A highly sensitive molecular structural probe applied to in situ biosensing of metabolites using PEDOT:PSS

A large amount of research within organic biosensors is dominated by organic electrochemical transistors (OECTs) that use conducting polymers such as poly(3,4-ethylene dioxythiophene) doped with poly(styrenesulfonate) (PEDOT:PSS). Despite the recent advances in OECT-based biosensors, the sensing is solely reliant on the amperometric detection of the bioanalytes. This is typically accompanied by large undesirable parasitic electrical signals from the electroactive components in the electrolyte. Herein, we present the use of in situ resonance Raman spectroscopy to probe subtle molecular structural changes of PEDOT:PSS associated with its doping level. We demonstrate how such doping level changes of PEDOT:PSS can be used, for the first time, on operational OECTs for sensitive and selective metabolite sensing while simultaneously performing amperometric detection of the analyte. We test the sensitivity by molecularly sensing a lowest glucose concentration of 0.02 mM in phosphate-buffered saline solution. By changing the electrolyte to cell culture media, the selectivity of in situ resonance Raman spectroscopy is emphasized as it remains unaffected by other electroactive components in the electrolyte. The application of this molecular structural probe highlights the importance of developing biosensing probes that benefit from high sensitivity of the material's structural and electrical properties while being complimentary with the electronic methods of detection.     

RNA-dependent association with myosin IIA promotes F-actin-guided trafficking of the ELAV-like protein HuR to polysomes

The role of the mRNA-binding protein human antigen R (HuR) in stabilization and translation of AU-rich elements (ARE) containing mRNAs is well established. However, the trafficking of HuR and bound mRNA cargo, which comprises a fundamental requirement for the aforementioned HuR functions is only poorly understood. By administering different cytoskeletal inhibitors, we found that the protein kinase Cδ (PKCδ)-triggered accumulation of cytoplasmic HuR by Angiotensin II (AngII) is an actin-myosin driven process functionally relevant for stabilization of ARE-bearing mRNAs. Furthermore, we show that the AngII-induced recruitment of HuR and its bound mRNA from ribonucleoprotein particles to free and cytoskeleton bound polysomes strongly depended on an intact actomyosin cytoskeleton. In addition, HuR allocation to free and cytoskeletal bound polysomes is highly sensitive toward RNase and PPtase and structurally depends on serine 318 (S318) located within the C-terminal RNA recognition motif (RRM3). Conversely, the trafficking of the phosphomimetic HuRS318D, mimicking HuR phosphorylation at S318 by the PKCδ remained PPtase resistant. Co-immunoprecipitation experiments with truncated HuR proteins revealed that the stimulus-induced association of HuR with myosin IIA is strictly RNA dependent and mediated via the RRM3. Our data implicate a microfilament dependent transport of HuR, which is relevant for stimulus-induced targeting of ARE-bearing mRNAs from translational inactive ribonucleoprotein particles to polysomes.     

CRISPRmap: an automated classification of repeat conservation in prokaryotic adaptive immune systems

Central to Clustered Regularly Interspaced Short Palindromic Repeat (CRISPR)-Cas systems are repeated RNA sequences that serve as Cas-protein–binding templates. Classification is based on the architectural composition of associated Cas proteins, considering repeat evolution is essential to complete the picture. We compiled the largest data set of CRISPRs to date, performed comprehensive, independent clustering analyses and identified a novel set of 40 conserved sequence families and 33 potential structure motifs for Cas-endoribonucleases with some distinct conservation patterns. Evolutionary relationships are presented as a hierarchical map of sequence and structure similarities for both a quick and detailed insight into the diversity of CRISPR-Cas systems. In a comparison with Cas-subtypes, I-C, I-E, I-F and type II were strongly coupled and the remaining type I and type III subtypes were loosely coupled to repeat and Cas1 evolution, respectively. Subtypes with a strong link to CRISPR evolution were almost exclusive to bacteria; nevertheless, we identified rare examples of potential horizontal transfer of I-C and I-E systems into archaeal organisms. Our easy-to-use web server provides an automated assignment of newly sequenced CRISPRs to our classification system and enables more informed choices on future hypotheses in CRISPR-Cas research: http://rna.informatik.uni-freiburg.de/CRISPRmap.     

