Grant et al. report that COVID-19 is distinguished from other causes of pneumonia by cumulative, but not peak, cytokine exposure, which is associated with inflammatory activation of microglia. The cover art is a stylized version of proinflammatory microglia, with the image rotated around a central axis to create a stellate, fractal-like pattern.
A systems analysis was conducted to determine the potential molecular mechanisms underlying differential immunogenicity and protective efficacy results of a clinical trial of the radiation-attenuated whole sporozoite PfSPZ Vaccine in African infants. Innate immune activation and myeloid signatures at pre-vaccination baseline correlated with protection from Pf parasitemia in placebo controls. These same signatures were associated with susceptibility to parasitemia among infants who received the highest and most protective PfSPZ Vaccine dose. Machine learning identified spliceosome, proteosome, and resting dendritic cell signatures as pre-vaccination features predictive of protection after highest-dose PfSPZ vaccination, whereas baseline CSP-specific IgG predicted non-protection. Pre-vaccination innate inflammatory and myeloid signatures were associated with higher sporozoite-specific IgG Ab response but undetectable PfSPZ-specific CD8+ T-cell responses post-vaccination. Consistent with these human data, innate stimulation in vivo conferred protection against infection by sporozoite injection in malaria-naïve mice while diminishing the CD8+ T-cell response to radiation-attenuated sporozoites. These data suggest a dichotomous role of innate stimulation for malaria protection and induction of protective immunity of whole-sporozoite malaria vaccines. The uncoupling of vaccine-induced protective immunity achieved by Abs from more protective CD8+ T cell responses suggest that PfSPZ Vaccine efficacy in malaria-endemic settings may be constrained by opposing antigen presentation pathways.
Leetah Senkpeil, Jyoti Bhardwaj, Morgan R. Little, Prasida Holla, Aditi Upadhye, Elizabeth M. Fusco, Phillip A. Swanson II, Ryan E. Wiegand, Michael D. Macklin, Kevin Bi, Barbara J. Flynn, Ayako Yamamoto, Erik L. Gaskin, D. Noah Sather, Adrian L. Oblak, Edward Simpson, Hongyu Gao, W. Nicholas Haining, Kathleen B. Yates, Xiaowen Liu, Tooba Murshedkar, Thomas L. Richie, B. Kim Lee Sim, Kephas Otieno, Simon Kariuki, Xiaoling Xuei, Yunlong Liu, Rafael B. Polidoro, Stephen L. Hoffman, Martina Oneko, Laura C. Steinhardt, Nathan W. Schmidt, Robert A. Seder, Tuan M. Tran
Fetuses with growth restriction (FGR) have an early activation of hepatic glucose production (HGP), a hallmark of type 2 diabetes (T2D). Here we used fetal hepatic catheterization to directly measure HGP and substrate flux in an FGR sheep model. We hypothesized that FGR fetuses would have increased hepatic lactate and amino acid uptake to support increased HGP. Indeed, FGR compared to normal (CON) fetuses had increased HGP and activation of gluconeogenic genes. Unexpectedly, hepatic pyruvate output was increased while hepatic lactate and gluconeogenic amino acid uptake rates were decreased in FGR fetal liver. Hepatic oxygen consumption and total substrate uptake rates were lower. In FGR liver tissue, metabolite abundance, 13C-metabolite labeling, enzyme activity, and gene expression support decreased pyruvate oxidation and increased lactate production. Isolated hepatocytes from FGR fetuses had greater intrinsic capacity for lactate-fueled glucose production. FGR livers also had lower energy (ATP) and redox state (NADH:NAD+). Thus, reduced hepatic oxidative metabolism may make carbons available for increased HGP but also produces nutrient and energetic stress in FGR fetal liver. Intrinsic programming of these pathways regulating HGP in the FGR fetus may underlie increased HGP and T2D risk postnatally.
Laura D. Brown, Paul J. Rozance, Dong Wang, Evren C. Eroglu, Randall B. Wilkening, Ashley Solmonson, Stephanie R. Wesolowski
Manganese is an essential yet potentially toxic metal. Initially reported in 2012, mutations in SLC30A10 are the first known inherited cause of manganese excess. SLC30A10 is an apical membrane protein that exports manganese from hepatocytes into bile and from enterocytes into the lumen of the gastrointestinal tract. SLC30A10 deficiency results in impaired gastrointestinal manganese excretion, leading to manganese excess, neurologic deficits, liver cirrhosis, polycythemia, and erythropoietin excess. Neurologic and liver disease are attributed to manganese toxicity. Polycythemia is attributed to erythropoietin excess. The goal of this study was to determine the basis of erythropoietin excess in SLC30A10 deficiency. Here we demonstrate that transcription factors hypoxia-inducible factor 1a (Hif1a) and 2a (Hif2a), key mediators of the cellular response to hypoxia, are both upregulated in livers of Slc30a10-deficient mice. Hepatic Hif2a deficiency corrected erythropoietin expression and polycythemia and attenuated aberrant hepatic gene expression in Slc30a10-deficient mice, while hepatic Hif1a deficiency had no discernible impact. Hepatic Hif2a deficiency also attenuated manganese excess, although the underlying cause of this is not clear at this time. Overall, our results indicate that hepatic HIF2 is a key determinant of pathophysiology in SLC30A10 deficiency and expand our understanding of the contribution of HIFs to human disease.
