Obstructive sleep apneas naturally occur in mice during REM sleep and are more prevalent in a mouse model of Down syndrome

Study Objectives. The use of mouse models in sleep apnea research is limited by the belief that central (CSA) but not obstructive sleep apneas (OSA) occur in rodents. With this study we wanted to develop a protocol to look for the presence of OSAs in wild-type mice and, then, to apply it to a mouse model of Down Syndrome (DS), a human pathology characterized by a high incidence of OSAs. Methods. Nine C57Bl/6J wild-type mice were implanted with electrodes for electroencephalography (EEG), neck electromyography (nEMG), diaphragmatic activity (DIA) and then placed in a whole-body-plethysmographic (WBP) chamber for 8h during the resting (light) phase to simultaneously record sleep and breathing activity. The concomitant analysis of WBP and DIA signals allowed the discrimination between CSA and OSA. The same protocol was then applied to 12 Ts65Dn mice (a validated model of DS) and 14 euploid controls. Results. OSAs represented about half of the apneic events recorded during rapid-eye-movement sleep (REMS) in each experimental group while almost only CSAs were found during non-REMS. Ts65Dn mice had similar rate of apneic events than euploid controls but a significantly higher occurrence of OSAs during REMS. Conclusions. We demonstrated for the first time that mice physiologically exhibit both CSAs and OSAs and that the latter are more prevalent in the Ts65Dn mouse model of DS. These findings indicate that mice can be used as a valid tool to accelerate the comprehension of the pathophysiology of all kind of sleep apnea and for the development of new therapeutical approaches to contrast these respiratory disorders.

Respiratory chain complex I dysfunction in tumorigenesis

Diseases due to mutations in mitochondrial DNA probably represent the most common form of metabolic disorders, including cancer, as highlighted in the last years. Approximately 300 mtDNA alterations have been identified as the genetic cause of mitochondrial diseases and one-third of these alterations are located in the coding genes for OXPHOS proteins. Despite progress in identification of their molecular mechanisms, little has been done with regard to the therapy. Recently, a particular gene therapy approach, namely allotopic expression, has been proposed and optimized, although the results obtained are rather controversial. In fact, this approach consists in synthesis of a wild-type version of mutated OXPHOS protein in the cytosolic compartment and in its import into mitochondria, but the available evidence is based only on the partial phenotype rescue and not on the demonstration of effective incorporation of the functional protein into respiratory complexes. In the present study, we took advantage of a previously analyzed cell model bearing the m.3571insC mutation in MTND1 gene for the ND1 subunit of respiratory chain complex I. This frame-shift mutation induces in fact translation of a truncated ND1 protein then degraded, causing complex I disassembly, and for this reason not in competition with that allotopically expressed. We show here that allotopic ND1 protein is correctly imported into mitochondria and incorporated in complex I, promoting its proper assembly and rescue of its function. This result allowed us to further confirm what we have previously demonstrated about the role of complex I in tumorigenesis process. Injection of the allotopic clone in nude mice showed indeed that the rescue of complex I assembly and function increases tumor growth, inducing stabilization of HIF1α, the master regulator of tumoral progression, and consequently its downstream gene expression activation.