Evaluation of Genetic or Cellular Impairments in Type I IFN Immunity in a Cohort of Young Adults with Critical COVID-19.

Several genetic and immunological risk factors for severe COVID-19 have been identified, with monogenic conditions relating to 13 genes of type I interferon (IFN) immunity proposed to explain 4.8% of critical cases. However, previous cohorts have been clinically heterogeneous and were not subjected to thorough genetic and immunological analyses. We therefore aimed to systematically investigate the prevalence of rare genetic variants causing inborn errors of immunity (IEI) and functionally interrogate the type I IFN pathway in young adults that suffered from critical COVID-19 yet lacked comorbidities. We selected and clinically characterized a cohort of 38 previously healthy individuals under 50 years of age who were treated in intensive care units due to critical COVID-19. Blood samples were collected after convalescence. Two patients had IFN-α autoantibodies. Genome sequencing revealed very rare variants in the type I IFN pathway in 31.6% of the patients, which was similar to controls. Analyses of cryopreserved leukocytes did not indicate any defect in plasmacytoid dendritic cell sensing of TLR7 and TLR9 agonists in patients carrying variants in these pathways. However, lymphocyte STAT phosphorylation and protein upregulation upon IFN-α stimulation revealed three possible cases of impaired type I IFN signaling in carriers of rare variants. Together, our results suggest a strategy of functional screening followed by genome analyses and biochemical validation to uncover undiagnosed causes of critical COVID-19.

Ex Vivo Generation of Donor Antigen-Specific Immunomodulatory Cells: A Comparison Study of Anti-CD80/86 mAbs and CTLA4-lg Costimulatory Blockade.

Adoptive transfer of alloantigen-specific immunomodulatory cells generated ex vivo with anti-CD80/CD86 mAbs (2D10.4/IT2.2) holds promise for operational tolerance after transplantation. However, good manufacturing practice is required to allow widespread clinical application. Belatacept, a clinically approved cytotoxic T-lymphocyte antigen 4-immunoglobulin that also binds CD80/CD86, could be an alternative agent for 2D10.4/IT2.2. With the goal of generating an optimal cell treatment with clinically approved reagents, we evaluated the donor-specific immunomodulatory effects of belatacept- and 2D10.4/IT2.2-generated immunomodulatory cells. Immunomodulatory cells were generated by coculturing responder human peripheral blood mononuclear cells (PBMCs) (50 × 106 cells) with irradiated donor PBMCs (20 × 106 cells) from eight human leukocyte antigen-mismatched responder-donor pairs in the presence of either 2D10.4/IT2.2 (3 µg/106 cells) or belatacept (40 µg/106 cells). After 14 days of coculture, the frequencies of CD4+ T cells, CD8+ T cells, and natural killer cells as well as interferon gamma (IFN-γ) production in the 2D10.4/IT2.2- and belatacept-treated groups were lower than those in the control group. The percentage of CD19+ B cells was higher in the 2D10.4/IT2.2- and belatacept-treated groups than in the control group. The frequency of CD4+CD25+CD127lowFOXP3+ T cells increased from 4.1±1.0% (preculture) to 7.1±2.6% and 7.3±2.6% (day 14) in the 2D10.4/IT2.2- and belatacept-treated groups, respectively (p<0.05). Concurrently, delta-2 FOXP3 mRNA expression increased significantly. Compared with cells derived from the no-antibody treated control group, cells generated from both the 2D10.4/IT2.2- and belatacept-treated groups produced lower IFN-γ and higher interleukin-10 levels in response to donor-antigens, as detected by enzyme-linked immunospot. Most importantly, 2D10.4/IT2.2- and belatacept-generated cells effectively impeded the proliferative responses of freshly isolated responder PBMCs against donor-antigens. Our results indicate that belatacept-generated donor-specific immunomodulatory cells possess comparable phenotypes and immunomodulatory efficacies to those generated with 2D10.4/IT2.2. We suggest that belatacept could be used for ex vivo generation of clinical grade alloantigen-specific immunomodulatory cells for tolerance induction after transplantation.

Prolonged exercise-induced stimulation of skeletal muscle glucose uptake is due to sustained increases in tissue perfusion and fractional glucose extraction.