Supersize me—new insights into cortical expansion and gyration of the mammalian brain

EMBO J 32 13, 1817–1828 doi:10.1038/emboj.2013.96; published online April262013During evolution, the mammalian brain massively expanded its size. However, the exact roles of distinct neural precursors, identified in the developing cortex during embryogenesis, for size expansion and surface folding (i.e., gyration) remain largely unknown. New findings by Nonaka-Kinoshita et al advance our understanding of embryonic neural precursor function by identifying cell type-selective functions for size expansion and folding, and challenge previously held concepts of mammalian brain development.Over the course of evolution, the mammalian brain massively expanded its size and complexity, which is believed to be responsible for an increase in cognitive functions and intellectual skills. The increase in brain size and number of cortical neurons is primarily due to an increased surface area by generating folds (gyrations) while the cortical thickness remained relatively constant (Lui et al, 2011). In the last decade, substantial progress has been made in identifying the cellular sources of cortex development. Using genetic lineage tracing of individual cell populations and time-lapse imaging of rodent and human slices of the embryonic cortex, radial glial cells (RGCs) were identified as the primary progenitors or neural stem cells (NSCs) in the developing cortex (Gotz and Huttner, 2005). Simplified, RG in the ventricular zone (VZ) line the ventricular surface and self-renew through symmetric divisions or give rise to basal progenitors (BPs; also called intermediate progenitors) in the subventricular zone (SVZ) that typically divide symmetrically and generate neurons. In contrast to the lissencephalic rodent brain, the developing cortex of gyrated mammals (e.g., humans and ferrets) contains a large number of basal radial glial (bRG) cells that reside in the outer subventricular zone (OSVZ), retain a cellular process that is connected to the pial surface and that are, in contrast to BPs, multipotent, meaning that they have the potency to generate diverse neural cell types (Fietz et al, 2010; Hansen et al, 2010; Reillo et al, 2011).Largely based on the anatomical differences between the developing cortex of lissencephalic and gyrencephalic brains, several hypotheses have been formulated aiming to explain the massive increase in size and induction of brain folding during mammalian evolution. One prominent hypothesis, called the radial unit hypothesis, suggests that the expansion of RGCs lining the ventricle leads to an increase of radial units that generate neurons and thus is responsible for the increase of surface area (Rakic, 1995). Others proposed that the increase in size and folding could be due to an increase in BP expansion in the SVZ compared to RGC numbers in the VZ, a hypothesis called the intermediate progenitor model (Kriegstein et al, 2006). These hypotheses were helpful to start explaining mammalian brain evolution, but testing the exact role of different neural precursors remained extremely challenging due to technical difficulties to selectively manipulating the proliferative activity of distinct precursor populations. Even though previous approaches were successful in enhancing brain size/neuron numbers in mouse models (e.g., by ectopically enhancing WNT signalling activity or manipulating the activity of the small RhoGTPase Cdc42 in neural precursors), these strategies had the drawback that the normal six-layered cortical topography was disrupted, making it difficult to draw definite conclusions (Chenn and Walsh, 2002; Cappello et al, 2006).In a collaborative work from the Calegari and Borrell laboratories, Nonaka-Kinoshita et al, 2013 now used an elegant approach to selectively enhance proliferation of distinct precursor populations in the mouse and ferret developing cortex. They used a previously described approach manipulating cell cycle length and subsequently proliferation by overexpressing the cell cycle regulators cdk4 and cyclinD1 that is sufficient to enhance neurogenesis without affecting cortical layering (a system called 4D) (Lange et al, 2009). For their mouse experiments, Nonaka-Kinoshita