Brain lactate concentration is higher during wakefulness than in sleep. However, it is unknown why arousal is linked to an increase in brain lactate and why lactate declines within minutes of sleep. Here, we show that the glymphatic system is responsible for state-dependent changes in brain lactate concentration. Suppression of glymphatic function via acetazolamide treatment, cisterna magna puncture, aquaporin 4 deletion, or changes in body position reduced the decline in brain lactate normally observed when awake mice transition into sleep or anesthesia. Concurrently, the same manipulations diminished accumulation of lactate in cervical, but not in inguinal lymph nodes when mice were anesthetized. Thus, our study suggests that brain lactate is an excellent biomarker of the sleep-wake cycle and increases further during sleep deprivation, because brain lactate is inversely correlated with glymphatic-lymphatic clearance. This analysis provides fundamental new insight into brain energy metabolism by demonstrating that glucose that is not fully oxidized can be exported as lactate via glymphatic-lymphatic fluid transport.
Chromogranin A knockout (Chga-KO) mice exhibit enhanced insulin sensitivity despite obesity. Here, we probed the role of the chromogranin A-derived peptide pancreastatin (PST: CHGA ) by investigating the effect of diet-induced obesity (DIO) on insulin sensitivity of these mice. We found that on a high-fat diet (HFD), Chga-KO mice (KO-DIO) remain more insulin sensitive than wild-type DIO (WT-DIO) mice. Concomitant with this phenotype is enhanced Akt and AMPK signaling in muscle and white adipose tissue (WAT) as well as increased FoxO1 phosphorylation and expression of mature Srebp-1c in liver and downregulation of the hepatic gluconeogenic genes, Pepck and G6pase. KO-DIO mice also exhibited downregulation of cytokines and proinflammatory genes and upregulation of anti-inflammatory genes in WAT, and peritoneal macrophages from KO mice displayed similarly reduced proinflammatory gene expression. The insulin-sensitive, anti-inflammatory phenotype of KO-DIO mice is masked by supplementing PST. Conversely, a PST variant peptide PSTv1 (PST-ND3: CHGA 276-301 ), lacking PST activity, simulated the KO phenotype by sensitizing WT-DIO mice to insulin. In summary, the reduced inflammation due to PST deficiency prevented the development of insulin resistance in KO-DIO mice. Thus, obesity manifests insulin resistance only in the presence of PST, and in its absence obesity is dissociated from insulin resistance.The chromogranin A (human CHGA/mouse Chga) proprotein (1-4) undergoes proteolysis and gives rise to bioactive peptides including the antihypertensive catestatin (CHGA 352-372 ) (5-8) and the diabetogenic pancreastatin (PST: CHGA 250-301 ) (9-12). We have shown that Chgadeficient mice (Chga-KO) are obese, hyperadrenergic, and hypertensive. They display elevated levels of circulating leptin and catecholamines but lower levels of interleukin (IL)-6 and Mcp-1 (11,13-16). Despite these abnormalities, Chga-KO mice exhibit enhanced insulin sensitivity (11), a phenotype masked by supplementing PST. PST regulates hepatic insulin signaling through conventional (c) PKC and Srebp-1c (11). Increased plasma PST levels in diabetic populations correlate with insulin resistance (10). Similarly, increased circulating levels of PST in diet-induced obesity (DIO) and db/ db mice are associated with insulin resistance. Despite high levels of plasma leptin and catecholamines, Chga-KO mice are obese owing to peripheral leptin and catecholamine resistance (17).Since normal chow diet (NCD)-fed Chga-KO mice displayed increased insulin sensitivity (11), we hypothesized that Chga-KO mice may be able to maintain insulin sensitivity when exposed to the dysglycemic stress of a highfat diet (HFD). The hallmarks of insulin resistance in DIO mice are obesity, hyperinsulinemia, and increased inflammation (18)(19)(20)(21)(22). Suppression of inflammation in DIO mice can improve insulin sensitivity (23-25). For example, rosiglitazone can improve inflammation and insulin sensitivity in DIO mice without reducing obesity significantly (23-25). Chga-KO mice are...
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