Myosin mediates contractile force generation by hepatic stellate cells in response to endothelin-1

Although endothelin-1-stimulated contractile force generation by stellate cells is believed to play an important role in hepatic pathophysiology, the molecular signals that mediate this process are incompletely understood. The aim of this study was to test the hypothesis that myosin mediates the contractile force generated by stellate cells in response to endothelin-1. Contractile force generation by primary and immortalized stellate cells was directly and quantitatively measured. Myosin phosphorylation and reorganization, and actin stress fiber formation were investigated in immortalized stellate cells. Endothelin-1 stimulated a rapid and robust generation of contractile force by primary and immortalized stellate cells with a similar dose dependence. Myosin phosphorylation, actin stress fiber assembly, and reorganization of myosin to stress fibers were induced by concentrations of endothelin-1 that also stimulated stellate cell contraction. BQ-123, a selective endothelin receptor antagonist, inhibited myosin phosphorylation and contractile force generation. Y-27632, which selectively inhibits rho-associated kinase, also blocked endothelin-1-stimulated myosin phosphorylation and contractile force generation with a similar dose dependence. These results suggest that endothelin-1-stimulated contractile force generation by stellate cells is mediated by myosin.

Effects of exercise on senescent muscle

Strength conditioning will result in an increase in muscle size and this increase in size is largely the result of increased contractile proteins. The mechanisms by which the mechanical events stimulate an increase in ribonucleic acid synthesis and subsequent protein synthesis are not well understood. Lifting weight requires that a muscle shorten as it produces force (concentric contraction). Lowering the weight, however, forces the muscle to lengthen as it produces force (eccentric contraction). These lengthening muscle contractions have been shown to produce ultrastructural damage (microscopic tears in contractile proteins muscle cells) that may stimulate increased muscle protein turnover. This muscle damage produces a cascade of metabolic events that is similar to an acute phase response and includes complement activation, mobilization of neutrophils, increased circulation of skeletal muscle interleukin-1, macrophage accumulation in muscle, and an increase in muscle protein synthesis and degradation. Although endurance exercise increases the oxidation of essential amino acids and increases the requirement for dietary protein, resistance exercise results in a decrease in nitrogen excretion, lowering dietary protein needs. This increased efficiency of protein use may be important for wasting diseases such as human immunodeficiency virus infection and cancer and particularly in elderly people suffering from sarcopenia. Research has indicated that increased dietary protein intake (as much as 1.6 g protein x kg x day ) may enhance the hypertrophic response to resistance exercise. It also has been shown that in very old men and women the use of a protein-calorie supplement was associated with greater strength and muscle mass gains than the use of placebo.

The role of contractile microfilaments in the morphogenesis of the developing foregut of chick embryos

The cellular processes that lead to changes in shape (morphogenesis) and organ formation (organogenesis) are poorly understood. Local contraction of microfilaments can change cell shape and lead to changes of tissue shape. To clarify the role of contractile microfilaments in the foregut morphogenesis of chick embryos, 2- to 4-day-old embryos were exposed to cytochalasin D (CD), which is known to disrupt microfilaments. Untreated age-matched embryos were used as controls. Sections of treated embryos and controls were stained with phalloidin, which binds to actin, and examined with a fluorescence microscope. Microdissected specimens were examined using a scanning electron microscope (SEM). Immunofluorescent staining showed a bright signal belt toward the apical cell region of the foregut epithelium in controls. This signal was not evident in CD-exposed embryos. SEM micrographs of the controls showed the cranial foregut as a smooth, even, cylindrical structure in all stages studied. The lumen was narrow and perfectly straight, the ventral and dorsal walls were in close apposition. The foregut of CD-exposed specimens, however, showed a wide lumen and the walls were separated from each other. The structure seemed atonic and appeared conical, curved, or tilted. We observed a dense microfilament network toward the apical cell pole of the epithelial foregut cells of controls that was no longer evident after CD exposure. This network seems to play an important role in foregut morphogenesis, since actin-filament disruption by CD causes loss of the normal shape.