CONTEXT: The mechanisms behind the positive effects of physical activity on glucose metabolism in skeletal muscle and the time course of the effects need to be more elucidated. OBJECTIVE: The aim was to examine the prolonged effects of an acute bout of one-legged exercise on local skeletal muscle glucose utilization and tissue perfusion. DESIGN AND SETTING: Interstitial glucose concentration, local tissue perfusion, glucose uptake, and effects of insulin infusion were studied 12 h after an acute bout of exercise and without prior exercise. PARTICIPANTS: Ten healthy subjects, five women and five men, participated in the study. INTERVENTION: Microdialysis measurements, (133)Xe clearance, and a 2-h hyperinsulinemic euglycemic clamp were performed on two occasions. MAIN OUTCOME MEASURES: We measured interstitial glucose concentration and tissue perfusion in the quadriceps femoris muscle of both legs. RESULTS: Tissue perfusion (3.3 ± 0.6 ml × 100 g(-1) × min(-1) vs. 1.4 ± 0.2 ml × 100 g(-1) × min(-1); P = 0.007) and basal glucose uptake (2.3 ± 0.5 µmol × 100 g(-1) × min(-1) vs. 0.9 ± 0.2 µmol × 100 g(-1) × min(-1); P = 0.006) were increased in the leg that had exercised compared to the resting leg; the findings in the resting leg were comparable to those in the control experiment without prior exercise. The relative effect of insulin on fractional skeletal muscle glucose uptake was the same in all experimental settings, and insulin did not affect tissue perfusion. CONCLUSIONS: The prolonged stimulatory effect of physical exercise on skeletal muscle glucose uptake was mediated via vascular effects combined with an increase in basal glucose transport independent of enhancement of insulin responses.

Major differences in noradrenaline action on lipolysis and blood flow rates in skeletal muscle and adipose tissue in vivo.

AIMS/HYPOTHESIS: The regulation of skeletal muscle lipolysis is not fully understood. In the present study, the effects of systemic and local noradrenaline administration on lipolysis and blood flow rates in skeletal muscle and adipose tissue were studied in vivo. METHODS: First, circulating noradrenaline levels were raised tenfold by a continuous i.v. infusion (n=12). Glycerol levels (an index of lipolysis) were measured in m. gastrocnemius and in abdominal adipose tissue using microdialysis. Local blood flow was determined with the (133)Xe clearance technique and whole-body lipolysis rates assessed with a stable glycerol isotope technique ([(2)H(5)] glycerol). Second, interstitial glycerol levels in m. gastrocnemius, m. vastus and adipose tissue were measured by microdialysis during local perfusion with noradrenaline (10(-8)-10(-6) mol/l) (n=10). Local blood flow was monitored with the ethanol perfusion technique. RESULTS: With regard to systemic noradrenergic stimulation, no change in fractional release of glycerol (difference between tissue and arterial glycerol) was seen in skeletal muscle. In adipose tissue it transiently increased twofold (p<0.0001), and the rate of appearance of glycerol in plasma showed the same kinetic pattern. Blood flow was reduced by 40% in skeletal muscle (p<0.005) and increased by 50% in adipose tissue (p<0.05). After noradrenaline stimulation in situ, a discrete elevation of skeletal muscle glycerol was registered only at the highest concentration of noradrenaline (10(-6) mol/l) (p<0.05). Adipose tissue glycerol doubled already at the lowest concentration (10(-8) mol/l) (p<0.05). In skeletal muscle a decrease in blood flow was seen at the highest noradrenaline concentrations (p<0.05). CONCLUSIONS/INTERPRETATION: Lipolysis and blood flow rates are regulated differently in adipose tissue and skeletal muscle. Adipose tissue displays a high, but transient (tachyphylaxia) sensitivity to noradrenaline, leading to stimulation of both lipolysis and blood flow rates. In skeletal muscle, physiological concentrations of noradrenaline decrease blood flow but have no stimulatory effect on lipolysis rates.

Impaired in vivo stimulation of lipolysis in adipose tissue by selective beta2-adrenergic agonist in obese adolescent girls.