Milankumar Prajapati, Jared Z. Zhang, Lauren Chiu, Grace S. Chong, Courtney J. Mercadante, Heather L. Kowalski, Bradley S. Delaney, Jessica A Anderson, Shuling Guo, Mariam Aghajan, Thomas B. Bartnikas
Chronic kidney disease (CKD) causes an accumulation of uremic metabolites that negatively impact skeletal muscle function. Tryptophan-derived uremic metabolites are agonists of the aryl hydrocarbon receptor (AHR) which has been shown to be activated in the blood of CKD patients. This study investigated the role of the AHR in skeletal muscle pathology of CKD. Compared to control participants with normal kidney function, AHR-dependent gene expression (CYP1A1 and CYP1B1) was significantly upregulated in skeletal muscle of patients with CKD (P=0.032) and the magnitude of AHR activation was inversely correlated with mitochondrial respiration (P<0.001). In mice with CKD, muscle mitochondrial oxidative phosphorylation (OXPHOS) was significantly impaired and strongly correlated with both the serum level of tryptophan-derived uremic metabolites and AHR activation. Muscle-specific deletion of the AHR significantly improved mitochondrial OXPHOS in male mice with the greatest uremic toxicity (CKD+probenecid) and abolished the relationship between uremic metabolites and OXPHOS. The uremic metabolite-AHR-mitochondrial axis in skeletal muscle was further confirmed using muscle-specific AHR knockdown in C57BL6J that harbour a high-affinity AHR allele, as well as ectopic viral expression of constitutively active mutant AHR in mice with normal renal function. Notably, OXPHOS changes in AHRmKO mice were only present when mitochondria were fueled by carbohydrates. Further analyses revealed that AHR activation in mice led to significant increases in Pdk4 expression (P<0.05) and phosphorylation of pyruvate dehydrogenase enzyme (P<0.05). These findings establish a uremic metabolite-AHR-Pdk4 axis in skeletal muscle that governs mitochondrial deficits in carbohydrate oxidation during CKD.
Trace Thome, Nicholas A. Vugman, Lauren E. Stone, Keon Wimberly, Salvatore T. Scali, Terence E. Ryan
BACKGROUND Persistent cough and dyspnea are prominent features of post-acute sequelae of SARS-CoV-2 (also termed ’Long COVID’); however, physiologic measures and clinical features associated with these pulmonary symptoms remain poorly defined. Using longitudinal pulmonary function testing (PFTs) and CT imaging, this study aimed to identify the characteristics and determinants of pulmonary Long COVID. METHODS This single-center retrospective study included 1,097 patients with clinically defined Long COVID characterized by persistent pulmonary symptoms (dyspnea, cough, and chest discomfort) lasting for ≥1 month after resolution of primary COVID infection. RESULTS After exclusion, a total of 929 patients with post-COVID pulmonary symptoms and PFTs were stratified diffusion impairment and restriction as measured by percent predicted diffusion capacity for carbon monoxide (DLCO) and total lung capacity (TLC). Dyspnea was the predominant symptom in the cohort (78%) and had similar prevalence regardless of degree of diffusion impairment or restriction. Longitudinal evaluation revealed diffusion impairment (DLCO ≤80%) and pulmonary restriction (TLC ≤80%) in 51% of the cohort overall (n=479). In multivariable logistic regression analysis (adjusted odds ratio; aOR, 95% confidence interval [CI]), invasive mechanical ventilation during primary infection conferred the greatest increased odds of developing pulmonary Long COVID with diffusion impairment and restriction (aOR=10.9 [4.09-28.6]). Finally, a sub-analysis of CT imaging identified radiographic evidence of fibrosis in this patient population. CONCLUSIONS Longitudinal PFT measurements in patients with prolonged pulmonary symptoms after SARS-CoV-2 infection revealed persistent diffusion impaired restriction as a key feature of pulmonary Long COVID. These results emphasize the importance of incorporating PFTs into routine clinical practice for evaluation of patients with prolonged pulmonary symptoms after resolution of SARS-CoV-2. Subsequent clinical trials should leverage combined symptomatic and quantitative PFT measurements for more targeted enrollment of pulmonary Long COVID patients. FUNDING This work was supported by the National Institute of Allergy and Infectious Diseases (AI156898, K08AI129705), the National Heart, Lung, and Blood Institute (HL153113, OTA21-015E, HL149944), and the COVID-19 Urgent Research Response Fund established by the Hugh Kaul Precision Medicine Network at the University of Alabama at Birmingham.
Michael John Patton, Donald Benson, Sarah W. Robison, Dhaval Raval, Morgan L. Locy, Kinner Patel, Scott Grumley, Emily B. Levitan, Peter Morris, Matthew Might, Amit Gaggar, Nathaniel Erdmann