Calcium-sensing receptor activation of rho involves filamin and rho-guanine nucleotide exchange factor

We investigated the role of Galphaq, filamin, Rho, the RhoGEF Lbc, and the C terminus of calcium-sensing receptor (CasR) in CasR signaling. We found that Ca(2+), Mg(2+), or the calcimimetic R isomer of N-(3-[2-chlorophenyl]propyl)-(R)-alpha-methyl-3-methoxybenzylamine (NPS-R568) stimulated serum response element (SRE) activity human embryonic kidney 293 cells transfected with CasR and an SRE-luciferase reporter construct. Coexpression of either the dominant negative Galphaq(305-359) minigene, regulators of G protein signaling (RGS)2 or RGS4, inhibited CasR-stimulated SRE activity, consistent with CasR activation of Galphaq. The cytoskeletal associated Rho protein is involved CasR activation of SRE, as evidenced by CasR-mediated increase in membrane-associated Rho A and by the ability of Clostridium botulinum C3 (C3) exoenzyme to inhibit both CasR and GalphaqQL-stimulated SRE activity. Overexpression of the RhoGEF Lbc, lacking either the Dbl-homology or Pleckstrin homology domain, as well as the filamin peptide (1530-1875) inhibited CasR-mediated activation of SRE. A carboxyl-terminal CasR minigene, CasR(906-980), encoding a filamin binding region, also blocked CasR- and GalphaqQL-stimulated SRE activity. Potential interactions between CasR, RhoGEF Lbc, Rho A, Galphaq, and filamin were demonstrated by reciprocal coimmunoprecipitation studies. Our results suggest that the C terminus of CasR may interact with filamin to create a cytoskeletal scaffold necessary for the spatial organization of Galphaq, RhoGEF Lbc, and Rho signaling pathways upstream of SRE activation.

Studies of myosin isoforms in muscle cells: single cell mechanics and gene transfer

Myosin, the motor protein in skeletal muscle, is composed of two subunits, myosin heavy chain and myosin light chain. All vertebrates express a family of myosin heavy chain and myosin light chain isoforms that together are primary determinants of force, velocity, and power in muscle fibers. Therefore, appropriate expression of myosin isoforms in skeletal muscle is critical to proper motor function. Myosin isoform expression is highly plastic and undergoes significant changes in response to muscular injury, muscle disuse, and disease. Therefore, myosin isoform function and plasticity are highly relevant to clinical orthopaedic research, musculoskeletal surgery, and sports medicine. Muscle from frogs offers a special opportunity to study the structural basis of contractile protein function because single intact fibers can be isolated that maintain excellent mechanical stability, allowing for high-resolution studies of contractile performance in intact cells. The current authors summarize recent studies defining the myosin isoforms in muscle from frogs and the relationship between myosin isoforms and mechanical performance of intact single muscle cells. Preliminary studies also are described that show the potential for simple plasmid-based in vivo gene transfer approaches as a model system to elucidate the structural basis of muscle protein function in intact cells.

Microfibril-associated glycoprotein-2 interacts with fibrillin-1 and fibrillin-2 suggesting a role for MAGP-2 in elastic fiber assembly

Elastic fibers are composed of the protein elastin and a network of 10-12 nm microfibrils. The microfibrillar proteins include, among others, the fibrillins and microfibril-associated glycoproteins-1 and -2 (MAGP-1 and MAGP-2). Little is known about how microfibrillar proteins interact to support fiber assembly. We used the C-terminal half of MAGP-2 in a yeast two-hybrid library screen to identify relevant ligands. Six of 13 positive clones encoded known microfibrillar proteins, including fibrillin-1 and -2. Deletion analysis of partial fibrillin-1 and -2 clones revealed a calcium-binding epidermal growth factor repeat-containing region near the C terminus responsible for binding. This region is distinct from the region of fibrillin-1 reported by others to bind MAGP-1. The MAGP-2 bait was unable to interact productively with other epidermal growth factor repeats in fibrillin-1, demonstrating specificity of the interaction. Deletion analysis of the MAGP-2 bait demonstrated that binding occurred in a core region containing 48% identity and 7 conserved cysteine residues with MAGP-1. Immunoprecipitation of MAGP-2 from transfected COS-7 cells resulted in the coprecipitation of fibrillin. These results demonstrate that MAGP-2 specifically interacts with fibrillin-1 and -2 and suggest that MAGP-2 may help regulate microfibrillar assembly. The results also demonstrate the utility of the yeast two-hybrid system to study protein-protein interactions of the extracellular matrix.

