Single-step fabrication of surface waveguides in fused silica with few-cycle laser pulses.

Direct laser writing of surface waveguides with ultrashort pulses is a crucial achievement towards all-laser manufacturing of photonic integrated circuits sensitive to their environment. In this Letter, few-cycle laser pulses (with a sub-10 fs duration) are used to produce subsurface waveguides in a non-doped, non-coated fused-silica substrate. The fabrication technique relies on laser-induced microdensification below the threshold for nanopore formation. The optical losses of the fabricated waveguides are governed by the optical properties of the superstrate. We have measured losses ranging from less than 0.1 dB/mm (air superstrate) up to 2.8 dB/mm when immersion oil is applied on top of the waveguide.

Magneto-Optical Functions at the 3p Resonances of Fe, Co, and Ni: Ab initio Description and Experiment.

We present experimental data and a complete theoretical description of the magneto-optical contributions to the complex refractive index in the extreme ultraviolet (XUV) range covering the 3p resonances of Fe, Co, and Ni. The direct comparison of the two allows us to conclude that many-body corrections to the ground state and local field effects are crucial for an accurate description of M-edge spectra. Our results are relevant for investigation of static magnetization, via XUV spectroscopy of multielement systems, as well as the dynamics of magnetization, as needed in the study of femtomagnetism and spintronics.

Retinal dystrophy in two boys with Costello syndrome due to the HRAS p.Gly13Cys mutation.

Features of Costello Syndrome, a systemic disorder caused by germline mutations in the proto-oncogene HRAS from the RAS/MAPK pathway, include failure-to-thrive, short stature, coarse facial features, cardiac defects including hypertrophic cardiomyopathy, intellectual disability, and predisposition to neoplasia. Two unrelated boys with Costello syndrome and an HRAS mutation (p.Gly13Cys) are presented with their ophthalmologic findings. Both had early symptoms of nystagmus, photophobia, and vision abnormalities. Fundus examination findings of retinal dystrophy were present at age 3 years. Both boys have abnormal electroretinograms with reduced or undetectable rod responses along with reduced cone responses consistent with rod-cone dystrophy. Our observations suggest that early ophthalmic examination and re-evaluations are indicated in children with Costello syndrome.

Uterus Wrapping: A Novel Concept in the Management of Uterine Atony during Cesarean Delivery.

Uterine atony during cesarean delivery is a serious cause of maternal morbidity and mortality. Management strategies include medical treatment with uterotonic agents, manual compression of the uterus, and interventional or surgical procedures. A novel technique to compress the uterus by wrapping it with an elastic bandage and its outcome in 3 cases of uterine atony during cesarean section are presented. Our novel method of intermittent wrapping of the uterus during cesarean delivery seems to be a successful additional approach in the management of uterine atony during cesarean delivery and may be an alternative treatment option to other compressing procedures in order to avoid high blood loss and last but not least postpartum hysterectomy.

Activation of the Unfolded Protein Response in Sporadic Inclusion-Body Myositis but Not in Hereditary GNE Inclusion-Body Myopathy.

Muscle fibers in patients with sporadic inclusion-body myositis (s-IBM),the most common age-associated myopathy, are characterized by autophagic vacuoles and accumulation of ubiquitinated and congophilic multiprotein aggregates that contain amyloid-ß and phosphorylated tau. Muscle fibers of autosomal-recessive hereditary inclusion-body myopathy caused by the GNE mutation (GNE-h-IBM) display similar pathologic features, except with less pronounced congophilia. Accumulation of unfolded/misfolded proteins inside the endoplasmic reticulum (ER) lumen leads to ER stress, which elicits the unfolded protein response (UPR) as a protective mechanism. Here we demonstrate for the first time that UPR is activated in s-IBM muscle biopsies, since there was 1) increased activating transcription factor 4 (ATF4) protein and increased mRNA of its target C/EBP homologous protein; 2) cleavage of the ATF6 and increased mRNA of its target glucose-regulated protein 78; and 3) an increase of the spliced form of X-box binding protein 1 and increased mRNA of ER degradation-enhancing α-mannosidase-like protein, target of heterodimer of cleaved ATF6 and spliced X-box binding protein 1. In contrast, we did not find similar evidence of the UPR induction in GNE-h-IBM patient muscle, suggesting that different intracellular mechanisms might lead to similar pathologic phenotypes. Interestingly, cultured GNE-h-IBM muscle fibers had a robust UPR response to experimental ER stress stimuli, suggesting that the GNE mutation per se is not responsible for the lack of UPR in GNE-h-IBM biopsied muscle.

