Role of circadian clock system in the mitochondrial trans-sulfuration pathway and tissue remodeling.

Previous studies from our laboratory revealed that the gaseous molecule hydrogen sulfide (H2S), a metabolic product of epigenetics, involves trans-sulfuration pathway for ensuring metabolism and clearance of homocysteine (Hcy) from body, thereby mitigating the skeletal muscle's pathological remodeling. Although the master circadian clock regulator that is known as brain and muscle aryl hydrocarbon receptor nuclear translocator like protein 1 (i.e., BMAL 1) is associated with S-adenosylhomocysteine hydrolase (SAHH) and Hcy metabolism but how trans-sulfuration pathway is influenced by the circadian clock remains unexplored. We hypothesize that alterations in the functioning of circadian clock during sleep and wake cycle affect skeletal muscle's biology. To test this hypothesis, we measured serum matrix metalloproteinase (MMP) activities using gelatin gels for analyzing the MMP-2 and MMP-9. Further, employing casein gels, we also studied MMP-13 that is known to be influenced by the growth arrest and DNA damage-45 (GADD45) protein during sleep and wake cycle. The wild type and cystathionine ß synthase-deficient (CBS-/+) mice strains were treated with H2S and subjected to measurement of trans-sulfuration factors from skeletal muscle tissues. The results suggested highly robust activation of MMPs in the wake mice versus sleep mice, which appears somewhat akin to the "1-carbon metabolic dysregulation", which takes place during remodeling of extracellular matrix during muscular dystrophy. Interestingly, the levels of trans-sulfuration factors such as CBS, cystathionine γ lyase (CSE), methyl tetrahydrofolate reductase (MTHFR), phosphatidylethanolamine N-methyltransferase (PEMT), and Hcy-protein bound paraoxonase 1 (PON1) were attenuated in CBS-/+ mice. However, treatment with H2S mitigated the attenuation of the trans-sulfuration pathway. In addition, levels of mitochondrial peroxisome proliferator-activated receptor-gamma coactivator 1-α (PGC 1-α) and mitofusin-2 (MFN-2) were significantly improved by H2S intervention. Our findings suggest participation of the circadian clock in trans-sulfuration pathway that affects skeletal muscle remodeling and mitochondrial regeneration.

Porphyromonas gingivalis induces cardiovascular dysfunction.

Porphyromonas gingivalis (P. gingivalis) is one of the most responsible periodontopathogenic bacteria in the development of periodontal disease (PD); however, its role in the development of other diseases still needs to be understood, specially its implications in the causation of cardiovascular pathogenesis. The aim of this study is to determine whether there is a direct association between P. gingivalis-induced PD with that of the development of cardiovascular disease, and whether a long-term administration of probiotic(s) could help improve the cardiovascular disease outcome. To test this hypothesis, we employed four different experimental groups of mice, designated as: Group I: Wild-type (WT) mice (C57BL/6J); Group II: Lactobacillus rhamnosus GG (LGG) (WT mice treated with a probiotic; LGG), Group III: PD (WT mice treated with P. gingivalis), and Group IV: PD + LGG (WT mice treated with P. gingivalis and LGG). PD was created by injecting 2 µL (i.e., 20 µg) of P. gingivalis lipopolysaccharide (LPS) intragingivally between the 1st and 2nd mandibular molars, two times a week for a total period of 6 weeks. The PD (LGG) intervention was done orally employing 2.5 × 105 CFU/day for a continuous period of 12 weeks. Immediately before the mice were sacrificed, echocardiography of the heart was performed, and after sacrifice, we collected serum samples, hearts, and the periodontal tissue. Histological assessment, cytokine analysis, and zymography of the cardiac tissue were performed. Results revealed inflammation of the heart muscle in the PD group that was marked by infiltration of neutrophils and monocytes, followed by fibrosis. Cytokine analysis of the mice sera revealed significantly elevated levels of tumor necrosis factor-α, IL-1ß, IL-6, and IL-17A in the PD group along with LPS-binding protein, and CD14. Most importantly, we observed elevated levels of P. gingivalis mRNAs in the heart tissues of PD mice. Zymographic analysis demonstrated matrix remodeling as revealed by increasing content of MMP-9 in the heart tissues of PD mice. Interestingly, LGG treatment was able to mitigate most of the pathological effects. The findings suggest that P. gingivalis could lead to cardiovascular system disorder and that probiotic intervention could alleviate, and most likely prevent bacteremia and its harmful effect(s) on the cardiovascular function.