[Mechanism of nitric oxide's effect on the sensitivity of smooth muscle contractions to calcium]

It was investigated whether the SH-groups of contractile proteins are involved in NO-induced relaxation of saponin-skinned smooth muscle strips. Both, the thiol-specific alkylating agent N-ethylmaleamide (NEM), and thiol-reducing agent dithiotreitol (DTT) induced relaxation of maximally activated skinned rat portal vein preparations. The relaxing effects of DTT and nitric oxide donor sodium nitroprusside were not additive. After the relaxation, induced by one of this agent, the effect of the other one was negligible. We suggest that NO-induced smooth muscle relaxation be due to decreasing of force sensitivity to Ca2+. This effect of nitric oxide is realized by its interaction with critical thiol groups of smooth muscle contractile proteins.

Contractile actin expression in torn human menisci

The human meniscus is subject to injury that necessitates repair or removal. Many aspects of the cellular response to injury have not been well characterized. The purpose of this study was to describe the cellular distributions within the torn human meniscus. In addition to evaluating the cell density in selected regions, we investigated the cellular expression of a contractile actin isoform that has recently been found in the intact human meniscus. Included as a contemporaneous comparative group were torn human meniscal allografts. We hypothesized that a hypercellular surface zone would be found in the torn menisci, with a higher percentage of cells in this peripheral region expressing alpha-smooth muscle actin compared with other locations in the interior of the remnant. The rationale for this hypothesis was based on prior immunohistochemical investigations of the distribution of alpha-smooth muscle actin-containing cells in the torn human anterior cruciate ligament. Eighteen torn meniscal specimens were obtained from 17 patients, 0.5 to 84 months after injury, and four torn allograft meniscal samples were retrieved from three patients, 11 to 49 months after implantation. Microtomed sections of paraffin-embedded tissue were stained with hematoxylin and eosin and a monoclonal antibody to alpha-smooth muscle actin. The cell density and percentage of cells containing alpha-smooth muscle actin were determined in the following zones: synovial, vascular, hypercellular with loose collagen, hypocellular with dense collagen, and organized collagen. A cellular layer that resembled synovium was present on the surface of all but two of the specimens. Vascular regions were often continuous with the synovium abutting the more interior loose collagen zones. The total cell density was greatest in each of the zones closest to the periphery (synovium, vascular, and loose collagen; p < 0.001), when compared to the interior of the tissue. The synovium-like layer was found to have the highest percentage of alpha-smooth muscle actin-expressing cells and the highest alpha-smooth muscle actin-containing cell density (p < 0.05). Similar results were found for the torn allograft menisci. These findings confirm the working hypothesis and suggest that the torn human meniscus is capable of mounting a reparative response, including the proliferation of cells capable of contributing to wound closure. This underscores the importance of providing a bridging scaffold into which such cells can migrate.

Filamin A-interacting protein (FILIP) regulates cortical cell migration out of the ventricular zone

Precisely regulated radial migration out of the ventricular zone is essential for corticogenesis. Here, we identify a mechanism that can tether ventricular zone cells in situ. FILIP interacts with Filamin A, an indispensable actin-binding protein that is required for cell motility, and induces its degradation in COS-7 cells. Degradation of Filamin A is identified in the cortical ventricular zone, where filip mRNA is localized. Furthermore, most ventricular zone cells that overexpress FILIP fail to migrate in explants. These results demonstrate that FILIP functions through a Filamin A F-actin axis to control the start of neocortical cell migration from the ventricular zone.

The etiology of adolescent idiopathic scoliosis

The etiology of adolescent idiopathic scoliosis (AIS), the most common form of scoliosis, is unclear. Researchers with divergent perspectives have tried to better define this etiology. Genetics, growth hormone secretion, connective tissue structure, muscle structure, vestibular dysfunction, melatonin secretion, and platelet microstructure are major areas of focus. In this article, we review the literature in these areas and present the consensus on proposed hypotheses. Studies that simplify the etiology to a single factor have been inconclusive or unsuccessful. Most likely, the etiology is multifactorial, and reported associations are links in pathogenesis rather than etiologic factors. Research is needed to better define the role of all factors in AIS development.

