Philip J. Young

Dysregulation of ubiquitin homeostasis and β-catenin signaling promote spinal muscular atrophy

The autosomal recessive neurodegenerative disease spinal muscular atrophy (SMA) results from low levels of survival motor neuron (SMN) protein; however, it is unclear how reduced SMN promotes SMA development. Here, we determined that ubiquitin-dependent pathways regulate neuromuscular pathology in SMA. Using mouse models of SMA, we observed widespread perturbations in ubiquitin homeostasis, including reduced levels of ubiquitin-like modifier activating enzyme 1 (UBA1). SMN physically interacted with UBA1 in neurons, and disruption of Uba1 mRNA splicing was observed in the spinal cords of SMA mice exhibiting disease symptoms. Pharmacological or genetic suppression of UBA1 was sufficient to recapitulate an SMA-like neuromuscular pathology in zebrafish, suggesting that UBA1 directly contributes to disease pathogenesis. Dysregulation of UBA1 and subsequent ubiquitination pathways led to β-catenin accumulation, and pharmacological inhibition of β-catenin robustly ameliorated neuromuscular pathology in zebrafish, Drosophila, and mouse models of SMA. UBA1-associated disruption of β-catenin was restricted to the neuromuscular system in SMA mice; therefore, pharmacological inhibition of β-catenin in these animals failed to prevent systemic pathology in peripheral tissues and organs, indicating fundamental molecular differences between neuromuscular and systemic SMA pathology. Our data indicate that SMA-associated reduction of UBA1 contributes to neuromuscular pathogenesis through disruption of ubiquitin homeostasis and subsequent β-catenin signaling, highlighting ubiquitin homeostasis and β-catenin as potential therapeutic targets for SMA.

A Mechanism of Release of Calreticulin from Cells During Apoptosis

Calreticulin (CRT) is an endoplasmic reticulum (ER) chaperone responsible for glycoprotein folding and Ca(2+) homeostasis. CRT also has extracellular functions, e.g. tumor and apoptotic cell recognition and wound healing, but the mechanism of CRT extracellular release is unknown. Cytosolic localization of CRT is determined by signal peptide and subsequent retrotranslocation of CRT into the cytoplasm. Here, we show that under apoptotic stress conditions, the cytosolic concentration of CRT increases and associates with phosphatidylserine (PS) in a Ca(2)(+)-dependent manner. PS distribution is regulated by aminophospholipid translocase (APLT), which maintains PS on the cytosolic side of the cell membrane. APLT is sensitive to redox modifications of its SH groups by reactive nitrogen species. During apoptosis, both CRT expression and the concentration of nitric oxide (NO) increase. By using S-nitroso-l-cysteine-ethyl-ester, an intracellular NO donor and inhibitor of APLT, we showed that PS and CRT externalization occurred together in an S-nitrosothiol-dependent and caspase-independent manner. Furthermore, the CRT and PS are relocated as punctate clusters on the cell surface. Thus, CRT induced nitrosylation and its externalization with PS could explain how CRT acts as a bridging molecule during apoptotic cell clearance.

Minute Virus of Mice NS1 Interacts with the SMN Protein, and They Colocalize in Novel Nuclear Bodies Induced by Parvovirus Infection

ABSTRACT The human survival motor neuron (SMN) gene is the spinal muscular atrophy-determining gene, and a knockout of the murine Smn gene results in preembryonic lethality. Here we show that SMN can directly interact in vitro and in vivo with the large nonstructural protein NS1 of the autonomous parvovirus minute virus of mice (MVM), a protein essential for viral replication and a potent transcriptional activator. Typically, SMN localizes within nuclear Cajal bodies and diffusely in the cytoplasm. Following transient NS1expression, SMN and NS1 colocalize within Cajal bodies. At early time points following parvovirus infection, NS1 fails to colocalize with SMN within Cajal bodies; however, during the course of MVM infection, dramatic nuclear alterations occur. Formerly distinct nuclear bodies such as Cajal bodies, promyelocytic leukemia gene product (PML) oncogenic domains (PODs), speckles, and autonomous parvovirus-associated replication (APAR) bodies are seen aggregating at later points in infection. These newly formed large nuclear bodies (termed SMN-associated APAR bodies) are active sites of viral replication and viral capsid assembly. These results highlight the transient nature of nuclear bodies and their contents and identify a novel nuclear body formed during infection. Furthermore, simple transient expression of the viral nonstructural proteins is insufficient to induce this nuclear reorganization, suggesting that this event is induced specifically by a step in the viral infection process.