Renal Denervation Helps Preserve the Ejection Fraction by Preserving Endocardial-Endothelial Function during Heart Failure.

Renal denervation (RDN) protects against hypertension, hypertrophy, and heart failure (HF); however, it is not clear whether RDN preserves ejection fraction (EF) during heart failure (HFpEF). To test this hypothesis, we simulated a chronic congestive cardiopulmonary heart failure (CHF) phenotype by creating an aorta-vena cava fistula (AVF) in the C57BL/6J wild type (WT) mice. Briefly, there are four ways to create an experimental CHF: (1) myocardial infarction (MI), which is basically ligating the coronary artery by instrumenting and injuring the heart; (2) trans-aortic constriction (TAC) method, which mimics the systematic hypertension, but again constricts the aorta on top of the heart and, in fact, exposes the heart; (3) acquired CHF condition, promoted by dietary factors, diabetes, salt, diet, etc., but is multifactorial in nature; and finally, (4) the AVF, which remains the only one wherein AVF is created ~1 cm below the kidneys in which the aorta and vena cava share the common middle-wall. By creating the AVF fistula, the red blood contents enter the vena cava without an injury to the cardiac tissue. This model mimics or simulates the CHF phenotype, for example, during aging wherein with advancing age, the preload volume keeps increasing beyond the level that the aging heart can pump out due to the weakened cardiac myocytes. Furthermore, this procedure also involves the right ventricle to lung to left ventricle flow, thus creating an ideal condition for congestion. The heart in AVF transitions from preserved to reduced EF (i.e., HFpEF to HFrEF). In fact, there are more models of volume overload, such as the pacing-induced and mitral valve regurgitation, but these are also injurious models in nature. Our laboratory is one of the first laboratories to create and study the AVF phenotype in the animals. The RDN was created by treating the cleaned bilateral renal artery. After 6 weeks, blood, heart, and renal samples were analyzed for exosome, cardiac regeneration markers, and the renal cortex proteinases. Cardiac function was analyzed by echocardiogram (ECHO) procedure. The fibrosis was analyzed with a trichrome staining method. The results suggested that there was a robust increase in the exosomes' level in AVF blood, suggesting a compensatory systemic response during AVF-CHF. During AVF, there was no change in the cardiac eNOS, Wnt1, or ß-catenin; however, during RDN, there were robust increases in the levels of eNOS, Wnt1, and ß-catenin compared to the sham group. As expected in HFpEF, there was perivascular fibrosis, hypertrophy, and pEF. Interestingly, increased levels of eNOS suggested that despite fibrosis, the NO generation was higher and that it most likely contributed to pEF during HF. The RDN intervention revealed an increase in renal cortical caspase 8 and a decrease in caspase 9. Since caspase 8 is protective and caspase 9 is apoptotic, we suggest that RDN protects against the renal stress and apoptosis. It should be noted that others have demonstrated a role of vascular endothelium in preserving the ejection by cell therapy intervention. In the light of foregoing evidence, our findings also suggest that RDN is cardioprotective during HFpEF via preservation of the eNOS and accompanied endocardial-endothelial function.

Simulation of COVID-19 symptoms in a genetically engineered mouse model: implications for the long haulers.

The ongoing pandemic (also known as coronavirus disease-19; COVID-19) by a constantly emerging viral agent commonly referred as the severe acute respiratory syndrome corona virus 2 or SARS-CoV-2 has revealed unique pathological findings from infected human beings, and the postmortem observations. The list of disease symptoms, and postmortem observations is too long to mention; however, SARS-CoV-2 has brought with it a whole new clinical syndrome in "long haulers" including dyspnea, chest pain, tachycardia, brain fog, exercise intolerance, and extreme fatigue. We opine that further improvement in delivering effective treatment, and preventive strategies would be benefited from validated animal disease models. In this context, we designed a study, and show that a genetically engineered mouse expressing the human angiotensin converting enzyme 2; ACE-2 (the receptor used by SARS-CoV-2 agent to enter host cells) represents an excellent investigative resource in simulating important clinical features of the COVID-19. The ACE-2 mouse model (which is susceptible to SARS-CoV-2) when administered with a recombinant SARS-CoV-2 spike protein (SP) intranasally exhibited a profound cytokine storm capable of altering the physiological parameters including significant changes in cardiac function along with multi-organ damage that was further confirmed via histological findings. More importantly, visceral organs from SP treated mice revealed thrombotic blood clots as seen during postmortem examination. Thus, the ACE-2 engineered mouse appears to be a suitable model for studying intimate viral pathogenesis thus paving the way for identification, and characterization of appropriate prophylactics as well as therapeutics for COVID-19 management.

