Timing of food intake has become a critical factor in determining overall cardiometabolic health. We hypothesized that timing of food intake entrains circadian rhythms of blood pressure and renal excretion in mice. Male C57BL/6J mice were fed ad libitum or reverse feeding (RF) where food was available at all times of day or only available during the 12-hour lights-on period, respectively. Mice eating ad libitum had a significantly higher mean arterial pressure (MAP) during lights-off compared to lights-on (113 ± 2 vs 100 ± 2 mmHg, respectively; p < 0.0001); however, RF for 6 days inverted the diurnal rhythm of MAP (99 ± 3 vs 110 ± 3 mmHg, respectively; p < 0.0001). In contrast to MAP, diurnal rhythms of urine volume and sodium excretion remained intact after RF. Male Bmal1 knockout mice (Bmal1KO) underwent the same feeding protocol. As previously reported, Bmal1KO mice did not exhibit a diurnal MAP rhythm during ad libitum feeding (95 ± 1 vs 92 ± 3 mmHg, lights-off vs lights-on; p > 0.05); however, RF induced a diurnal rhythm of MAP (79 ± 3 vs 95 ± 2 mmHg, lights-off vs lights-on phase; p < 0.01). Transgenic PERIOD2::LUCIFERASE knock-in mice were used to assess the rhythm of the clock protein PERIOD2 in ex vivo tissue cultures. The timing of the PER2::LUC rhythm in the renal cortex and suprachiasmatic nucleus was not affected by RF; however, RF induced significant phase shifts in the liver, renal inner medulla and adrenal gland. In conclusion, the timing of food intake controls blood pressure rhythms in mice independent of Bmal1, urine volume or sodium excretion.
Histone deacetylase (HDAC) enzymes regulate transcription through epigenetic modification of chromatin structure, but their specific functions in the kidney remain elusive. We discovered that the human kidney expresses class I HDACs. Kidney medulla-specific inhibition of class I HDACs in the rat during high-salt feeding results in hypertension, polyuria, hypokalemia, and nitric oxide deficiency. Three new inducible murine models were used to determine that HDAC1 and HDAC2 in the kidney epithelium are necessary for maintaining epithelial integrity and maintaining fluid-electrolyte balance during increased dietary sodium intake. Moreover, single-nucleus RNA-sequencing determined that epithelial HDAC1 and HDAC2 are necessary for expression of many sodium or water transporters and channels. In performing a systematic review and meta-analysis of serious adverse events associated with clinical HDAC inhibitor use, we found that HDAC inhibitors increased the odds ratio of experiencing fluid-electrolyte disorders, such as hypokalemia. This study provides insight on the mechanisms of potential serious adverse events with HDAC inhibitors, which may be fatal to critically ill patients. In conclusion, kidney tubular HDACs provide a link between the environment, such as consumption of high-salt diets, and regulation of homeostatic mechanisms to remain in fluid-electrolyte balance.
Exposure to early life stress (ELS) is associated with a greater risk of chronic disease development including depression and cardiovascular disease. Altered gut microbiota has been linked to both depression and cardiovascular disease in mice and humans. Rodent models of early life neglect are used to characterize the mechanistic links between early life stress (ELS) and the risk of disease later in life. However, little is understood about ELS exposure and the gut microbiota in the young mice and the influence of the maternal inheritance of the gut microbiota. We used a mouse model of ELS, maternal separation with early weaning (MSEW), and normally-reared mice to determine whether the neonate microbiota is altered, and if so, are the differences attributable to changes in dam microbiota that are then transmitted to their offspring. Individual amplicon sequence variants (ASVs) displayed differential abundance in the microbiota of MSEW compared to normally-reared pups at post-natal day (PD)28. Additionally, ELS exposure reduced the alpha diversity and altered microbial community composition at PD28. The composition, levels of alpha diversity, and abundance of individual ASVs in the microbiota of dams were similar from MSEW or normally-reared cohorts. Thus, the observed shifts in the abundance of individual bacterial ASVs in the neonates and young pups are likely driven by endogenous effects of MSEW in the offspring host and are not due to inherited differences from the dam. This knowledge suggests that exposure to ELS has a direct effect on microbial factors on the risk of chronic disease development.
