Klotho genetic variants mediate the association between obstructive sleep apnea and short telomere length.

The core features of obstructive sleep apnea (OSA) can potentially contribute to the acceleration of telomere shortening mechanisms. Other factor associated with telomeres is Klotho gene as it can negatively regulates telomerase activity. Noteworthy, KLOTHO protein level has recently been associated with OSA. In this sense, it was plausible to hypothesize that OSA would be associated with short telomere length and those with OSA plus risk single nucleotide polymorphisms (SNPs) in Klotho gene would present even shorter telomere length. As part of the EPISONO cohort, 1042 individuals answered questionnaires, underwent polysomnography and had blood collected for DNA extraction. OSA was defined according to AHI≥ 15 events/hour. Leukocyte telomere length (LTL) was measured through real-time polymerase chain reaction (qPCR) and Klotho SNPs were genotyped by array. Mediation analyses considered the presence of SNPs in Klotho gene and how this interaction can affect OSA and its consequence in telomere length. All the analyses were corrected for multiple comparisons. LTL was significantly shorter in OSA compared to controls in a severity-dependent manner (B = 0.055; CI = 0.007-0.102; p = 0.02). Among the 43 Klotho SNPs analyzed, we observed that 4 SNPs (rs525014, rs7982726, rs685417 and rs9563124) significantly mediated the association between OSA and short LTL. Klotho gene opens a new venue in OSA research since it can contribute in the increase of knowledge of the mechanisms involved in the consequences of short telomeres in individuals with OSA.

Restriction of rapid eye movement sleep during adolescence increases energy gain and metabolic efficiency in young adult rats.

NEW FINDINGS: What is the central question of this study? Sleep curtailment in infancy and adolescence may lead to long-term risk for obesity, but the mechanisms involved have not yet been determined. This study examined the immediate and long-term metabolic effects produced by sleep restriction in young rats. What is the main finding and its importance? Prolonged sleep restriction reduced weight gain (body fat stores) in young animals. After prolonged recovery, sleep-restricted rats tended to save more energy and to store more fat, possibly owing to increased gross food efficiency. This could be the first step to understand this association. Sleep curtailment is associated with obesity and metabolic changes in adults and children. The aim of the present study was to evaluate the immediate and long-term metabolic alterations produced by sleep restriction in pubertal male rats. Male Wistar rats (28 days old) were allocated to a control (CTL) group or a sleep-restricted (SR) group. This was accomplished by the single platform technique for 18 h per day for 21 days. These groups were subdivided into the following four time points for assessment: sleep restriction and 1, 2 and 4 months of recovery. Body weight and food intake were monitored throughout the experiment. At the end of each time period, blood was collected for metabolic profiling, and the carcasses were processed for measurement of body composition and energy balance. During the period of sleep restriction, SR animals consumed less food in the home cages. This group also displayed lower body weight, body fat, triglycerides and glucose levels than CTL rats. At the end of the first month of recovery, despite eating as much as CTL rats, SR animals showed greater energy and body weight gain, increased gross food efficiency and decreased energy expenditure. At the end of the second and fourth months of recovery, the groups were no longer different, except for energy gain and gross food efficiency, which remained higher in SR animals. In conclusion, sleep restriction affected weight gain of young animals, owing to reduction of fat stores. Two months were sufficient to recover this deficit and to reveal that SR rats tended to save more energy and to store more fat.