Diagnostic histochemistry and clinical-pathological testings as molecular pathways to pathogenesis and treatment of the ageing neuromuscular system: a personal view.

Ageing of the neuromuscular system in elderhood ingravescently contributes to slowness, weakness, falling and death, often accompanied by numbness and pain. This article is to put in perspective examples from a half-century of personal and team neuromuscular histochemical-pathological and clinical-pathological research, including a number of lucky and instructive accomplishments identifying new treatments and new diseases. A major focus currently is on some important, still enigmatic, aspects of the ageing neuromuscular system. It is also includes some of the newest references of others on various closely-related aspects of this ageing system. The article may help guide others in their molecular-based endeavors to identify paths leading to discovering new treatments and new pathogenic aspects. These are certainly needed - our ageing and unsteady constituents are steadily increasing. This article is part of a Special Issue entitled: Neuromuscular Diseases: Pathology and Molecular Pathogenesis.

Sporadic inclusion-body myositis: A degenerative muscle disease associated with aging, impaired muscle protein homeostasis and abnormal mitophagy.

Sporadic inclusion-body myositis (s-IBM) is the most common degenerative muscle disease in which aging appears to be a key risk factor. In this review we focus on several cellular molecular mechanisms responsible for multiprotein aggregation and accumulations within s-IBM muscle fibers, and their possible consequences. Those include mechanisms leading to: a) accumulation in the form of aggregates within the muscle fibers, of several proteins, including amyloid-ß42 and its oligomers, and phosphorylated tau in the form of paired helical filaments, and we consider their putative detrimental influence; and b) protein misfolding and aggregation, including evidence of abnormal myoproteostasis, such as increased protein transcription, inadequate protein disposal, and abnormal posttranslational modifications of proteins. Pathogenic importance of our recently demonstrated abnormal mitophagy is also discussed. The intriguing phenotypic similarities between s-IBM muscle fibers and the brains of Alzheimer and Parkinson's disease patients, the two most common neurodegenerative diseases associated with aging, are also discussed. This article is part of a Special Issue entitled: Neuromuscular Diseases: Pathology and Molecular Pathogenesis.

Sodium phenylbutyrate reverses lysosomal dysfunction and decreases amyloid-ß42 in an in vitro-model of inclusion-body myositis.

Sporadic inclusion-body myositis (s-IBM) is a severe, progressive muscle disease for which there is no enduring treatment. Pathologically characteristic are vacuolated muscle fibers having: accumulations of multi-protein aggregates, including amyloid-ß(Aß) 42 and its toxic oligomers; increased γ-secretase activity; and impaired autophagy. Cultured human muscle fibers with experimentally-impaired autophagy recapitulate some of the s-IBM muscle abnormalities, including vacuolization and decreased activity of lysosomal enzymes, accompanied by increased Aß42, Aß42 oligomers, and increased γ-secretase activity. Sodium phenylbutyrate (NaPB) is an orally bioavailable small molecule approved by the FDA for treatment of urea-cycle disorders. Here we describe that NaPB treatment reverses lysosomal dysfunction in an in vitro model of inclusion-body myositis, involving cultured human muscle fibers. NaPB treatment improved lysosomal activity, decreased Aß42 and its oligomers, decreased γ-secretase activity, and virtually prevented muscle-fiber vacuolization. Accordingly, NaPB might be considered a potential treatment of s-IBM patients.

Luminescent conjugated oligothiophenes for sensitive fluorescent assignment of protein inclusion bodies.

Small hydrophobic ligands identifying intracellular protein deposits are of great interest, as protein inclusion bodies are the pathological hallmark of several degenerative diseases. Here we report that fluorescent amyloid ligands, termed luminescent conjugated oligothiophenes (LCOs), rapidly and with high sensitivity detect protein inclusion bodies in skeletal muscle tissue from patients with sporadic inclusion body myositis (s-IBM). LCOs having a conjugated backbone of at least five thiophene units emitted strong fluorescence upon binding, and showed co-localization with proteins reported to accumulate in s-IBM protein inclusion bodies. Compared with conventional amyloid ligands, LCOs identified a larger fraction of immunopositive inclusion bodies. When the conjugated thiophene backbone was extended with terminal carboxyl groups, the LCO revealed striking spectral differences between distinct protein inclusion bodies. We conclude that 1) LCOs are sensitive, rapid and powerful tools for identifying protein inclusion bodies and 2) LCOs identify a wider range of protein inclusion bodies than conventional amyloid ligands.