Exposure to early life stress (ELS) is associated with a greater risk of chronic disease development including depression, cardiovascular disease (CVD), and inflammatory bowel disease (IBD). Changes in the gut microbiota have been linked to IBD and CVD. Rodent models of early life neglect are used to characterize the mechanistic links between ELS exposure and the risk of disease later in life. However, little is understood about ELS exposure and the gut microbiota. We used a mouse model of ELS, maternal separation with early weaning (MSEW) and normally‐reared (NR) mice to determine whether the neonate microbiota is altered, and if so, whether the MSEW protocol induces changes in the dam microbiota that are then transmitted to their offspring. MSEW mice (n = 12) were subjected to maternal separation for 4 h per day on postnatal days (PDs) 2–5, and 8 h per day on PDs 6–16, and were subsequently weaned at PD17. NR mice (n = 13) remained undisturbed with dams until weaning on PD21. All mice were maintained on standard chow (NIH‐31; NSN 8710‐01‐005‐8438) following weaning. Paired‐end Illumina sequencing was conducted on colonic content from PD28 mice and DADA2 was utilized to infer and assign taxonomy to individual amplicon sequence variants (ASVs). The fecal microbiota of dams (n= 5) was also sequenced. Analysis of composition of microbiomes (ANCOM) detected 32 ASVs that had statistically different abundance in MSEW compared to NR mice at PD28. Five of the nine ASVs that increased in MSEW mice were classified as Clostridium senso stricto 1 or Lachnoclostridium, while none the of the 23 ASVs enriched in NR animals belonged to these taxa. Fifty‐seven percent (13 of 23) of the ASVs that had greater abundance in NR animals were classified as Lachnospiracea (other than Lachnoclostrium) or Ruminococcaceae. Compared to NR animals, MSEW PD28 mice had reduced phylogenetic diversity (18.7 ± 0.3 compared to 20.3 ± 0.3 in NR; P = 0.003) and Chao1ASV richness (175 ± 8 compared to 198 ± 8 in NR; P = 0.04). Microbial community composition was also altered at PD28 based permutational analysis of variance of Aitchison distance (F(1,24) = 2.29, P = 0.002). The composition, levels of diversity, and abundance of individual ASVs in the microbiota of dams were no different between MSEW and NR cohorts. Thus, the observed microbiota shifts in the young pups are likely driven by endogenous effects of MSEW in the offspring and independent of maternal inheritance. MSEW mice had lower microbial diversity and a reduction in Lachnospiraceae and Ruminococcaceae, which are important fermenters of short‐chain fatty acids (SCFAs). Nine different SCFAs were measured in plasma of PD28 mice and MSEW animals had reduced butyrate (P = 0.02) compared to NR controls. Butyrate promote colonic homeostasis as well as regulates metabolic health and CVD risk. Studies are on‐going to determine the impact of altered SCFA levels with ELS exposure. This study suggests a direct effect of ELS‐exposure on the gut microbiota, which may impact the risk of chronic disease...
