Nestin (+) stem cells independently contribute to neural remodelling of the ischemic heart

Recent studies have revealed the existence of multipotent nestin-immunoreactive cells in the adult mammalian heart. These cells were recruited to infarct site following ischemic injury and differentiated to a vascular lineage leading to de novo blood vessel formation. Here, we show that a sub-population of cardiac resident nestin((+)) cells can further differentiate to a neuronal-like fate in vivo following myocardial infarction. In the ischemically damaged rat heart, neurofilament-M((+)) fibres were detected innervating the peri-infarct/infarct region and the preponderance of these fibres were physically associated with processes emanating from nestin((+)) cells. One week after isogenic heterotopic cardiac transplantation, the beating transplanted rat heart was devoid of neurofilament-M((+)) fibre staining. The superimposition of an ischemic insult to the transplanted heart led to the de novo synthesis of neurofilament-M((+)) fibres by cardiac resident nestin((+)) cells. Nerve growth factor infusion and the exposure of normal rats to intermittent hypoxia significantly increased the density of neurofilament-M((+)) fibres in the heart. However, these newly formed neurofilament-M((+)) fibres were not physically associated with nestin((+)) processes. These data highlight a novel paradigm of reparative fibrosis as a subpopulation of cardiac resident nestin((+)) cells directly contributed to neural remodelling of the peri-infarct/infarct region of the ischemically damaged rat heart via the de novo synthesis of neurofilament-M fibres.     

Sleep Deprivation Reveals Altered Brain Perfusion Patterns in Somnambulism

Background

Despite its high prevalence, relatively little is known about the pathophysiology of somnambulism. Increasing evidence indicates that somnambulism is associated with functional abnormalities during wakefulness and that sleep deprivation constitutes an important drive that facilitates sleepwalking in predisposed patients. Here, we studied the neural mechanisms associated with somnambulism using Single Photon Emission Computed Tomography (SPECT) with ^99mTc-Ethylene Cysteinate Dimer (ECD), during wakefulness and after sleep deprivation.

Methods

Ten adult sleepwalkers and twelve controls with normal sleep were scanned using ^99mTc-ECD SPECT in morning wakefulness after a full night of sleep. Eight of the sleepwalkers and nine of the controls were also scanned during wakefulness after a night of total sleep deprivation. Between-group comparisons of regional cerebral blood flow (rCBF) were performed to characterize brain activity patterns during wakefulness in sleepwalkers.

Results

During wakefulness following a night of total sleep deprivation, rCBF was decreased bilaterally in the inferior temporal gyrus in sleepwalkers compared to controls.

Conclusions

Functional neural abnormalities can be observed during wakefulness in somnambulism, particularly after sleep deprivation and in the inferior temporal cortex. Sleep deprivation thus not only facilitates the occurrence of sleepwalking episodes, but also uncovers patterns of neural dysfunction that characterize sleepwalkers during wakefulness.     

How does the Bax-α1 targeting sequence interact with mitochondrial membranes? The role of cardiolipin

A key event in programmed cell death is the translocation of the apoptotic Bax protein from the cytosol towards mitochondria. The first helix localized at the N-terminus of Bax (Bax-α1) can act here as an addressing sequence, which directs activated Bax towards the mitochondrial surface. Solid state NMR (nuclear magnetic resonance), CD (circular dichroism) and ATR (attenuated total reflection) spectroscopy were used to elucidate this recognition process of a mitochondrial membrane system by Bax-α1. Two potential target membranes were studied, with the outer mitochondrial membrane (OM) mimicked by neutral phospholipids, while mitochondrial contact sites (CS) contained additional anionic cardiolipin. ¹H and ³¹P magic angle spinning (MAS) NMR revealed Bax-α1 induced pronounced perturbations in the lipid headgroup region only in presence of cardiolipin. Bax-α1 could not insert into CS membranes but at elevated concentrations it inserted into the hydrophobic core of cardiolipin-free OM vesicles, thereby adopting β-sheet-like features, as confirmed by ATR. CD studies revealed, that the cardiolipin mediated electrostatic locking of Bax-α1 at the CS membrane surface promotes conformational changes into an α-helical state; a process which seems to be necessary to induce further conformational transition events in activated Bax which finally causes irreversible membrane permeabilization during the mitochondrial apoptosis.     