Studies performed in adults with long-standing obesity suggest a reduced lipolytic sensitivity to catecholamines in subcutaneous abdominal adipose tissue (AT). We used microdialysis to study the in situ lipolytic effects of dobutamine (selective beta1-agonist) and terbutaline (selective beta2-agonist) on glycerol release (lipolytic index) in abdominal subcutaneous AT in 10 obese girls aged 13-17 years, BMI 38 +/- 2.1 kg/m2, and in 7 lean girls aged 11-17 years, BMI 21 +/- 1.1 kg/m2, and compared them with 10 obese women aged 21-39 years, BMI 36 +/- 1.6 kg/m2, and 10 lean women aged 18-42 years, BMI 21 +/- 0.4 kg/m2. Terbutaline at 10(-6) mol/l stimulated glycerol release more efficiently in lean girls than in obese girls (peak response approximately 350 vs. 150% of control, P < 0.01). At the lower concentration of agonist, no significant difference was seen. In women, terbutaline was more effective in lean than in obese women in stimulating glycerol release at both 10(-8) mol/l (peak response lean approximately 175% vs. obese 125% of control) and 10(-6) mol/l (approximately 300 vs. 150% of control, P < 0.05). No significant difference in glycerol release between obese and lean girls or women was detected with selective beta1-stimulation. Our data demonstrate a specific impairment in the capacity of beta2-adrenergic agonists to promote lipolysis in subcutaneous abdominal adipose tissue of obese adolescent girls and women. Thus, decreased mobilization of fat during activation of the adrenergic system might be present early in the development of adolescent obesity.

Highly efficient cell-mediated gene transfer using non-viral vectors and FuGene6: in vitro and in vivo studies.

The present study was undertaken to develop an efficient non-viral gene delivery system for cardiovascular gene therapy. We investigated transfection efficiency and toxic properties of the new transfection reagent, FuGene6, and compared it with two other transfection reagents, Tfx-50 and LipoTaxi. For in vivo experiments, the plasmid was delivered intramuscularly via transplantation of fibroblasts transfected with plasmid and FuGene6. Conditions for efficient gene delivery were initially studied in vitro. Human and rabbit fibroblasts were isolated from skin, cultured and transfected with phVEGF165 or pCMVbeta gal plasmids, coding for vascular endothelial growth factor (VEGF) or beta-galactosidase, respectively. The effect of the DNA amount and the DNA:transfection reagent ratio on plasmid uptake were studied. Of the transfection reagents tested, only FuGene6 provided high-efficiency and dose-dependent plasmid transfer both for cell-localised (beta-galactosidase) and secreted (VEGF) gene products. When analysed with an MTT assay, FuGene6 showed no toxicity at low doses. Optimised conditions were applied for in vivo reporter gene delivery. Rabbits were injected intramuscularly with ex vivo-transfected fibroblasts. As in in vitro studies, ex vivo-transfected fibroblasts showed highly efficient gene expression in vivo. Tissue sections were analysed with macrophage-specific immunostaining. No signs of inflammation were seen in the region of fibroblast injection. This study demonstrates that FuGene6 is a highly efficient transfection reagent that may be useful for in vitro non-viral transfection of primary human and rabbit fibroblasts and for in vivo therapeutic non-viral gene delivery.

beta-Adrenergic regulation of lipolysis and blood flow in human skeletal muscle in vivo.

Little is known about the regulation of catecholamine-stimulated lipolysis in human skeletal muscle. Therefore, beta-adrenergic regulation of lipolysis and blood flow was investigated in healthy subjects in vivo by use of microdialysis of the gastrocnemius muscle. First, during a hypoglycemic, hyperinsulinemic clamp, which induces a lipolytic response in skeletal muscle tissue, the muscle was locally perfused with beta-adrenoceptor blocking agents. Perfusion with nonselective (propranolol) and beta2-selective (ICI-118551) blocking agents counteracted the hypoglycemia-induced lipolysis (P < 0.01), but perfusion with metoprolol (beta1-blocker) did not affect the glycerol response. Second, selective beta-adrenoceptor agonists were perfused in situ into skeletal muscle during resting conditions. beta2-Adrenoceptor stimulation with terbutaline induced a concentration-dependent increase in skeletal muscle glycerol levels and in tissue blood flow, whereas perfusion with beta1- or beta3-adrenoceptor agonists (dobutamine or CGP-12177) did not influence the glycerol concentration or blood flow. In conclusion, in skeletal muscle tissue, only the beta2-subtype is of importance among beta-adrenoceptors for regulation of lipolysis and blood flow. This is in contrast to adipose tissue, where beta1- and beta3-adrenoceptors are also involved.

Various phosphodiesterase subtypes mediate the in vivo antilipolytic effect of insulin on adipose tissue and skeletal muscle in man.