Contractile properties, structure and fiber phenotype of intact and regenerating slow-twitch muscles of mice treated with cyclosporin A

We have studied the contractile properties, structure, fiber-type composition, and myosin heavy chain (MyHC) expression pattern of regenerating and intact soleus muscles of adult CBA/J mice treated with cyclosporin A (CsA) or vehicle solutions (Cremophor, saline). A comparison of muscles after 4-7 weeks drug application with those receiving vehicle showed that the isometric contractile force of intact drug-treated muscles was reduced (tetanus, -21%; twitch, -34%) despite normal mass and muscle cross-sectional area. The frequency of fast-twitch fibers was increased, whereas no innervation deficits, histopathological alterations, or changes in fiber numbers were observed. Regeneration after cryolesion of the contralateral soleus proceeded more slowly in CsA-treated than in vehicle-treated animals. Despite this, when muscle properties reached mature levels (4-7 weeks), muscle mass recovery was better in CsA-treated animals (30% higher weight, 50% more fiber profiles in cross-sections). The force production per unit cross-sectional area was deficient, but not the maximum tension. Twitch time-to-peak and half-relaxation time were shorter than controls correlating with a predominance of fast-twitch fibers (98% Type II fibers versus 16%-18% in control muscles) and fast MyHC isoforms. Partial reversal of this fast phenotype and an increase in muscle force were observed when the animals were left to recover without treatment for 5-8 weeks after CsA application over 7 weeks. The high numbers of fiber profiles in CsA-treated regenerated muscles and increased mass remained unchanged after withdrawal. Thus, CsA treatment has a hyperplastic effect on regenerating muscles, and drug-induced phenotype alterations are much more prominent in regenerated muscles.

Expression profiling of cardiac genes in human hypertrophic cardiomyopathy: insight into the pathogenesis of phenotypes

OBJECTIVES

The goal of this study was to identify genes upregulated in the heart in human patients with hypertrophic cardiomyopathy (HCM).

BACKGROUND

Hypertrophic cardiomyopathy is a genetic disease caused by mutations in contractile sarcomeric proteins. The molecular basis of diverse clinical and pathologic phenotypes in HCM remains unknown.

METHODS

We performed polymerase chain reaction-select complementary DNA subtraction between normal hearts and hearts with HCM and screened subtracted libraries by Southern blotting. We sequenced the differentially expressed clones and performed Northern blotting to detect increased expression levels.

RESULTS

We screened 288 independent clones, and 76 clones had less than twofold increase in the signal intensity and were considered upregulated. Sequence analysis identified 36 genes including those encoding the markers of pressure overload-induced ("secondary") cardiac hypertrophy, cytoskeletal proteins, protein synthesis, redox system, ion channels and those with unknown function. Northern blotting confirmed increased expression of skeletal muscle alpha-actin (ACTA1), myosin light chain 2a (MLC2a), GTP-binding protein Gs-alpha subunit (GNAS1), NADH ubiquinone oxidoreductase (NDUFB10), voltage-dependent anion channel 1 (VDAC1), four-and-a-half LIM domain protein 1 (FHL1) (also known as SLIM1), sarcosin (SARCOSIN) and heat shock 70kD protein 8 (HSPA8) by less than twofold. Expression levels of ACTA1, MLC2a and GNAS1 were increased in six additional and FHL1 in four additional hearts with HCM.

CONCLUSIONS

A diverse array of genes is upregulated in the heart in human patients with HCM, which could account for the diversity of clinical and pathologic phenotypes. Markers of secondary hypertrophy are also upregulated, suggesting commonality of pathways involved in HCM and the acquired forms of cardiac hypertrophy. Elucidation of the role of differentially expressed genes in HCM could provide for new therapeutic targets.

Lung tissue mechanics and extracellular matrix remodeling in acute lung injury

This study was undertaken to test whether there is structural remodeling of lung parenchyma that could lead to tissue mechanical changes at an early phase of varying degrees of acute lung injury (ALI). Tissue resistance (R), dynamic elastance (E), and hysteresivity (eta) were analyzed during sinusoidal oscillations of rat lung parenchymal strips 24 h after intraperitoneal injection of saline (C) or paraquat (P [10, 15, 25, and 30 mg/kg]). These strips were also stained in order to quantify the amount of collagen and of three types of elastic fibers (elaunin, oxytalan, and fully developed elastic fibers) in the alveolar septa. E augmented progressively from C to P25, but the data from the P25 and P30 groups were not different (p < 0.0001). R and eta increased from C to P10 and from P15 to P25 (p < 0.001). Collagen fiber content increased exponentially with the severity of the injury. Elaunin and fully developed elastic fibers remained unchanged in the five groups, while oxytalan fibers increased only in the P25 and P30 groups. In conclusion, the pronounced mechanical changes at the tissue level and fibroelastogenesis happened at an early phase of the disease and even in mildly abnormal lung parenchyma.