et al used a transgenic strategy to transiently overexpress 4D in nestin-expressing precursors using a tetracycline-controlled gene expression system (nestin^rtTA/tetbi^4D). With this approach, they selectively enhanced proliferation of BPs in the SVZ without affecting the number or proliferation of RGCs in the VZ (Nonaka-Kinoshita et al, 2013). Strikingly, targeted expansion of BPs induced a substantial increase in surface area but was not sufficient to induce cortical folding in the otherwise smooth mouse cortex, challenging the radial unit hypothesis and the intermediate progenitor model with regard to their predictions on the effects on size and/or gyration of the cortex upon expansion of the BP pool. Complementing their findings of BP expansion in the lissencephalic mouse brain, Nonaka-Kinoshita et al used retroviral vectors and electroporation of 4D expression constructs to target 4D expression to neural precursors in the developing ferret cortex that is gyrated under physiological conditions. In the ferret, 4D expression induced proliferation of multipotent bRG located in the OSVZ, as outlined above, a cell type that is found predominantly in gyrated cortices compared to lissencephalic brains. Notably, enhanced proliferation of bRG triggered the formation of novel cortical folds, suggesting that indeed the expansion of bRG may represent a key event during evolution to induce gyration and subsequent surface expansion of the mammalian brain (Borrell and Reillo, 2012; Nonaka-Kinoshita et al, 2013) (Figure 1). This now experimentally supported hypothesis is strongly reinforced by two recent publications: one from (Tuoc et al, 2013) who found that deletion of the chromatin remodelling protein BAF170 increases the BP pool and subsequently enhances brain size; and another one from the Götz laboratory where it was found that experimentally reduced expression levels of the DNA-associated protein Trnp1 substantially increased the expansion of bRG and BPs, inducing folding of the normally lissencephalic mouse brain (Stahl et al, 2013). Taken together, these studies suggest that bRG in the OSVZ play an important role in cortical folding by enhancing the generation of neurons and by providing a glial scaffold for newborn neurons to disperse more laterally and thus to form folds in the developing brain (Reillo et al, 2011).Open in a separate windowFigure 1How different neural precursors appear to regulate size expansion and folding during mammalian brain development. (A) Shown are the main cellular components of the cortex of the lissencephalic mouse brain during embryonic development with RGCs (blue) lining the lateral ventricles in the VZ that generate BPs (yellow) in the SVZ and provide a scaffold for migrating neurons (left; green). Note that the mouse developing brain contains only a few bRG in the OSVZ (red). Notably, expansion of BPs using the 4D strategy developed in the Calegari laboratory increases surface area of the murine cortex without inducing the folding of the smooth mouse brain surface (right panel). (B) In contrast to lissencephalic animals, the developing cortices of species with gyrated brains (e.g., humans and ferrets) contain a substantial number of bRG located in the OSVZ (left panel). 4D-based, virus-mediated expansion of bRG in the ferret cortex leads to the induction of additional folds in the ferret cortex, indicating that the proliferative activity of bRG is critically involved in the extent of folding in physiologically gyrated brains (right panel).Even though this new study challenges previously held concepts regarding size expansion and folding of the mammalian brain, future studies are required that even more selectively enhance the proliferation and expansion of distinct precursor subtypes with high temporal and spatial control. Thus, the combination of sophisticated genetic tools to enhance precursor activity with detailed molecular analyses (e.g., analysing gene expression in highly folded versus unfolded brain regions, an approach that already showed differential levels of Trnp1 expression; Stahl et al, 2013) and live-imaging studies in the developing mammalian cortex will further enhance the understanding how our brains developed during evolution.     