The antilipolytic effect of insulin on human abdominal subcutaneous adipose tissue and skeletal muscle during local inhibition of cAMP-phosphodiesterases (PDEs) was investigated in vivo, by combining microdialysis with a euglycaemic, hyperinsulinaemic clamp. During hyperinsulinaemia, the glycerol concentration decreased by 40% in fat and by 33% in muscle. Addition of the selective PDE3-inhibitor amrinone abolished the insulin-induced decrease in adipose glycerol concentration, but did not influence the glycerol concentration in skeletal muscle. Nor did the PDE4-selective inhibitor rolipram or the PDE5-selective inhibitor dipyridamole influence the insulin-induced decrease in muscle tissue glycerol. However, the non-selective PDE-inhibitor theophylline counteracted the antilipolytic action of insulin at both sites. The specific activity of PDEs was also determined in both tissues. PDE3-activity was 36.8+/-6.4 pmol x min(-1) x mg(-1) in adipose tissue and 3.9+/-0.5 pmol x min(-1) x mg(-1) in muscle. PDE4-activity in skeletal muscle was high, i.e., 60.7+/-10.2 pmol x min(-1) x mg(-1) but 8.5 pmol x min(-1) x mg(-1) or less in adipose tissue. In conclusion, insulin inhibits lipolysis in adipose tissue and skeletal muscle by activation of different PDEs, suggesting a unique metabolic role of muscle lipolysis.

Effect of insulin on glycerol production in obese adolescents.

Impaired stimulation of glucose metabolism and reduced suppression of lipolytic activity have both been suggested as important defects related to the insulin resistance of adolescent obesity. To further explore the relationship between these abnormalities, we studied seven obese [body mass index (BMI) 35 +/- 2 kg/m2] and seven lean (BMI 21 +/- 1 kg/m2) adolescents aged 13-15 yr and compared them with nine lean adults (aged 21-27 yr, BMI 23 +/- 1 kg/m2) during a two-step euglycemic-hyperinsulinemic clamp in combination with 1) a constant [2H5]glycerol (1.2 mg.m-2.min-1) infusion to quantify glycerol turnover and 2) indirect calorimetry to estimate glucose and net lipid oxidation rates. In absolute terms, basal glycerol turnover was increased and suppression by insulin was impaired in obese adolescents compared with both groups of lean subjects (P < 0.01). However, when the rates of glycerol turnover were adjusted for differences in body fat mass, the rates were similar in all three groups. Basal plasma free fatty acid (FFA) concentrations were significantly elevated, and the suppression by physiological increments in plasma insulin was impaired in obese adolescents compared with lean adults (P < 0.05). In parallel with the high circulating FFA levels, net lipid oxidation in the basal state and during the clamp was also elevated in the obese group compared with lean adults. Net lipid oxidation was inversely correlated with glucose oxidation (r = -0.50, P < 0.01). In conclusion, these data suggest that lipolysis is increased in obese adolescents (vs. lean adolescents and adults) as a consequence of an enlarged adipose mass rather than altered sensitivity of adipocytes to the suppressing action of insulin.

Importance of phosphodiesterase 3 for the lipolytic response in adipose tissue during insulin-induced hypoglycemia in normal man.

The present investigation aimed to clarify the role of phosphodiesterase (PDE) type 3 for in vivo lipolysis in human adipose tissue during simultaneous insulin and catecholamine stimulation. Therefore, ten healthy subjects were investigated during insulin-induced hypoglycemia. Microdialysis probes were implanted in the subcutaneous adipose tissue and perfused by solvents with or without addition of the specific PDE 3 antagonist amrinone. Furthermore, changes in the local blood flow surrounding the dialysis probes were assessed by the ethanol escape technique. During the 60 min period before the start of the insulin infusion, adipose tissue glycerol levels (lipolysis index) increased significantly when amrinone was added to the perfusate (p = 0.0006, one-factor ANOVA). The antilipolytic response to the early phase of insulin infusion decreased (delta glycerol 9.0+/-3.5 vs. 29.9+/-6.0 micromol/l, p = 0.04) and the lipolytic response after hypoglycemia increased (AUC 122.4+/-18.0 vs. 13.4+/-16.3 micromol x l(-1) x h, p = 0.0001) comparing the experiments with or without amrinone, respectively. When amrinone was excluded from the perfusate, there was an increase in the nutritive blood flow during hypoglycemia, whereas there were no significant changes in the local blood flow surrounding the probe when amrinone was added to the perfusate. In conclusion, during insulin-induced hypoglycemia, PDE 3 activation clearly counteracts the lipolytic effect of catecholamines. When PDE 3 is specifically blocked, lipolysis increases greatly. Thus, PDE 3 is important for the in vivo regulation of the antilipolytic and lipolytic responses to hormones in human adipose tissue.