KEYWORDS

elastance; collagen fibers; elastin; paraquat

Interaction of the calcium-sensing receptor and filamin, a potential scaffolding protein

In many cases, the biologic responses of cells to extracellular signals and the specificity of the responses cannot be explained solely on the basis of the interactions of known signaling proteins. Recently, scaffolding and adaptor proteins have been identified that organize signaling proteins in cells and that contribute to the nature and specificity of signaling pathways. In an effort to identify proteins that might organize the signaling system(s) activated by the extracellular Ca(2+) receptor (CaR), we used a bait construct representing the intracellular C terminus of the human CaR and the yeast two hybrid system to screen a human kidney cDNA library. We identified a clone representing the C-terminal 1042 amino acids (aa) of the cytoskeletal protein filamin (ABP-280). Analysis of truncation and deletion constructs of the CaR C terminus and the filamin cDNA clone demonstrated that the CaR and filamin interact via regions containing aa 907-997 of the CaR C terminus and aa 1566-1875 of filamin. Interaction of the two proteins in mammalian HEK-293 cells was demonstrated by co-immunoprecipitation and colocalization of them using immunofluorescence microscopy. The functional importance of their interaction was documented by transiently expressing the CaR in M2 melanoma cells that lack filamin, or in A7 melanoma cells that stably express filamin, and demonstrating that the CaR activated ERK only in the presence of filamin. Co-expression of the CaR with a peptide derived from the region of the CaR C terminus that interacts with filamin reduced the ability of the CaR to activate p42ERK in a dose-dependent manner, but did not inhibit the ability of the ET(A) receptor to activate ERK. The fact that filamin interacts with the CaR and other cell signaling proteins including mitogen-activated protein kinases and small GTPases, indicates that it may act as a scaffolding protein to organize cell signaling systems involving the CaR.

Computer-aided measurement of cell shortening and calcium transients in adult cardiac myocytes

The contractile cycle of the cardiac myocyte is essentially controlled by the concentration of intracellular calcium ([Ca2+]i). Measurement of [Ca2+]i using Ca2+-dependent fluorescence and simultaneous monitoring of cell dynamics enable characterization of a variety of substances interacting with ion channels and contractile proteins. In this report we describe a novel method featuring up to 480 frames/s for monitoring rapid changes in cellular calcium and cell length, in which every individual cycle allows effective evaluation of major cell parameters. Computers aid in determination of time to peak (in ms), time to 50% decrease (ms), diastolic Ca2+ (relative fluorescence units, rfu), systolic Ca2+ (rfu), Ca2+ transients (rfu), DeltaCa2+/Delta(t) rise (rfu/s), and DeltaCa2+/Delta(t) fall (rfu/s). Contractile parameters are as follows: maximum cell length (microm), minimum cell length (microm), absolute cell shortening (microm), peak DeltaL/Delta(t) shortening (microm/s), and peak DeltaL/Delta(t) relaxation (microm/s). In summary, we succeeded in demonstrating that this system is a unique and valuable tool that allows simultaneous and accurate assessment of contractile parameters and of calcium movements of isolated adult cardiac myocytes.

Contraction and polymerization cooperate to assemble and close actomyosin rings around Xenopus oocyte wounds

Xenopus oocytes assemble an array of F-actin and myosin 2 around plasma membrane wounds. We analyzed this process in living oocytes using confocal time-lapse (four-dimensional) microscopy. Closure of wounds requires assembly and contraction of a classic "contractile ring" composed of F-actin and myosin 2. However, this ring works in concert with a 5-10-microm wide "zone" of localized actin and myosin 2 assembly. The zone forms before the ring and can be uncoupled from the ring by inhibition of cortical flow and contractility. However, contractility and the contractile ring are required for the stability and forward movement of the zone, as revealed by changes in zone dynamics after disruption of contractility and flow, or experimentally induced breakage of the contractile ring. We conclude that wound-induced contractile arrays are provided with their characteristic flexibility, speed, and strength by the combined input of two distinct components: a highly dynamic zone in which myosin 2 and actin preferentially assemble, and a stable contractile actomyosin ring.