SMN, Gemin2 and Gemin3 Associate with β-Actin mRNA in the Cytoplasm of Neuronal Cells In Vitro

Childhood spinal muscular atrophy is caused by a reduced expression of the survival motor neuron (SMN) protein. SMN has been implicated in the axonal transport of beta-actin mRNA in both primary and transformed neuronal cell lines, and loss of this function could account, at least in part, for spinal muscular atrophy onset and pathological specificity. Here we have utilised a targeted screen to identify mRNA associated with SMN, Gemin2 and Gemin3 in the cytoplasm of a human neuroblastoma cell line, SHSY5Y. Importantly, we have provided the first direct evidence that beta-actin mRNA is present in SMN cytoplasmic complexes in SHSY5Y cells.

Minute Virus of Mice Small Nonstructural Protein NS2 Interacts and Colocalizes with the Smn Protein

ABSTRACT The small nonstructural protein NS2 of the minute virus of mice (MVM) is required for efficient viral replication, although its mode of action is unclear. Here we demonstrate that NS2 and survival motor neuron protein (Smn) interact in vitro and in vivo. NS2 and Smn also colocalize in infected nuclei at late times following MVM infection.

A survival motor neuron:tetanus toxin fragment C fusion protein for the targeted delivery of SMN protein to neurons

Spinal muscular atrophy (SMA) is a degenerative disorder of spinal motor neurons caused by homozygous mutations in the survival motor neuron (SMN1) gene. Because increased tissue levels of human SMN protein (hSMN) in transgenic mice reduce the motor neuron loss caused by murine SMN knockout, we engineered a recombinant SMN fusion protein to deliver exogenous hSMN to the cytosolic compartment of motor neurons. The fusion protein, SDT, is comprised of hSMN linked to the catalytic and transmembrane domains of diphtheria toxin (DTx) followed by fragment C of tetanus toxin (TTC). Following overexpression in Escherichia coli, SDT possessed a subunit molecular weight of approximately 130 kDa as revealed by both SDS-PAGE and immunoblot analyses with anti-SMN, anti-DTx, and anti-TTC antibodies. Like wild-type SMN, purified SDT showed specific binding in vitro to an RG peptide derived from Ewings sarcoma protein. The fusion protein also bound to cultured primary neurons in amounts similar to those achieved by TTC. Unlike the case with TTC, however, immunolabeling of SDT-treated neurons with anti-TTC and anti-SMN antibodies showed staining restricted to the cell surface. Results from cytotoxicity studies in which the DTx catalytic domain of SDT was used as a reporter protein for internalization and membrane translocation activity suggest that the SMN moiety of the fusion protein is interfering with one or both of these processes. While these studies indicate that SDT may not be useful for SMA therapy, the use of the TTC:DTx fusion construct to deliver other passenger proteins to the neuronal cytosol should not be ruled out.

Lysyl tRNA synthetase is required for the translocation of calreticulin to the cell surface in immunogenic death

In response to immunogenic cell death inducers, calreticulin (CRT) translocates from its orthotopic localization in the lumen of the endoplasmic reticulum (ER) to the surface of the plasma membrane where it serves as an engulfment signal for antigen-presenting cells.1 Here, we report that yet another ER protein, the lysyl-tRNA synthetase (KARS), was exposed on the surface of stressed cells, on which KARS co-localized with CRT in lipid rafts. Depletion of KARS with small interfering RNAs suppressed CRT exposure induced by anthracyclines or UVC light. In contrast to CRT, KARS was also found in the supernatant of stressed cells. Recombinant KARS protein was unable to influence the binding of recombinant CRT to the cell surface. Moreover, recombinant KARS protein was unable to stimulate macrophages in vitro. These results underscore the contribution of KARS to the emission of (one of) the principal signal(s) of immunogenic cell death, CRT exposure.