Defective Autophagy and mTORC1 Signaling in Myotubularin Null Mice

Autophagy is a vesicular trafficking pathway that regulates the degradation of aggregated proteins and damaged organelles. Initiation of autophagy requires several multiprotein signaling complexes, such as the ULK1 kinase complex and the Vps34 lipid kinase complex, which generates phosphatidylinositol 3-phosphate [PtdIns(3)P] on the forming autophagosomal membrane. Alterations in autophagy have been reported for various diseases, including myopathies. Here we show that skeletal muscle autophagy is compromised in mice deficient in the X-linked myotubular myopathy (XLMTM)-associated PtdIns(3)P phosphatase myotubularin (MTM1). Mtm1-deficient muscle displays several cellular abnormalities, including a profound increase in ubiquitin aggregates and abnormal mitochondria. Further, we show that Mtm1 deficiency is accompanied by activation of mTORC1 signaling, which persists even following starvation. In vivo pharmacological inhibition of mTOR is sufficient to normalize aberrant autophagy and improve muscle phenotypes in Mtm1 null mice. These results suggest that aberrant mTORC1 signaling and impaired autophagy are consequences of the loss of Mtm1 and may play a primary role in disease pathogenesis.     

Molecular structure,spectroscopic (FT-IR,FT-Raman,UV–vis), NBO,thermochemistry analysis of bis(thiourea)zinc(II) chloride crystals

The experimental and theoretical studies on the molecular structure and vibrational spectra of bis(thiourea)zinc(II) chloride (BTZC) crystals were investigated. The Fourier transform infrared, Fourier transform Raman and UV–vis spectra of BTZC were recorded. The molecular geometry and vibrational frequencies of BTZC in the ground state were calculated by using B3LYP with LANL2DZ as basis set. Comparison of the observed structural parameters of BTZC with single-crystal X-ray studies yields a good agreement. Vibrational analysis of the simultaneous IR and Raman activation of the Zn–Cl stretching mode in the molecule provides the evidence for the charge transfer interaction taking place within the molecule. The energy and oscillator strength are calculated by time-dependent density functional theory. The simulated spectra satisfactorily coincide with the experimental spectra.     

ARF1 controls Rac1 signaling to regulate migration of MDA-MB-231 invasive breast cancer cells

ADP-ribosylation factors (ARFs) are monomeric G proteins that regulate many cellular processes such as reorganization of the actin cytoskeleton. We have previously shown that ARF1 is overexpressed in highly invasive breast cancer cells and contribute to their enhanced migration. In this study, we propose to define the molecular mechanism by which ARF1 regulates this complex cellular response by investigating the role of this ARF GTPase on the activation process of Rac1, a Rho GTPase, associated with lamellipodia formation during cell migration. Here, we first show that inhibition of ARF1 or Rac1 expression markedly impacts the ability of MDA-MB-231 cells to migrate upon EGF stimulation. However, the effect of ARF1 depletion can be reversed by overexpression of the Rac1 active mutant, Rac1 Q⁶¹L. Depletion of ARF1 also impairs the ability of EGF stimulation to promote GTP-loading of Rac1. To further investigate the possible cross-talk between ARF1 and Rac1, we next examined whether they could form a complex. We observed that the two GTPases could directly interact independently of the nature of the nucleotide bound to them. EGF treatment however resulted in the association of Rac1 with its effector IRSp53, which was completely abrogated in ARF1 depleted cells. We present evidences that this ARF isoform is responsible for the plasma membrane targeting of both Rac1 and IRSp53, a step essential for lamellipodia formation. In conclusion, this study provides a new mechanism by which ARF1 regulates cell migration and identifies this GTPase as a promising pharmacological target to reduce metastasis formation in breast cancer patients.     

Spatio-temporal mapping of local soil pH changes induced by roots of lupin and soft-rush

Aims

The rhizosphere is a dynamic system strongly influenced by root activity. Roots modify the pH of their surrounding soil causing the soil pH to vary as a function of distance from root surface, location along root axes, and root maturity. Non-invasive imaging techniques provide the possibility to capture pH patterns around the roots as they develop.

Methods

We developed a novel fluorescence imaging set up and applied to the root system of two lupin (Lupinus albus L., Lupinus angustifolius L.) and one soft-rush (Juncus effusus L.) species. We grew plants in glass containers filled with soil and equipped with fluorescence sensor foils on the container side walls. We gained highly-resolved data on the spatial distribution of H⁺ around the roots by taking time-lapse images of the samples over the course of several days.

Results

We showed how the soil pH in the vicinity of roots developed over time to different values from that of the original bulk soil. The soil pH in the immediate vicinity of the root surface varied greatly along the root length, with the most acidic point being at 0.56–3.36 mm behind the root tip. Indications were also found for temporal soil pH changes due to root maturity.

Conclusion

In conclusion, this study shows that this novel optical fluorescence imaging set up is a powerful tool for studying pH developments around roots in situ.     