Filamins as integrators of cell mechanics and signalling

Filamins are large actin-binding proteins that stabilize delicate three-dimensional actin webs and link them to cellular membranes. They integrate cellular architectural and signalling functions and are essential for fetal development and cell locomotion. Here, we describe the history, structure and function of this group of proteins.

Manipulating the contractile apparatus: genetically defined animal models of cardiovascular disease

Within the last 10 years via gene targeting and transgenesis, numerous models of cardiovascular disease have been established and used to determine if a protein's presence or absence causes cardiovascular disease. By affecting the heart's protein complement in a defined manner, the function of the different mutated proteins or protein isoforms present in the contractile apparatus can be determined and pathogenic mechanism(s) explored. We can now remodel the cardiac protein profile and effect replacement of even the most abundant contractile proteins. Precise genetic manipulation allows exploration of the structure-function relationships which underlie cardiac function, and the consequences of defined mutations at the molecular, biochemical, cytological and physiologic levels can be determined.

Filamin (280-kDa actin-binding protein) is a caspase substrate and is also cleaved directly by the cytotoxic T lymphocyte protease granzyme B during apoptosis

We used yeast two-hybrid screening to identify the cytoskeletal protein filamin as a ligand for the proapoptotic protease granzyme B, produced by cytotoxic T lymphocytes. Filamin was directly cleaved by granzyme B when target cells were exposed to granzyme B and the lytic protein perforin, but it was also cleaved in a caspase-dependent manner following the ligation of Fas receptors. A similar pattern of filamin cleavage to polypeptides of approximately 110 and 95 kDa was observed in Jurkat cells killed by either mechanism. However, filamin cleavage in response to granzyme B was not inhibited by the caspase inhibitor z-Val-Ala-Asp-fluoromethylketone at concentrations that abolished DNA fragmentation. Filamin staining was redistributed from the cell membrane into the cytoplasm of Jurkat cells exposed to granzyme B and perforin and following ligation of Fas receptors, coincident with the morphological changes of apoptosis. Filamin-deficient human melanoma cells were significantly (although not completely) protected from granzyme B-mediated death compared with isogenic filamin-expressing cells, both in clonogenic survival and (51)Cr release assays, whereas death from multiple other stimuli was not affected by filamin deficiency. Thus, filamin is a functionally important substrate for granzyme B, as its cleavage may account at least partly for caspase-independent cell death mediated by the granzyme.

Embryonic morphogenesis in Caenorhabditis elegans integrates the activity of LET-502 Rho-binding kinase, MEL-11 myosin phosphatase, DAF-2 insulin receptor and FEM-2 PP2c phosphatase

let-502 rho-binding kinase and mel-11 myosin phosphatase regulate Caenorhabditis elegans embryonic morphogenesis. Genetic analysis presented here establishes the following modes of let-502 action: (i) loss of only maternal let-502 results in abnormal early cleavages, (ii) loss of both zygotic and maternal let-502 causes elongation defects, and (iii) loss of only zygotic let-502 results in sterility. The morphogenetic function of let-502 and mel-11 is apparently redundant with another pathway since elimination of these two genes resulted in progeny that underwent near-normal elongation. Triple mutant analysis indicated that unc-73 (Rho/Rac guanine exchange factor) and mlc-4 (myosin light chain) act in parallel to or downstream of let-502/mel-11. In contrast mig-2 (Rho/Rac), daf-2 (insulin receptor), and age-1 (PI3 kinase) act within the let-502/mel-11 pathway. Mutations in the sex-determination gene fem-2, which encodes a PP2c phosphatase (unrelated to the MEL-11 phosphatase), enhanced mutations of let-502 and suppressed those of mel-11. fem-2's elongation function appears to be independent of its role in sexual identity since the sex-determination genes fem-1, fem-3, tra-1, and tra-3 had no effect on mel-11 or let-502. By itself, fem-2 affects morphogenesis with low penetrance. fem-2 blocked the near-normal elongation of let-502; mel-11 indicating that fem-2 acts in a parallel elongation pathway. The action of two redundant pathways likely ensures accurate elongation of the C. elegans embryo.