Chaperone-mediated autophagy components are upregulated in sporadic inclusion-body myositis muscle fibres.

AIMS: Sporadic inclusion-body myositis (s-IBM) is an age-associated degenerative muscle disease. Characteristic features are muscle-fibre vacuolization and intramuscle-fibre accumulations of multiprotein aggregates, which may result from the demonstrated impairments of the 26S proteasome and autophagy. Chaperone-mediated autophagy (CMA) is a selective form of lysosomal degradation targeting proteins carrying the KFERQ motif. Lysosome-associated membrane protein type 2A (LAMP2A) and the heat-shock cognate protein 70 (Hsc70) constitute specific CMA components. Neither CMA components nor CMA activity has been studied in normal or disease human muscle, to our knowledge. METHODS: We studied CMA components by immunocytochemistry, immunoblots, real-time PCR and immunoprecipitation in: (a) 16 s-IBM, nine aged-matched normal and nine disease control muscle biopsies; and (b) cultured human muscle fibres (CHMFs) with experimentally inhibited activities of either the 26S proteasome or autophagy. RESULTS: Compared with age-matched controls, in s-IBM muscle, LAMP2A and Hsc70 were on a given transverse section accumulated as aggregates in approximately 5% of muscle fibres, where they (a) colocalized with each other and α-synuclein (α-syn), a CMA-targeted protein; and (b) were bound to each other and to α-syn by immunoprecipitation. By immunoblots, LAMP2A was increased sevenfold P < 0.001 and Hsc70 2.6-fold P < 0.05. LAMP2A mRNA was increased 4.4-fold P < 0.001 and Hsc70 mRNA 1.9-fold P < 0.05. In CHMFs inhibition of either the 26S proteasome or autophagy induced CMA, evidenced by a significant increase of both LAMP2A and Hsc70. CONCLUSIONS: Our study demonstrates, for the first time, up-regulation of CMA components in s-IBM muscle, and it provides further evidence that altered protein degradation is likely an important pathogenic aspect in s-IBM.

Activation of the γ-secretase complex and presence of γ-secretase-activating protein may contribute to Aß42 production in sporadic inclusion-body myositis muscle fibers.

The muscle-fiber phenotype of sporadic inclusion-body myositis (s-IBM), the most common muscle disease associated with aging, shares several pathological abnormalities with Alzheimer disease (AD) brain, including accumulation of amyloid-ß 42 (Aß42) and its cytotoxic oligomers. The exact mechanisms leading to Aß42 production within s-IBM muscle fibers are not known. Aß42 and Aß40 are generated after the amyloid-precursor protein (AßPP) is cleaved by ß-secretase and the γ-secretase complex. Aß42 is considered more cytotoxic than Aß40, and it has a higher propensity to oligomerize, form amyloid fibrils, and aggregate. Recently, we have demonstrated in cultured human muscle fibers that experimental inhibition of lysosomal enzyme activities leads to Aß42 oligomerization. In s-IBM muscle, we here demonstrate prominent abnormalities of the γ-secretase complex, as evidenced by: a) increase of γ-secretase components, namely active presenilin 1, presenilin enhancer 2, nicastrin, and presence of its mature, glycosylated form; b) increase of mRNAs of these γ-secretase components; c) increase of γ-secretase activity; d) presence of an active form of a newly-discovered γ-secretase activating protein (GSAP); and e) increase of GSAP mRNA. Furthermore, we demonstrate that experimental inhibition of lysosomal autophagic enzymes in cultured human muscle fibers a) activates γ-secretase, and b) leads to posttranslational modifications of AßPP and increase of Aß42. Since autophagy is impaired in biopsied s-IBM muscle, the same mechanism might be responsible for its having increased γ-secretase activity and Aß42 production. Accordingly, improving lysosomal function might be a therapeutic strategy for s-IBM patients.

Pathogenic considerations in sporadic inclusion-body myositis, a degenerative muscle disease associated with aging and abnormalities of myoproteostasis.