Hydrogen sulfide mitigates skeletal muscle mitophagy-led tissue remodeling via epigenetic regulation of the gene writer and eraser function.

Ketone bodies (KB) serve as the food for mitochondrial biogenetics. Interestingly, probiotics are known to promote KB formation in the gut (especially those that belong to the Lactobacillus genus). Furthermore, Lactobacillus helps produce folate that lowers the levels of homocysteine (Hcy); a hallmark non-proteinogenic amino acid that defines the importance of epigenetics, and its landscape. In this study, we decided to test whether hydrogen sulfide (H2 S), another Hcy lowering agent regulates the epigenetic gene writer DNA methyltransferase (DNMT), eraser FTO and TET2, and thus mitigates the skeletal muscle remodeling. We treated hyperhomocysteinemic (HHcy, cystathionine beta-synthase heterozygote knockout; CBS+/- ) mice with NaHS (the H2 S donor). The results suggested multi-organ damage by HHcy in the CBS+/- mouse strain compared with WT control mice (CBS+/+ ). H2 S treatment abrogated most of the HHcy-induced damage. The levels of gene writer (DNMT2) and H3K9 (methylation) were higher in the CBS+/- mice, and the H2 S treatment normalized their levels. More importantly, the levels of eraser FTO, TET, and associated GADD45, and MMP-13 were decreased in the CBS+/- mice; however, H2 S treatment mitigated their respective decrease. These events were associated with mitochondrial fission, i.e., an increase in DRP1, and mitophagy. Although the MMP-2 level was lower in CBS+/- compared to WT but H2 S could further lower it in the CBS+/- mice. The MMPs levels were associated with an increase in interstitial fibrosis in the CBS+/- skeletal muscle. Due to fibrosis, the femoral artery blood flow was reduced in the CBS+/- mice, and that was normalized by H2 S. The bone and muscle strengths were found to be decreased in the CBS+/- mice but the H2 S treatment normalized skeletal muscle strength in the CBS+/- mice. Our findings suggest that H2 S mitigates the mitophagy-led skeletal muscle remodeling via epigenetic regulation of the gene writer and eraser function.

COVID-19 Mimics Pulmonary Dysfunction in Muscular Dystrophy as a Post-Acute Syndrome in Patients.

Although progressive wasting and weakness of respiratory muscles are the prominent hallmarks of Duchenne muscular dystrophy (DMD) and long-COVID (also referred as the post-acute sequelae of COVID-19 syndrome); however, the underlying mechanism(s) leading to respiratory failure in both conditions remain unclear. We put together the latest relevant literature to further understand the plausible mechanism(s) behind diaphragm malfunctioning in COVID-19 and DMD conditions. Previously, we have shown the role of matrix metalloproteinase-9 (MMP9) in skeletal muscle fibrosis via a substantial increase in the levels of tumor necrosis factor-α (TNF-α) employing a DMD mouse model that was crossed-bred with MMP9-knockout (MMP9-KO or MMP9-/-) strain. Interestingly, recent observations from clinical studies show a robust increase in neopterin (NPT) levels during COVID-19 which is often observed in patients having DMD. What seems to be common in both (DMD and COVID-19) is the involvement of neopterin (NPT). We know that NPT is generated by activated white blood cells (WBCs) especially the M1 macrophages in response to inducible nitric oxide synthase (iNOS), tetrahydrobiopterin (BH4), and tetrahydrofolate (FH4) pathways, i.e., folate one-carbon metabolism (FOCM) in conjunction with epigenetics underpinning as an immune surveillance protection. Studies from our laboratory, and others researching DMD and the genetically engineered humanized (hACE2) mice that were administered with the spike protein (SP) of SARS-CoV-2 revealed an increase in the levels of NPT, TNF-α, HDAC, IL-1ß, CD147, and MMP9 in the lung tissue of the animals that were subsequently accompanied by fibrosis of the diaphragm depicting a decreased oscillation phenotype. Therefore, it is of interest to understand how regulatory processes such as epigenetics involvement affect DNMT, HDAC, MTHFS, and iNOS that help generate NPT in the long-COVID patients.

Patient perspectives on self-monitoring of blood glucose: perceived recommendations, behaviors and barriers in a clinic sample of adults with type 2 diabetes.

