Secondary Alterations of Sphingolipid Metabolism in Lysosomal Storage Diseases

In several neurodegenerative diseases, sphingolipid metabolism is deeply deregulated, leading to the expression of abnormal membrane sphingolipid patterns and altered plasma membrane organization. In this paper, we review the potential importance of these alterations to the pathogenesis of these diseases and focus the reader’s attention on some secondary alterations of sphingolipid metabolism that have been sporadically reported in the literature. Moreover, we present a detailed analysis of the lipid composition of different central nervous system and extraneural tissues from the acid sphingomyelinase-deficient mouse, the animal model for Niemann-Pick disease type A, characterized by the accumulation of sphingomyelin. Our data show an unexpected, tissue specific selection of the accumulated molecular species of sphingomyelin, and an accumulation of GM3 and GM2 gangliosides in both neural and extraneural tissues, that cannot be solely explained by the lack of acid sphingomyelinase.     

Vancomycin-resistance Transferability from VanA Enterococci to <Emphasis Type="Italic">Staphylococcus aureus</Emphasis>

In last decade methicillin-resistant Staphylococcus aureus with high level of vancomycin-resistance (VRSA) have been reported and generally the patients with VRSA infection were also infected with a vancomycin-resistant Enterococcus (VRE). Considering that the high level of vancomycin-resistance in VRSA isolates seems to involve the horizontal transfer of Tn1546 transposon containing vanA gene from coinfecting VRE strains, the authors have studied the “in vitro” conjugative transfer of this resistance from VanA enterococci to S. aureus. Out of 25 matings performed combining five vancomycin-resistant enterococci as donors (three Enterococcus faecalis and two Enterococcus faecium), and five S. aureus as recipients, all clinical isolates, two have been successful using E. faecalis as donor. The transfer of vancomycin-resistance was confirmed by vanA gene amplification in both transconjugants and the resistance was expressed at lower levels (MIC 32 μg/ml) in comparison with the respective VRE donors (MIC > 128 μg/ml). The vancomycin-resistance of trasconjugants was maintained even after subsequent overnight passages on MSA plates containing subinhibitory levels of vancomycin. This study shows that the vanA gene transfer can be achieved through techniques “in vitro” without the use of laboratory animals employed, in the only similar experiment previously carried out by other authors, as substrate for the trasconjugant growth. Moreover, in that previous experiment, contrary to this study, the vancomycin resistant S. aureus trasconjugants were selected on erythromycin agar and not by direct vancomycin agar selection.     

Evolution of the TIR domain-containing adaptors in humans: swinging between constraint and adaptation

Natural selection is expected to act strongly on immune system genes as hosts adapt to novel, diverse, and coevolving pathogens. Population genetic studies of host defense genes with parallel functions in model organisms have revealed distinct evolutionary histories among the different components-receptors, adaptors, and effectors-of the innate immune system. In humans, however, detailed evolutionary studies have been mainly confined to the receptors and in particular to Toll-like receptors (TLRs). By virtue of a toll/interleukin-1 receptor (TIR) domain, TLRs activate distinct signaling pathways, which are mediated by the five TIR-containing adaptors: myeloid differentiation factor-88 (MyD88), myeloid differentiation factor-88 adaptor-like protein (MAL), toll/interleukin-1 receptor domain-containing adaptor protein inducing interferon (IFN)β (TRIF), toll/interleukin-1 receptor domain-containing adaptor protein inducing IFNβ-related adaptor molecule (TRAM), and sterile α- and armadillo motif-containing protein (SARM). Here, we have examined the extent to which natural selection has affected immune adaptors in humans, using as a paradigm the TIR-containing adaptors. To do so, we characterized their levels of naturally occurring genetic variation in various human populations. We found that MyD88 and TRIF have mainly evolved under purifying selection, suggesting that their role in the early stages of signal transduction is essential and nonredundant for host survival. In addition, the adaptors have been targeted by multiple episodes of positive selection, differing in timing and spatial location. MyD88 and SARM display signatures of a selective sweep that has occurred in all humans, whereas for the other three adaptors, we detected signatures of adaptive evolution that are restricted to specific populations. Our study provides evidence that the contemporary diversity of the five TIR-containing adaptors results from the intermingling of different selective events, swinging between constraint and adaptation.     

Excitatory projection neuron subtypes control the distribution of local inhibitory interneurons in the cerebral cortex

In the mammalian cerebral cortex, the developmental events governing the integration of excitatory projection neurons and inhibitory interneurons into balanced local circuitry are poorly understood. We report that different subtypes of projection neurons uniquely and differentially determine the laminar distribution of cortical interneurons. We find that in Fezf2?/? cortex, the exclusive absence of subcerebral projection neurons and their replacement by callosal projection neurons cause distinctly abnormal lamination of interneurons and altered GABAergic inhibition. In addition, experimental generation of either corticofugal neurons or callosal neurons below the cortex is sufficient to recruit cortical interneurons to these ectopic locations. Strikingly, the identity of the projection neurons generated, rather than strictly their birthdate, determines the specific types of interneurons recruited. These data demonstrate that in the neocortex individual populations of projection neurons cell-extrinsically control the laminar fate of interneurons and the assembly of local inhibitory circuitry.     