The pathogenesis of sporadic inclusion-body myositis (s-IBM) is complex; it involves multidimensional pathways and the most critical issues are still unresolved. The onset of muscle fiber damage is age related and the disease is slowly, but inexorably, progressive. Muscle fiber degeneration and mononuclear cell inflammation are major components of s-IBM pathology, but which is precedent and how they interrelate is not known. There is growing evidence that aging of the muscle fiber associated with intramyofiber accumulation of conformationally modified proteins plays a primary pathogenic role leading to muscle fiber destruction. Here, we review the presumably most important known molecular abnormalities that occur in s-IBM myofibers and that likely contribute to s-IBM pathogenesis. Abnormal accumulation within the fibers of multiprotein aggregates (several of which are congophilic and, therefore, generically called "amyloid") may result from increased transcription of several proteins, their abnormal posttranslational modifications and misfolding, and inadequate protein disposal, that is, abnormal "myoproteostasis," which is combined with and may be provoked or abetted by an aging intracellular milieu. The potential cytotoxicity of accumulated amyloid ß protein (Aß42) and its oligomers, phosphorylated tau in the form of paired helical filaments and α-synuclein, and the putative pathogenic role and cause of the mitochondrial abnormalities and oxidative stress are reviewed. On the basis of our experimental evidence, potential interventions in the complex, interwoven pathogenic cascade of s-IBM are suggested.

Novel demonstration of conformationally modified tau in sporadic inclusion-body myositis muscle fibers.

s-IBM is the most common muscle disease of older persons. Its muscle fiber molecular phenotype has close similarities to Alzheimer disease (AD) brain, including intra-muscle-fiber accumulations of (a) Aß42 and its oligomers, and (b) large, squiggly or linear, clusters of paired-helical filaments (PHFs) that are immunoreactive with various antibodies directed against several epitopes of phosphorylated tau (p-tau), and thereby strongly resembling neurofibrillary tangles of AD brain. In AD brain, conformational changes of tau, including its modifications detectable with specific antibodies TG3 (recognizing phosphorylated-Thr231), and Alz50 and MC1 (both recognizing amino acids 5-15 and 312-322) are considered early and important modifications leading to tau's abnormal folding and assembly into PHFs. We have now identified conformationally modified tau in 14 s-IBM muscle biopsies by (a) light-and electron-microscopic immunohistochemistry, (b) immunoblots, and (c) dot-immunoblots, using TG3, Alz50 and MC1 antibodies. Our double-immunolabeling on the light- and electron-microscopic levels, which combined an antibody against p62 that recognizes s-IBM clusters of PHFs, revealed that TG3 immunodecorated, abundantly and exclusively, all p62 immunopositive clusters, while Alz50 labeling was less abundant, and MC1 was mainly diffusely immunoreactive. Interestingly, in the very atrophic degenerating fibers, TG3 co-localized with PHF-1 antibody that recognizes tau phosphorylated at Ser396/404, which is considered a later change in the formation of PHFs; however, most of TG3-positive inclusions in non-atrophic fibers were immunonegative with PHF-1. None of the 12 normal- and disease-control muscle biopsies contained conformational or PHF-1 immunoreactive tau. This first demonstration of conformational tau in s-IBM, because of its abundance in non-atrophic muscle fibers, suggests that it might play an early role in s-IBM PHFs formation and thus be pathogenically important.

Abnormalities of NBR1, a novel autophagy-associated protein, in muscle fibers of sporadic inclusion-body myositis.

Intra-muscle fiber accumulation of ubiquitinated protein aggregates containing several conformationally modified proteins, including amyloid-ß and phosphorylated tau, is characteristic of the pathologic phenotype of sporadic inclusion-body myositis (s-IBM), the most common progressive degenerative myopathy of older persons. Abnormalities of protein-degradation, involving both the 26S proteasome and autophagic-lysosomal pathways, were previously demonstrated in s-IBM muscle. NBR1 is a ubiquitin-binding scaffold protein importantly participating in autophagic degradation of ubiquitinated proteins. Whereas abnormalities of p62, a ubiquitin-binding protein, were previously described in s-IBM, abnormalities of NBR1 have not been reported in s-IBM. We have now identified in s-IBM muscle biopsies that NBR1, by: (a) immunohistochemistry, was strongly accumulated within s-IBM muscle-fiber aggregates, where it closely co-localized with p62, ubiquitin, and phosphorylated tau; (b) immunoblots, was increased threefold (p < 0.001); and (c) immunoprecipitation, was associated with p62 and LC3. By real-time PCR, NBR1 mRNA was increased twofold (p < 0.01). None of the various disease- and normal-control muscle biopsies had any NBR1 abnormality. In cultured human muscle fibers, NBR1 also physically associated with both p62 and LC3, and experimental inhibition of either the 26S proteasome or the lysosomal activity resulted in NBR1 increase. Our demonstration of NBR1 abnormalities in s-IBM provides further evidence that altered protein degradation pathways may be critically involved in the s-IBM pathogenesis. Accordingly, attempts to unblock defective protein degradation might be a therapeutic strategy for s-IBM patients.