Early life stress (ELS) is associated with cardiovascular disease (CVD) risk in adulthood, but the underlying vascular mechanisms are poorly understood. Increased hemoglobin and heme have recently been implicated to mediate endothelial dysfunction in several vascular diseases. Chronic physiological stress is associated with alterations in the heme pathway that have been well-described in the literature. However, very little is known about the heme pathway with exposure to ELS or chronic psychosocial stress. Utilizing a mouse model of ELS, maternal separation with early weaning (MSEW), we previously reported that MSEW induces endothelial dysfunction via increased superoxide production. We reasoned that heme dysregulation may be one of the culprits induced by MSEW and sustained throughout adulthood; thus, we hypothesized that MSEW induces heme dysfunction. We investigated whether circulating levels of heme, a circulating pro-oxidant mediator, are increased by MSEW and examined the role of the heme metabolic pathway and heme homeostasis in this process.We found that circulating levels of heme are increased in mice exposed to MSEW and that plasma from MSEW mice stimulated higher superoxide production in cultured mouse aortic endothelial cells (MAECs) compared to plasma from normally reared mice. The heme scavenger hemopexin blunted this enhanced superoxide production. Splenic haptoglobin abundance was significantly lower and hemoglobin levels per red blood cell were significantly higher in MSEW versus control mice. These findings lead us to propose that ELS induces increased circulating heme through dysregulation of the haptoglobin-hemoglobin system representing a mechanistic link between ELS
Early life stress (ELS) is an independent risk factor for the development of cardiovascular disease in adulthood in both humans and rodent models. Maternal separation and early weaning (MSEW), a model of ELS, produces mice with an increased risk of cardiovascular dysfunction in adulthood, despite resting blood pressures (BP), heart rates (HR), and body weights comparable to normally reared controls. Autonomic regulation of HR and BP is an important component of the homeostatic response to stress but has not been investigated in MSEW mice. We hypothesized that exposure to MSEW impairs autonomic function at baseline and in response to an acute psychosocial stressor in adult male mice. C57Bl/6J litters were randomly assigned to MSEW or normally reared control conditions. MSEW litters were separated from dams for 4 h on postnatal days (PDs) 2-5, 8 h on PDs 6-16, and weaned at PD 17. Control litters were undisturbed until weaning at PD 21. At 9 weeks old, telemeters were implanted in MSEW (n=16) and control mice (n=12). During cage switch stress (CSS), mice were moved to a soiled, unfamiliar cage for 4 h. HR, systolic BP (SBP), diastolic BP (DBP), and activity (monitored by telemetry) were similar between control and MSEW mice at baseline and during CSS (p>0.05, 2-way ANOVA). Spectral analysis of HR, SBP, and DBP indicated that HR variability (HRV) total power was lower in MSEW mice during the 12 h inactive period compared to controls (18.9±1.1 ms 2 vs. 27.5±3.1 ms 2 ; p=0.0033, 2-way ANOVA) at baseline. HRV low frequency (LF) power was also lower during the 12 h inactive period in MSEW mice (4.2±0.4 ms 2 vs.6.6±0.9 ms 2 ; p=0.009). At baseline, 12 h and 24 h DBP variability LF/high frequency (HF) ratio, normalized LF, and normalized HF power were lower in the MSEW group (p<0.05, all comparisons). During the final 90 minutes of CSS, MSEW mice had lower HRV total, LF, and HF power compared to controls (p<0.05); although HR, SBP, DBP, and activity remained similar between groups. These data suggest that MSEW mice have impaired autonomic control of HR and DBP and lack the ability to robustly respond and recover from an acute stressor. Reduced responsiveness of the autonomic nervous system may contribute to the increased risk of cardiovascular disease development in adult mice exposed to MSEW.