BACKGROUND: Patient-centered perspectives on self-monitoring of blood glucose (SBMG) were assessed in adults with type 2 diabetes using a self-regulation conceptual framework. METHODS: Participants (N = 589; 53 % female) were adults with type 2 diabetes who were recruited during routine appointments at a diabetes outpatient clinic in the Southeastern/lower Midwestern region of the United States. RESULTS: Participant's had varying perceptions regarding provider recommendations for SMBG (responder n = 380). Personal blood glucose testing patterns were also varied and reports frequently omitted (responder n = 296). Respondent's most frequent personal pattern was to test "occasionally, as needed," which did not differ by insulin use status, gender or age. In those not prescribed insulin, HbA1c reflected better control in those testing at least once per week (p = .040) or with a blood glucose goal (p = .018). 30.9 % endorsed at least monthly perceived encounters with SMBG barriers, with higher reports by women (p = .005) and younger (p = .006) participants. Poorer glycemic control was observed for participants with more frequently reported scheduling (p = .025, .041) and discouragement (p = .003) barriers. CONCLUSIONS: Findings suggest that many may experience difficulty integrating SMBG into their lives and are unsure of recommendations and appropriate function. Research is needed to promote best practice recommendations for SMBG.

S-adenosylmethionine decreases lipopolysaccharide-induced phosphodiesterase 4B2 and attenuates tumor necrosis factor expression via cAMP/protein kinase A pathway.

S-Adenosylmethionine (SAM) treatment has anti-inflammatory, cytoprotective effects against endotoxin-induced organ injury. An important component of the anti-inflammatory action of SAM involves down-regulation of the lipopolysaccharide (LPS)-induced transcriptional induction of tumor necrosis factor-α (TNF) expression by monocytes/macrophages. We examined the effect of SAM on expression and activity of LPS-induced up-regulation of phosphodiesterase 4 (PDE4), which regulates cellular cAMP levels and TNF expression. LPS treatment of RAW 264.7, a mouse macrophage cell line, led to the induction of Pde4b2 mRNA expression with no effect on Pde4a or Pde4d. SAM pretreatment led to a significant decrease in LPS-induced up-regulation of Pde4b2 expression in both RAW 264.7 cells and primary human CD14(+) monocytes. Of note, the decreased Pde4b2 mRNA expression correlated with the SAM-dependent increase in the transcriptionally repressive histone H3 lysine 9 trimethylation on the Pde4b2 intronic promoter region. The SAM-mediated decrease in LPS-inducible Pde4b2 up-regulation resulted in an increase in cellular cAMP levels and activation of cAMP-dependent protein kinase A (PKA), which plays an inhibitory role in LPS-induced TNF production. In addition, SAM did not affect LPS-inducible inhibitor of nuclear factor-κB degradation or nuclear factor-κB (NF-κB)-p65 translocation into the nucleus but rather inhibited NF-κB transcriptional activity. These results demonstrate for the first time that inhibition of LPS-induced PDE4B2 up-regulation and increased cAMP-dependent PKA activation are significant mechanisms contributing to the anti-TNF effect of SAM. Moreover, these data also suggest that SAM may be used as an effective PDE4B inhibitor in the treatment of chronic inflammatory disorders in which TNF expression plays a significant pathogenic role.

Mechanisms of non-alcoholic steatohepatitis.

In 1980, the term non-alcoholic steatohepatitis was coined to describe a new syndrome occurring in patients who usually were obese (often diabetic) females who had a liver biopsy picture consistent with alcoholic hepatitis, but who denied alcohol use. The causes of this syndrome were unknown, and there was no defined therapy. More than two decades later, this clinical syndrome is only somewhat better understood, and still there is no Food and Drug Administration-approved or even generally accepted drug therapy. Patients with primary non-alcoholic steatohepatitis typically have the insulin resistance syndrome (synonymous with the metabolic syndrome, syndrome X, and so forth), which is characterized by obesity, diabetes, hyperlipidemia, hypertension, and, in some instances, other metabolic abnormalities such as polycystic ovary disease. Secondary non-alcoholic steatohepatitis may be caused by drugs such as tamoxifen, certain industrial toxins, rapid weight loss, and so forth. The cause of non-alcoholic steatohepatitis remains elusive, but most investigators agree that a baseline of steatosis requires a second hit capable of inducing inflammation, fibrosis, or necrosis for non-alcoholic steatohepatitis to develop. Our research group has focused its efforts on the interactions of nutritional abnormalities, cytokines, oxidative stress with lipid peroxidation, and mitochondrial dysfunction in the induction of steatohepatitis, both alcoholic and non-alcoholic in origin. Research findings from other laboratories also support the role of increased cytokine activity, oxidative stress, and mitochondrial dysfunction in the pathogenesis of non-alcoholic steatohepatitis. The objectives of this article are to review the (1) definition and clinical features of non-alcoholic steatohepatitis, (2) potential mechanisms of non-alcoholic steatohepatitis, and (3) potential therapeutic interventions in non-alcoholic steatohepatitis.