Overexpression of Lis1 in different stages of spermatogenesis does not result in an aberrant phenotype.

Previous studies showed that in the mouse mutant Lis1(GT/GT) gene trap integration in intron 2 of Lis1 gene leads to male infertility in homozygous Lis1(GT/GT) mice. We further analyzed this line and could confirm the suggested downregulation of a testis-specific Lis1 transcript in mutant animals in a quantitative manner. Moreover, we analyzed the gene trap mutation on different genetic backgrounds in incipient congenic animals and could exclude a genetic background effect. To gain further insights into the role and requirement of LIS1 in spermatogenesis, 3 transgenic lines were generated, that overexpress Lis1 under control of the testis-specific promoters hEF-1α, which is exclusively active in spermatogonial cells, PGK2, which is active in pachytene spermatocytes and following stages of spermatogenesis, and Tnp2 which is active in round spermatids and following stages of spermatogenesis, respectively. All 3 transgenic lines remained fertile and testis sections displayed no abnormalities. To overcome the infertility of Lis1(GT/GT) males, these transgenic Lis1-overexpressing animals were mated with Lis1(GT/GT) mice to generate 'rescued' Lis1(GT/GT)/Lis1(Tpos) males. 'Rescued' animals from all transgenic lines remained infertile, thus overexpression of Lis1 in different stages of spermatogenesis could not rescue the infertility phenotype of homozygous gene trap males.

Sporadic inclusion-body myositis: conformational multifactorial ageing-related degenerative muscle disease associated with proteasomal and lysosomal inhibition, endoplasmic reticulum stress, and accumulation of amyloid-ß42 oligomers and phosphorylated tau.

The pathogenesis of sporadic inclusion-body myositis (s-IBM), the most common muscle disease of older persons, is complex and multifactorial. Both the muscle fiber degeneration and the mononuclear-cell inflammation are components of the s-IBM pathology, but how each relates to the pathogenesis remains unsettled. We consider that the intramuscle fiber degenerative component plays the primary and the major pathogenic role leading to muscle fiber destruction and clinical weakness. In this article we review the newest research advances that provide a better understanding of the s-IBM pathogenesis. Cellular abnormalities occurring in s-IBM muscle fibers are discussed, including: several proteins that are accumulated in the form of aggregates within muscle fibers, including amyloid-ß42 and its oligomers, and phosphorylated tau in the form of paired helical filaments, and we consider their putative detrimental influence; cellular mechanisms leading to protein misfolding and aggregation, including evidence of their inadequate disposal; pathogenic importance of endoplasmic reticulum stress and the unfolded protein response demonstrated in s-IBM muscle fibers; and decreased deacetylase activity of SIRT1. All these factors are combined with, and perhaps provoked by, an ageing intracellular milieu. Also discussed are the intriguing phenotypic similarities between s-IBM muscle fibers and the brains of Alzheimer and Parkinson's disease patients, the two most common neurodegenerative diseases associated with ageing. Muscle biopsy diagnostic criteria are also described and illustrated.

Double aberration correction in a low-energy electron microscope.

The lateral resolution of a surface sensitive low-energy electron microscope (LEEM) has been improved below 4 nm for the first time. This breakthrough has only been possible by simultaneously correcting the unavoidable spherical and chromatic aberrations of the lens system. We present an experimental criterion to quantify the aberration correction and to optimize the electron optical system. The obtained lateral resolution of 2.6 nm in LEEM enables the first surface sensitive, electron microscopic observation of the herringbone reconstruction on the Au(111) surface.