Exposure to early life stress (ELS) is associated with a greater risk of developing cardiovascular disease (CVD) later in life. Using a mouse model of ELS, we have recently showed that 4‐week‐old pre‐pubertal mice exposed to ELS have lower microbial diversity and reduced abundances of Lachnospiraceae and Ruminococcaceae taxa, which are important producers of short‐chain fatty acids (SCFAs). An essential mechanism by which gut microbes influence host physiology is through the production of SCFAs that act as vasoactive mediators, histone deacetylase inhibitors, and immunomodulators. Therefore, we hypothesized that ELS‐induced changes in the gut microbiota would result in reduced circulating SCFAs. To test this hypothesis, we subjected mice to maternal separation (MaSep) in which pups underwent daily separation for 4 h on postnatal days (PDs) 2–5 and 8 h on PDs 6–16 until weaning on PD17. Normally reared (NR) mice remained undisturbed with dams until weaning on PD21. All mice were maintained on standard chow (NIH‐31) following weaning. Plasma was collected at PD28 (n=17 MaSep mice from 7 litters and 13 NR mice from 7 litters) and at PD84 (n=8 MaSep from 3 litters and 11 NR mice from 3 litters) for analysis of lactate and the SCFAs acetate, butyrate, isovalerate, propionate, and succinate by gas chromatography/mass spectrometry. Acetate, succinate, and lactate were not different between MaSep and NR mice at either timepoint. However, ELS exposure resulted in significantly reduced butyrate plasma concentrations at PD28 (14.38 ± 0.50 µM in MaSep mice compared to 18.58 ± 1.87 µM in NR mice; P = 0.02) and PD84 (11.94 ± 0.18 µM in MaSep mice compared to 15.03 ± 0.21 µM in NR mice; P < 0.001). ELS also reduced propionate plasma concentrations at PD28 (35.96 ± 1.47 µM in MaSep mice compared to 43.70 ± 1.44 µM in NR mice; P = 0.001) and PD84 (32.16 ± 0.92 µM in MaSep mice compared to 42.53 ± 1.05 µM in NR mice; P < 0.001). Isovalerate plasma concentration was greater in MaSep mice at PD84 (1.11 ± 0.13 µM) compared to NR mice (0.45 ± 0.11 µM; P = 0.002), while there was no difference in isovalerate between MaSep and NR mice at PD28. These data indicate that exposure to stress in early life can result in sustained reductions in butyrate (~22%) and propionate (~21%) concentrations in circulation. Recent advances have determined that butyrate and propionate are involved in blood pressure regulation and vascular physiology. Much less is known about the branched SCFA isovalerate. Future studies will determine if decreases in circulating butyrate and propionate, or increases in circulating isovalerate, play a role in ELS‐induced increased risk of CVD.
Circadian clock genes are important for vascular homeostasis. Loss of Bmal1 , a clock gene, impairs vascular function and blood pressure rhythm in mice. We previously reported that hepatocyte-specific Bmal1 deletion (HBK) in the liver alters perivascular adipose tissue-mediated vascular function in young adult mice, yet aortic collagen content and wall thickness in 4- to 6- month old HBK mice is similar to control genotype flox mice. To our knowledge, this is some of the first evidence that liver circadian clock disruption distally affects function in another tissue. We hypothesized that Bmal1 deletion in liver leads to vascular disease in older adult mice. Studies were performed in 8- to 11-month old male HBK and flox control mice. Aortic stiffness, measured by pulse wave velocity, was significantly higher in HBK mice compared to flox control mice (Flox: 1.93 ± 0.2 m/s; HBK: 3.3 ± 0.5 m/s; n = 7-8, p = 0.02). Light phase systolic blood pressure (tail-cuff) was similar in both flox control and HBK mice (Flox: 101 ± 1 mm Hg; HBK: 103 ± 2 mm Hg; n = 3-5, p = 0.35). Plasma and aortas were collected at ZT10 for metabolite measurements and histological analysis. Circulating plasminogen activator inhibitor-1 (PAI-1) was not different between genotypes. Picrosirius red (PSR)-stained aortic sections were examined under bright field or polarized light to assess collagen content with Metamorph software analysis. Aortic collagen content was not different between flox control and HBK mice under bright or polarized light (bright light, % area stained positive for PSR, Flox: 28.5 ± 2.4%; HBK: 23.6 ± 3.3%, p = 0.30; polarized, Flox: 16.7 ± 0.8%; HBK: 16.3 ± 1.3%; n = 4-5, p=0.82). TUNEL staining showed increased cellular apoptosis in aortas of HBK mice (Flox: 0.72 ± 0.3%; HBK: 2.73 ± 0.7%; n = 4, p = 0.04). Aortic wall thickness was measured as the difference between the external elastic lamina and the internal elastic lamina with CellSens software. Interestingly, aortic wall thickness was significantly lower in older HBK mice compared to flox control mice (Flox: 70.0 ± 2.3 μm; HBK: 58.8 ±2 .3 μm; n = 4-5, p =0. 01). Thus, liver circadian clock disruption in older adult mice increases aortic stiffness with aortic apoptosis and reduced wall thickness, which may result in cardiovascular disease.
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