Loss of Starch Granule Initiation Has a Deleterious Effect on the Growth of Arabidopsis Plants Due to an Accumulation of ADP-Glucose

STARCH SYNTHASE4 (SS4) is required for proper starch granule initiation in Arabidopsis (Arabidopsis thaliana), although SS3 can partially replace its function. Unlike other starch-deficient mutants, ss4 and ss3/ss4 mutants grow poorly even under long-day conditions. They have less chlorophyll and carotenoids than the wild type and lower maximal rates of photosynthesis. There is evidence of photooxidative damage of the photosynthetic apparatus in the mutants from chlorophyll a fluorescence parameters and their high levels of malondialdehyde. Metabolite profiling revealed that ss3/ss4 accumulates over 170 times more ADP-glucose (Glc) than wild-type plants. Restricting ADP-Glc synthesis, by introducing mutations in the plastidial phosphoglucomutase (pgm1) or the small subunit of ADP-Glc pyrophosphorylase (aps1), largely restored photosynthetic capacity and growth in pgm1/ss3/ss4 and aps1/ss3/ss4 triple mutants. It is proposed that the accumulation of ADP-Glc in the ss3/ss4 mutant sequesters a large part of the plastidial pools of adenine nucleotides, which limits photophosphorylation, leading to photooxidative stress, causing the chlorotic and stunted growth phenotypes of the plants.The metabolism of starch plays an essential role in the physiology of plants. Starch breakdown provides the plant with carbon skeletons and energy when the photosynthetic machinery is inactive (transitory starch) or in the processes of germination and sprouting (storage starch). Deficiencies in the accumulation of transitory starch in Arabidopsis (Arabidopsis thaliana) have been described previously, specifically in mutants affected in the plastidial phosphoglucomutase (PGM1) or the small subunit (APS1) of the ADP-Glc pyrophosphorylase (AGPase). While they are described as “starchless,” they actually contain small amounts of starch (1%–2% of the wild-type levels; Streb et al., 2009) and share similar phenotypic alterations, such as growth retardation when cultivated under a short-day photoregime and increased levels of soluble sugars during the light phase and reduced levels during the night (Caspar et al., 1985; Lin et al., 1988b; Schulze et al., 1991). Carbon partitioning is altered in these plants. As photosynthate cannot be accumulated as starch, it is diverted via hexose phosphates in the cytosol to the synthesis of Suc, which accumulates together with the hexose sugars, Glc and Fru (Caspar et al., 1985). In Arabidopsis, there are five starch synthase isoforms: one granule-bound starch synthase and four soluble starch synthases: SS1, SS2, SS3, and SS4. We have described previously an Arabidopsis mutant plant lacking SS3 and SS4 that is also severely affected in the accumulation of starch (Szydlowski et al., 2009). SS4 is involved in the initiation of the starch granule and controls the number of granules per chloroplast (Roldán et al., 2007). The elimination of SS3 in an ss4 background leads to an absence of starch in most of the chloroplasts, despite the fact that SS1 and SS2 are still present and total starch synthase activity is only reduced by 35% (Szydlowski et al., 2009). However, a very small proportion of chloroplasts of this mutant plant contain a single huge starch granule, which is also a characteristic of chloroplasts in the ss4 single mutant (D’Hulst and Mérida, 2012). Thus, like aps1 and pgm1, ss3/ss4 plants contain only small amounts of starch. However, unlike aps1 or pgm1 plants, most of the cells of this mutant have empty chloroplasts, without starch (Szydlowski et al., 2009).In this work, we have analyzed the phenotypic effects of the impaired starch accumulation of ss3/ss4 plants. We show that this mutant displays phenotypic changes that are not found in other mutants with very low levels of starch, such as aps1 or pgm1 plants. We provide evidence that extremely high levels of ADP-Glc accumulate in the ss3/ss4 plants. Using reverse genetics to block the pathway of starch synthesis upstream of the starch synthases reduced the level of ADP-Glc in ss3/ss4 plants and reverted the other phenotypic traits. This suggests that ADP-Glc accumulation is the causal factor behind the chlorotic and stunted growth phenotypes of the ss3/ss4 mutant.