A case of gonadal dysgenesis, breast development, Graves' disease, and low bone mass.

OBJECTIVE: To describe a case of XY gonadal dysgenesis with Tanner stage 4 breast development in the absence of a hormone-producing gonadal neoplasm and with Graves' disease and low bone mass. METHODS: The clinical features, laboratory results, and cytogenetic findings in the patient are presented, and the potential mechanisms of breast development are discussed. A MEDLINE search was performed, and related articles in the English-language literature published between 1955 and 2001 were reviewed. RESULTS: A 23-year-old African American woman was referred to the University of Louisville Hospital for evaluation of hyperthyroidism. About 4 months before this referral, hyperthyroidism was diagnosed, and treatment with methimazole was initiated. She continued to have thyrotoxicosis. Additionally, systemic review disclosed a history of primary amenorrhea. Physical examination revealed a tall phenotypic female patient with Tanner stage 4 breast development. Pelvic examination showed normal findings except for sparse pubic hair. Laboratory evaluation confirmed the diagnosis of Graves' disease as well as primary gonadal failure. Pelvic ultrasonography revealed a small uterus and bilateral adnexal masses (0.9 by 0.6 cm). On chromosomal analysis, a 46,XY karyotype was found. Further analysis of Y-DNA by polymerase chain reaction confirmed the presence of an intact Y chromosome, and no microdeletions were identified. Dual-energy x-ray absorptiometry demonstrated a Z-score of -4.7 and -4.2 at the lumbar spine and right hip, respectively. Graves' disease was successfully treated with (131)I. Laparoscopy was performed to resect streak gonads. On histologic examination, no typical ovarian, testicular, or neoplastic tissue was identified. The breast development in this patient remains unexplained. CONCLUSION: To the best of our knowledge, this is the first case report of a tall XY female patient with breast development in the absence of a hormone-producing gonadal neoplasm and without clearly identifiable gonads. Breast development was most likely related to estrogens, possibly produced by either streak gonads at the time of puberty or peripheral conversion of androgens, or to increased sensitivity of breast tissue to estrogens. Graves' disease is likely coincidental and could contribute to bone loss in such subjects.

Minimal change nephropathy and graves' disease: report of a case and review of the literature.

OBJECTIVE: To describe a possible association between Graves' disease and nephrotic syndrome attributable to minimal change nephropathy and to review the literature related to renal diseases in patients with Graves' disease. METHODS: The clinical, laboratory, and renal biopsy findings in a patient with Graves' disease and minimal change nephropathy are discussed. In addition, the pertinent English-language literature published from 1966 to 2001, determined by means of a MEDLINE search, is reviewed. RESULTS: A 29-year-old woman underwent assessment by her primary-care physician because of palpitations, sweating, and a 4.5-kg weight loss. Physical examination revealed a diffuse goiter and tremors of the extremities but no ophthalmologic signs. Laboratory tests confirmed a diagnosis of thyrotoxicosis. Treatment was initiated with propylthiouracil and propranolol. Four weeks later, she presented to the University of Louisville Hospital with increasing swelling of her legs and periorbital puffiness. Examination revealed generalized edema, ascites, and pleural effusion. She continued to have features of thyrotoxicosis. Laboratory tests showed undetectable thyroid-stimulating hormone (<0.03 mIU/mL) and homogeneously increased 123I thyroid uptake and scan. A 24-hour urine collection revealed urinary protein excretion of 6.75 g. Antinuclear antibodies, serum complement levels, hepatitis, and human immunodeficiency virus (HIV) screen were normal. A kidney biopsy specimen revealed features consistent with minimal change disease on light, immunofluorescence, and electron microscopy. The patient had an excellent clinical and laboratory response to treatment with radioactive iodine and corticosteroids, and she was asymptomatic at 6-month follow-up. CONCLUSION: To the best of our knowledge, this is the first report of the concomitant occurrence of Graves' disease and minimal change disease in the absence of any other immunologic disorder known to be associated with minimal change nephropathy.