmal integrity is directly shown in Largemyd muscles and similarly in normal muscles when arenaviruses compete with matrix proteins for binding α-dystroglycan. These data provide direct mechanistic insight into how the dystroglycan-linked basal lamina contributes to the maintenance of sarcolemmal integrity and protects muscles from damage.

Incorporation of Macromolecules into Living Cells

Publisher Summary This chapter describes the incorporation of macromolecules into living cells. Techniques for loading impermeant molecules into the cytoplasm of living cells have become essential cell and molecular biological tools. There are several variations of the mechanical strategy for temporarily disrupting plasma membrane or its derivatives. Cells allowed to pinocytose macromolecules in hypertonic medium are loaded by osmotically lysing such pinosomes. Scrape loading is another simple technique for loading cell populations with macromolecules. Adherent cells are scraped off of their substratum with a rubber policeman in the presence of the macromolecules to be loaded. The major variable influencing loading and cell yield from the scrape loading procedure is the strength with which cells adhere to their substratum. Radiolabeled molecules can be used as tracers in quantitative measurements of amount of loading. Phase contrast microscopy provides a rapid way of visually assessing cell health and fluorescence microscopy of qualitatively assessing the extent to which individual cells and the population as a whole are loaded.

The endomembrane requirement for cell surface repair

The capacity to reseal a plasma membrane disruption rapidly is required for cell survival in many physiological environments. Intracellular membrane (endomembrane) is thought to play a central role in the rapid resealing response. We here directly compare the resealing response of a cell that lacks endomembrane, the red blood cell, with that of several nucleated cells possessing an abundant endomembrane compartment. RBC membrane disruptions inflicted by a mode-locked Ti:sapphire laser, even those initially smaller than hemoglobin, failed to reseal rapidly. By contrast, much larger laser-induced disruptions made in sea urchin eggs, fibroblasts, and neurons exhibited rapid, Ca2+-dependent resealing. We conclude that rapid resealing is not mediated by simple physiochemical mechanisms; endomembrane is required.

Calpain Is Required for the Rapid, Calcium-dependent Repair of Wounded Plasma Membrane

Mammalian cells require extracellular calcium ion to undergo rapid plasma membrane repair seconds after mechanical damage. Utilizing transformed fibroblasts from calpain small subunit knock-out (Capns1-/-) mouse embryos, we now show that the heterodimeric, typical subclass of calpains is required for calcium-mediated survival after plasma membrane damage caused by scraping a cell monolayer. Survival of scrape-damaged Capns1-/- cells was unaffected by calcium in the scraping medium, whereas more Capns1+/+ cells survived when calcium was present. Calcium-mediated survival was increased when Capns1-/- cells were scraped in the presence of purified m- or μ-calpain. Survival rates of scraped Capns1+/+, HFL-1, or Chinese hamster ovary cells were decreased by the calpain inhibitor, calpeptin, or the highly specific calpain inhibitor protein, calpastatin. Capns1-/- cells failed to reseal following laser-induced membrane disruption, demonstrating that their decreased survival after scraping resulted, at least in part, from failed membrane repair. Proteomic and immunologic analyses demonstrated that the known calpain substrates talin and vimentin were exposed at the cell surface and processed by calpain following cell scraping. Autoproteolytic activation of calpain at the scrape site was evident at the earliest time point analyzed and appeared to precede proteolysis of talin and vimentin. The results indicate that conventional calpains are required for calcium-facilitated survival after plasma membrane damage and may act by localized remodeling of the cortical cytoskeleton at the injury site.

Efficient recovery of dysferlin deficiency by dual adeno-associated vector-mediated gene transfer

Deficiency of the dysferlin protein presents as two major clinical phenotypes: limb-girdle muscular dystrophy type 2B and Miyoshi myopathy. Dysferlin is known to participate in membrane repair, providing a potential hypothesis to the underlying pathophysiology of these diseases. The size of the dysferlin cDNA prevents its direct incorporation into an adeno-associated virus (AAV) vector for therapeutic gene transfer into muscle. To bypass this limitation, we split the dysferlin cDNA at the exon 28/29 junction and cloned it into two independent AAV vectors carrying the appropriate splicing sequences. Intramuscular injection of the corresponding vectors into a dysferlin-deficient mouse model led to the expression of full-length dysferlin for at least 1 year. Importantly, systemic injection in the tail vein of the two vectors led to a widespread although weak expression of the full-length protein. Injections were associated with an improvement of the histological aspect of the muscle, a reduction in the number of necrotic fibers, restoration of membrane repair capacity and a global improvement in locomotor activity. Altogether, these data support the use of such a strategy for the treatment of dysferlin deficiency.