Characterization of the expression and regulation of MK5 in the murine ventricular myocardium

MK5, a member of the MAPK-activated protein kinase family, is highly expressed in the heart. Whereas MK2 and MK3 are activated by p38 MAPK, MK5 has also been shown to be activated by ERK3 and ERK4. We studied the regulation of MK5 in mouse heart. mRNA for 5 splice variants (MK5.1–5.5), including the original form (MK5.1), was detected. MK5 comprises 14 exons: exon 12 splicing was modified in MK5.2, MK5.3, and MK5.5. MK5.2 and MK5.5 lacked 6 bases at the 3′-end of exon 12, whereas MK5.3 lacked exon 12, resulting in a frame shift and premature termination of translation at codon 3 of exon 13. MK5.4 and MK5.5 lacked exons 2–6, encoding kinase subdomains I–VI, and were kinase-dead. All 5 MK5 variants were detected at the mRNA level in all mouse tissues examined; however, their relative abundance was tissue-specific. Furthermore, the relative abundance of variant mRNA was altered both during hypertrophy and postnatal cardiac development, suggesting that the generation or the stability of MK5 variant mRNAs is subject to regulation. When expressed in HEK293 cells, MK5.1, MK5.2 and MK5.3 were nuclear whereas MK5.4 and MK5.5 were cytoplasmic. A p38 MAPK activator, anisomycin, induced the redistribution of each variant. In contrast, MK5 co-immunoprecipitated ERK3, but not ERK4 or p38α, in control and hypertrophying hearts. GST pull-down assays revealed unbound ERK4 and p38α but no free MK5 or ERK3 in heart lysates. Hence, 1) in heart MK5 complexes with ERK3 and 2) MK5 splice variants may mediate distinct effects thus increasing the functional diversity of ERK3–MK5 signaling.     

How is protein aggregation in amyloidogenic diseases modulated by biological membranes?

The fate of proteins with amyloidogenic properties depends critically on their immediate biochemical environment. However, the role of biological interfaces such as membrane surfaces, as promoters of pathological aggregation of amyloidogenic proteins, is rarely studied and only established for the amyloid-β protein (Aβ) involved in Alzheimer’s disease, and α-synuclein in Parkinsonism. The occurrence of binding and misfolding of these proteins on membrane surfaces, is poorly understood, not at least due to the two-dimensional character of this event. Clearly, the nature of the folding pathway for Aβ protein adsorbed upon two-dimensional aggregation templates, must be fundamentally different from the three-dimensional situation in solution. Here, we summarize the current research and focus on the function of membrane interfaces as aggregation templates for amyloidogenic proteins (and even prionic ones). One major aspect will be the relationship between membrane properties and protein association and the consequences for amyloidogenic products. The other focus will be on a general understanding of protein folding pathways on two-dimensional templates on a molecular level. Finally, we will demonstrate the potential importance of membrane-mediated aggregation for non-amphiphatic soluble amyloidogenic proteins, by using the SOD1 protein involved in the amyotrophic lateral sclerosis syndrome. Australian Society for Biophysics Special Issue: Metals and Membranes in Neuroscience.     

Amplification of Adipogenic Commitment by VSTM2A

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Lipid composition regulates the conformation and insertion of the antimicrobial peptide maculatin 1.1

Antimicrobial peptides interact with cell membranes and their selectivity is contingent on the nature of the constituent lipids. Eukaryotic and bacterial membranes are comprised of different proportions of a range of lipid species with different physical properties. Hence, characterisation of antimicrobial peptides with respect to the magnitude of their interactions with model membranes of different lipid types is needed. Maculatin 1.1 is a short antimicrobial peptide secreted from the skin of several Australian tree-frog species. Circular dichroism spectroscopy (CD) was used to explore the interaction of maculatin 1.1 with a wide range of model membrane systems of different head group and acyl chain characteristics. For neutral phosphatidylcholine (PC), unlike anionic phospholipids, the magnitude of the peptide interactions was dependent on the length and degree of saturation of the constituent acyl chains. Oriented circular dichroism (OCD) data indicated that helical structure was likely promoted by peptide insertion into the hydrophobic core of PC bilayers. The addition of cholesterol (30% mol/mol) tended to decrease the membrane interaction of maculatin 1.1. Anionic lipids locked maculatin 1.1 via electrostatic interactions onto the surface of oriented bilayers as seen in OCD spectra. Furthermore, increasing the membrane curvature by reducing the vesicle radii only slightly reduced the proportion of helical structure in all systems by approximately 10%. The peptide-lipid interaction was strongly dependent on both the lipid chain length and head group, which highlights the importance of the lipid composition used to mimic different cell types. This article is part of a Special Issue entitled: Membrane protein structure and function.     

Synthesis and binding properties of cyclopentane analogues of myo-inositol 1,4,5-tris(phosphate)

Cyclopentanic analogues of myo-inositol 1,4,5-tris(phosphate) were synthesised starting from cyclopentadiene. The affinities of the trisphosphorylated derivatives for the Ins(1,4,5)P(3) receptors were equipotent to that of compound 4, showing that the relative orientation of the functional groups, particularly of the hydroxyl, is not of prime importance in this series. The (31)P NMR titration curves show that the tris(phosphate) 5 behaves as the superimposition of an independent phosphate and a vicinal bis(phosphate).