Sistema nervoso enterico e scrapie sperimentale in ovini di razza sarda con diversa suscettibilità genetica nei confronti della malattia

Sebbene il sistema nervoso enterico (“enteric nervous system”, ENS) svolga un ruolo cruciale nella patogenesi della Scrapie ovina, non esistono tuttavia in letteratura dati sulle popolazioni cellulari progressivamente coinvolte nel corso dell’infezione, né sugli eventuali danni morfo-funzionali da esse subiti. Il presente studio è stato condotto sui plessi mienterici e sottomucosi dell’ileo di 46 pecore di razza Sarda, recanti diversi polimorfismi del gene Prnp (ARQ/ARQ, ARQ/AHQ, ARQ/ARR, ARR/ARR). I suddetti animali, infettati per os all’età di 8 mesi con un ceppo di Scrapie precedentemente caratterizzato nel topo, sono stati sacrificati mediante eutanasia a determinati intervalli di tempo post-infezione (p.i.). E’ stata quindi valutata, tramite immunoistochimica ed immunofluorescenza indiretta su sezioni tissutali e su preparati “wholemount”, l’immunoreattività (IR) nei confronti della PrPSc, del “marker” panneuronale Hu C/D, dell’ossido-nitrico sintetasi (nNOS), della calbindina (CALB) e della proteina fibrillare acida gliale (GFAP). In 8 pecore con genotipo ARQ/ARQ, clinicamente sane e sacrificate a 12-24 mesi p.i., nonché in 5 ovini clinicamente affetti (2 con genotipo ARQ/ARQ, 3 con genotipo ARQ/AHQ), questi ultimi sacrificati rispettivamente a 24, 36 e 40 mesi p.i., le indagini immunoistochimiche hanno consentito di dimostrare la presenza di PrPSc a livello sia dell’encefalo (obex), sia dell’ENS, in particolar modo nei plessi mienterici. In tali distretti il deposito della PrPSc risultava pienamente compatibile con un interessamento delle cellule enterogliali (“enteroglial cells”, EGCs), mentre occasionalmente si notava un contestuale coinvolgimento della componente neuronale ivi residente. In conclusione, i dati della presente indagine consentono di ipotizzare un verosimile coinvolgimento delle EGCs e dei neuroni residenti a livello dei plessi dell’ENS nella patogenesi della Scrapie sperimentale realizzata per os in ovini di razza Sarda.

Intrinsic uncoupling in the ATP synthase of Escherichia coli. Studies on WT and ε-truncated mutants

The H+/ATP ratio in the catalysis of ATP synthase has generally been considered a fixed parameter. However, Melandri and coworkers have recently shown that, in the ATP synthase of the photosynthetic bacterium Rb.capsulatus, this ratio can significantly decrease during ATP hydrolysis when the concentration of either ADP or Pi is maintained at a low level (Turina et al., 2004). The present work has dealt with the ATP synthase of E.coli, looking for evidence of this phenomenon of intrinsic uncoupling in this organism as well. First of all, we have shown that the DCCD-sensitive ATP hydrolysis activity of E.coli internal membranes was strongly inhibited by ADP and Pi, with a half-maximal effect in the submicromolar range for ADP and at 140 µM for Pi. In contrast to this monotonic inhibition, however, the proton pumping activity of the enzyme, as estimated under the same conditions by the fluorescence quenching of the ΔpH-sensitive probe ACMA, showed a clearly biphasic progression, both for Pi, increasing from 0 up to approximately 200 µM, and for ADP, increasing from 0 up to a few µM. We have interpreted these results as indicating that the occupancy of ADP and Pi binding sites shifts the enzyme from a partially uncoupled state to a fully coupled state, and we expect that the ADP- and Pi-modulated intrinsic uncoupling is likely to be a general feature of prokaryotic ATP synthases. Moreover, the biphasicity of the proton pumping data suggested that two Pi binding sites are involved. In order to verify whether the same behaviour could be observed in the isolated enzyme, we have purified the ATP synthase of E.coli and reconstituted it into liposomes. Similarly as observed in the internal membrane preparation, in the isolated and reconstituted enzyme it was possible to observe inhibition of the hydrolytic activity by ADP and Pi (with half-maximal effects at few µM for ADP and at 400 µM for Pi) with a concomitant stimulation of proton pumping. Both the inhibition of ATP hydrolysis and the stimulation of proton pumping as a function of Pi were lost upon ADP removal by an ADP trap. These data have made it possible to conclude that the results obtained in E.coli internal membranes are not due to the artefactual interference of enzymatic activities other than the ones of the ATP synthase. In addition, data obtained with liposomes have allowed a calibration of the ACMA signal by ΔpH transitions of known extent, leading to a quantitative evaluation of the proton pumping data. Finally, we have focused our efforts on searching for a possible structural candidate involved in the phenomenon of intrinsic uncoupling. The ε-subunit of the ATP-synthase is known as an endogenous inhibitor of the hydrolysis activity of the complex and appears to undergo drastic conformational changes between a non-inhibitory form (down-state) and an inhibitory form (up-state)(Rodgers & Wilce, 2000; Gibbons et al., 2000). In addition, the results of Cipriano & Dunn (2006) indicated that the C-terminal domain of this subunit played an important role in the coupling mechanism of the pump, and those of Capaldi et al. (2001), Suzuki et al. (2003) were consistent with the down-state showing a higher hydrolysis-to-synthesis ratio than the up-state. Therefore, we decided to search for modulation of pumping efficiency in a C-terminally truncated ε mutant. A low copy number expression vector has been built, carrying an extra copy of uncC, with the aim of generating an ε-overexpressing E.coli strain in which normal levels of assembly of the mutated ATP-synthase complex would be promoted. We have then compared the ATP hydrolysis and the proton pumping activity in membranes prepared from these ε-overexpressing E.coli strains, which carried either the WT ε subunit or the ε88-stop truncated form. Both strains yielded well energized membranes. Noticeably, they showed a marked difference in the inhibition of hydrolysis by Pi, this effect being largely lost in the truncated mutant. However, pre-incubation of the mutated enzyme with ADP at low nanomolar concentrations (apparent Kd = 0.7nM) restored the hydrolysis inhibition, together with the modulation of intrinsic uncoupling by Pi, indicating that, contrary to wild-type, during membrane preparation the truncated mutant had lost the ADP bound at this high-affinity site, evidently due to a lower affinity (and/or higher release) for ADP of the mutant relative to wild type. Therefore, one of the effects of the C-terminal domain of ε appears to be to modulate the affinity of at least one of the binding sites for ADP. The lack of this domain does not appear so much to influence the modulability of coupling efficiency, but instead the extent of this modulation. At higher preincubated ADP concentrations (apparent Kd = 117nM), the only observed effects were inhibition of both hydrolysis and synthesis, providing a direct proof that two ADP-binding sites on the enzyme are involved in the inhibition of hydrolysis, of which only the one at higher affinity also modulates the coupling efficiency.