Proteasome inhibitors sensitize glioma cells and glioma stem cells to TRAIL-induced apoptosis by PKCε-dependent downregulation of AKT and XIAP expressions

In this study we examined the effects of proteasome inhibitors on cell apoptosis in TRAIL-resistant glioma cells and glioma stem cells (GSCs). Treatment with proteasome inhibitors and TRAIL induced apoptosis in all the resistant glioma cells and GSCs, but not in astrocytes and neural progenitor cells. Since PKCε has been implicated in the resistance of glioma cells to TRAIL, we examined its role in TRAIL and proteasome inhibitor-induced apoptosis. We found that TRAIL did not induce significant changes in the expression of PKCε, whereas a partial decrease in PKCε expression was obtained by proteasome inhibitors. A combined treatment of TRAIL and proteasome inhibitors induced accumulation of the catalytic fragment of PKCε and significantly and selectively decreased its protein and mRNA levels in the cancer but not in normal cells. Overexpression of PKCε partially inhibited the apoptotic effect of the proteasome inhibitors and TRAIL, and the caspase-resistant PKCεD383A mutant exerted a stronger inhibitory effect. Silencing of PKCε induced cell apoptosis in both glioma cells and GSCs, further supporting its role in cell survival. TRAIL and the proteasome inhibitors decreased the expression of AKT and XIAP in a PKCε-dependent manner and overexpression of these proteins abolished the apoptotic effect of this treatment. Moreover, silencing of XIAP sensitized glioma cells to TRAIL. Our results indicate that proteasome inhibitors sensitize glioma cells and GSCs to TRAIL by decreasing the expression of PKCε, AKT and XIAP. Combining proteasome inhibitors with TRAIL may be useful therapeutically in the treatment of gliomas and the eradication of GSCs.     

PKCε acts as negative allosteric modulator of EGF receptor signalling

Protein kinase C ε (PKCε) is a transforming oncogene and plays a pivotal role in numerous cellular processes including proliferation, invasion and differentiation. Recently, we described a function of PKCε as a scaffold protein linking PLCγ1 to the EGFR module. Here, in the head and neck squamous carcinoma cell line (HNSCC) FaDu we demonstrate that over-expressed PKCε may be associated with the EGFR. This is linked with the consecutive inhibition of the recruitment of PLCγ1 to the EGFR, of the catalytical activation of PLCγ1 by EGF, and of the PLCγ1-mediated effect of EGF on cell proliferation. These effects are independent of the catalytical as well as the scaffold activity of PKCε but are a function of the cellular expression level of PKCε. In contrast to FaDu cells where the PLCγ1 pathway was selectively affected, in three other HNSCC cell lines investigated over-expression of PKCε resulted in association with EGFR and, subsequently, in either partial (ERK and Akt or PLCγ1 and Akt) or complete (ERK, PLCγ1 and Akt) inhibition of the main EGFR signalling pathways. Together, our data suggest that in particular carcinoma cells highly expressed PKCε may act as negative allosteric modulator of EGFR signalling. This novel function of PKCε provides also the first indication that the EGFR may be a target for allosteric modulation by accessory proteins.     

Identification of novel NK1/NK3 dual antagonists for the potential treatment of schizophrenia

During the lead optimization of NK(1)/NK(3) receptor antagonists program, a focused exploration of molecules bearing a lactam moiety was performed. The aim of the investigation was to identify the optimal position of the carbonyl and hydroxy methyl group in the lactam moiety, in order to maximize the in vitro affinity and the level of insurmountable antagonism at both NK(1) and NK(3) receptors. The synthesis and biological evaluation of these novel lactam derivatives, with potent and balanced NK(1)/NK(3) activity, were reported in this paper.     

The anti-malarial activity of bivalent imidazolium salts

A series of compounds containing bivalent imidazolium rings and one triazolium analog were synthesized and evaluated for their ability to inhibit the replication of Plasmodium falciparum cultures. The activity and selectivity of the compounds for P. falciparum cultures were found to depend on the presence of electron-deficient rings that were spaced an appropriate distance apart. The activity of the compounds was not critically dependent on the nature of the linker between the electron-deficient rings, an observation that suggests that the rings were responsible for the primary interaction with the molecular target of the compounds in the parasite. The bivalent imidazolium and triazolium compounds disrupted the process whereby merozoites gain entry into erythrocytes, however, they did not appear to prevent merozoites from forming. The compounds were also found to be active in a murine Plasmodium berghei infection, a result consistent with the compounds specifically interacting with a parasite component that is required for replication and is conserved between two Plasmodium species.     

Myosin VI regulates ciliogenesis by promoting the turnover of the centrosomal/satellite protein OFD1

The actin motor protein myosin VI is a multivalent protein with diverse functions. Here, we identified and characterised a myosin VI ubiquitous interactor, the oral‐facial‐digital syndrome 1 (OFD1) protein, whose mutations cause malformations of the face, oral cavity, digits and polycystic kidney disease. We found that myosin VI regulates the localisation of OFD1 at the centrioles and, as a consequence, the recruitment of the distal appendage protein Cep164. Myosin VI depletion in non‐tumoural cell lines causes an aberrant localisation of OFD1 along the centriolar walls, which is due to a reduction in the OFD1 mobile fraction. Finally, loss of myosin VI triggers a severe defect in ciliogenesis that could be, at least partially, ascribed to an impairment in the autophagic removal of OFD1 from satellites. Altogether, our results highlight an unprecedent layer of regulation of OFD1 and a pivotal role of myosin VI in coordinating the formation of the distal appendages and primary cilium with important implications for the genetic disorders known as ciliopathies.