Mechanisms and disturbances of neuronal migration

Neuronal migration appears as a complex ontogenic step occurring early during embryonic and fetal development. Control of neuronal migration involves different cell populations including Cajal-Retzius neurons, subplate neurons, neuronal precursors or radial glia. The integrity of multiple molecular mechanisms, such as cell cycle control, cell-cell adhesion, interaction with extracellular matrix protein, neurotransmitter release, growth factor availability, platelet-activating factor degradation or transduction pathways seems to be critical for normal neuronal migration. The complexity and the multiplicity of these mechanisms probably explain the clinical, radiologic and genetic heterogeneity of human disorders of neuronal migration. The present review will be focused on mechanisms and disturbances of migration of neurons destined to the neocortex. New insights gained from the analysis of animal models as well as from the study of human diseases will be included.

Androgen receptor nuclear translocation is facilitated by the f-actin cross-linking protein filamin

The human androgen receptor (hAR) is a ligand-dependent transcription factor responsible for the development of the male phenotype. The mechanism whereby nuclear translocation of the hAR is induced by its natural ligand 5alpha-dihydrotestosterone is a phenomenon not fully understood. The two-hybrid interaction trap assay has been used to isolate proteins that interact with the hAR in an attempt to identify molecules involved in hAR transactivation and movement. We have identified the actin-binding protein filamin, a 280-kDa component of the cytoskeleton, as an hAR interacting protein. This interaction is ligand independent but is enhanced in its presence. The functional significance of this interaction was analyzed using a cell line deficient in filamin via transient expression of a green fluorescent protein-hAR chimera. In filamin-deficient cells this revealed that hAR remained cytoplasmic even after prolonged exposure to synthetic ligand. Nuclear shuttling was restored when this cell line regained wild-type expression of filamin. These data suggest a novel role for filamin, implicating it as an important molecule in AR movement from the cytoplasm to the nucleus.

Remodeling the cardiac sarcomere using transgenesis

An underpinning of basic physiology and clinical medicine is that specific protein complements underlie cell and organ function. In the heart, contractile protein changes correlating with functional alterations occur during both normal development and the development of numerous pathologies. What has been lacking for the majority of these observations is an extension of correlation to causative proof. More specifically, different congenital heart diseases are characterized by shifts in the motor proteins, and the genetic etiologies of a number of different dilated and hypertrophic cardiomyopathies have been established as residing at loci encoding the contractile proteins. To establish cause, or to understand development of the pathophysiology over an animal's life span, it is necessary to direct the heart to synthesize, in the absence of other pleiotropic changes, the candidate protein. Subsequently one can determine whether or how the protein's presence causes the effects either directly or indirectly. By affecting the heart's protein complement in a defined manner, the potential to establish the function of different proteins and protein isoforms exists. Transgenesis provides a means of stably modifying the mammalian genome. By directing expression of engineered proteins to the heart, cardiac contractile protein profiles can be effectively remodeled and the resultant animal used to study the consequences of a single, genetic manipulation at the molecular, biochemical, cytological, and physiological levels.

Differential effects of 4-chloro-m-cresol and caffeine on skinned fibers from rat fast and slow skeletal muscles

Contractile responses to 4-chloro-m-cresol (4-CmC) were tested in saponin- and Triton X-100-skinned fibers from soleus and edl (extensor digitorum longus) muscles of adult rats and compared with those to caffeine. The testing of different concentrations of 4-CmC on saponin-skinned fibers showed that 4-CmC induced a dose-dependent caffeine-like transient contractile response in edl and soleus due to an activation of the ryanodine receptor. Both types of skeletal muscles showed a 10 to 20 times lower 4-CmC threshold concentration and EC(50) value (concentration providing 50% of the maximal 4-CmC contracture) than for caffeine. The results indicate that edl is more sensitive than soleus to 4-CmC and that this difference in sensitivity is more marked than with caffeine. Furthermore, an increase in cytosolic Ca(2+) activity induced a more marked shift of dose-response curves toward lower concentrations for 4-CmC than caffeine. Experiments conducted on Triton X-100-skinned fibers showed that in both muscles, 4-CmC decreased in a dose-dependent manner the Ca(2+)-activated force of contractile apparatus, particularly in edl. Furthermore, the tension pCa curves indicated that 4-CmC induced a dose-dependent sensitizing (soleus) or desensitizing (edl) effect on the Ca(2+) sensitivity of myofibrils. These results indicate that edl and soleus contractile responses can be discriminated with 4-CmC instead of caffeine and that care must be taken in interpreting results because muscular pathology could be due in part to an increase in intracellular Ca(2+).