SMN and the Gemin proteins form sub-complexes that localise to both stationary and dynamic neurite granules.

Childhood spinal muscular atrophy (SMA) is caused by a reduction in survival motor neuron (SMN) protein. SMN is expressed in every cell type, but it is predominantly the lower motor neurones of the spinal cord that degenerate in SMA. SMN has been linked to the axonal transport of beta-actin mRNA, a breakdown in which could trigger disease onset. It is known that SMN is present in transport ribonucleoproteins (RNPs) granules that also contain Gemin2 and Gemin3. To further characterise these granules we have performed live cell imaging of GFP-tagged SMN, GFP-Gemin2, GFP-Gemin3, GFP-Gemin6 and GFP-Gemin7. In all, we have made two important observations: (1) SMN granules appear metamorphic; and (2) the SMN-Gemin complex(es) appears to localise to two distinct subsets of bodies in neurites; stationary bodies and smaller dynamic bodies. This study provides an insight into the neuronal function of the SMN complex.

Monitoring of recombinant survival motor neuron protein using fiber-optic surface plasmon resonance.

Spinal muscular atrophy (SMA) is the leading genetic cause of infant mortality. SMA is caused by the homozygous loss of the survival motor neuron 1 (SMN1) gene. A nearly identical copy gene exists known as SMN2, however, due to an aberrant splicing event, the SMN2 gene fails to produce sufficient full-length protein to protect against disease development in the absence of SMN1. While a number of compounds have recently been identified that can stimulate full-length survival motor neuron (SMN) expression from the nearly identical copy SMN2, one of the difficulties has been the lack of a highly reproducible and quantitative means to measure the levels of SMN protein. To develop a technique that allows the rapid and highly sensitive measurement of SMN protein, a Surface Plasmon Resonance (SPR) application has been developed. The ability to quantify unassociated SMN protein and monitor the binding of SMN with other proteins in solution using a SPR sensor in less than 15 min and at low ng mL(-1) levels in HEPES Buffer Saline (HBS) has been achieved. The detection limit for the specific binding of SMN in HBS pH 7.4 solution is 0.99 ng mL(-1) with non-specific binding accounting for approximately 30% of the signal. Quantification of SMN is based on an immunoassay performed on the gold surface of the SPR sensor. 16-mercaptohexadecanoic acid (MHA) was reacted with dicyclohexylcarbodiimide (DCC) and N-hydroxysuccinimide (NHS) to form a pre-activated thiol (MHA-NHS). Antibodies for SMN were then coupled to the sensor with the pre-activated thiol. Sensor specificity was examined with mixtures of myoglobin (MG) and SMN. SMN sensor response decreases by more than 60% when MG was added to SMN. The decrease in sensor response can be attributed to non-specific binding of SMN to MG, verified with a sensor for MG.

Identification of a self-association domain in the Ewing’s sarcoma protein: a novel function for arginine-glycine-glycine rich motifs?

The Ewings sarcoma (EWS) protein is a ubiquitously expressed RNA chaperone. The EWS protein localizes predominantly to the nucleus. Previous reports have suggested that the EWS protein is capable of dimerizing. However, to date this has not been confirmed. Here, using a novel panel of recombinant proteins, we have performed an in vitro biomolecular interaction analysis of the EWS protein. We have demonstrated that all three arginine-glycine-glycine (RGG) motifs are capable of binding directly to the survival motor neuron protein, a Tudor domain containing EWS binding partner. We have also confirmed EWS is capable of self-associating, and we have mapped this binding domain to the RGG motifs. We have also found that self-association may be required for EWS nuclear import. This is the first direct evidence of RGG domains being involved in self-association and has implications on all RGG-containing proteins.