Forskolin potentiates isoprenaline-induced glycerol output and local blood flow in human adipose tissue in vivo.

The synergistic action of forskolin on beta-adrenoceptor-mediated glycerol output and changes in local blood flow were investigated in situ, in human adipose tissue of healthy subjects, by the use of microdialysis. The addition of isoprenaline 0.1-1.0 microM or forskolin 10-100 microM to the perfusion solvent caused a concentration-dependent, marked and sustained increase in the levels of glycerol in the dialysate (lipolysis index) as compared to the solvent alone. On a molar basis, isoprenaline was almost one thousand times more potent than forskolin. Isoprenaline caused a rapid and concentration-dependent decrease in the ethanol clearance ratio (index of local blood flow, i.e. a decrease in ethanol ratio implies an increase in blood flow). Forskolin had no effect on the ethanol ratio at either 1.0 microM or 10 microM, while forskolin at 100 microM induced a significant decrease in the ethanol ratio. When adipose tissue was pre-treated with forskolin, the subsequent addition of isoprenaline to the microdialysate resulted in a significantly higher glycerol output and a significantly more prominent decrease in the ethanol ratio than with isoprenaline alone. In conclusion, the data demonstrate that forskolin and the (beta-adrenoceptor-agonist both stimulate lipolysis and local blood flow in human adipose tissue in vivo. Furthermore, forskolin, at concentrations that are ineffective alone, potentiates the actions of isoprenaline on lipolysis and blood flow.

Absolute concentrations of glycerol and lactate in human skeletal muscle, adipose tissue, and blood.

The absolute concentrations of glycerol and lactate were studied with microdialysis of adipose tissue and skeletal muscle in normal-weight subjects. The basal interstitial glycerol concentration was 232 +/- 33, 96 +/- 8, and 59 +/- 6 mumol/l in fat, muscle, and arterialized plasma, respectively (P = 0.0002). This relationship was maintained during both euglycemic hyperinsulinemia, when glycerol decreased in all three compartments, and hypoglycemia, when glycerol first decreased and then increased in fat, muscle, and blood (P = 0.0001 for both). Basal interstitial lactate concentrations were similar in adipose tissue (1.1 +/- 0.2 mmol/l) and skeletal muscle (1.9 +/- 0.4 mmol/l) and higher than in arterialized blood (0.6 +/- 0.1 mmol/l, P = 0.002). During hyperinsulinemia and hypoglycemia, lactate increased (P = 0.0001) and the tissue-blood relationship was maintained (P = 0.04). In conclusion, adipose tissue and skeletal muscle mobilize glycerol and lactate at rest. Glycerol and lactate production are influenced by hyperinsulinemia and hypoglycemia in both tissues. Adipose tissue appears to be the major site of glycerol production, whereas skeletal muscle and fat may be equally important for lactate production.

Influence of local blood flow on glycerol levels in human adipose tissue.

DESIGN: The influence of blood flow on adipose tissue glycerol levels was investigated in human subcutaneous adipose tissue in situ, with the aid of microdialysis of the extracellular water space. The concentration of tissue-derived glycerol and the escape of ethanol from the dialysis solvent into the extracellular space were simultaneously monitored; the latter was used as an index of local blood flow around the probe. RESULTS: Selective vasodilation with nitroprusside or hydralazine rapidly reduced the concentration of glycerol by 50% and at the same time increased the escape of ethanol (P < 0.001). Stimulation of local blood flow and lipolysis with the beta-adrenoceptor agonist isoprenaline caused an increase in ethanol escape (P = 0.01) and a 100% rise in the dialysate glycerol level (P = 0.001). When vasodilation was first induced by nitroprusside, the subsequent addition of isoprenaline to the microdialysate perfusate caused no change in the concentration of glycerol in adipose tissue but a slight increase in ethanol escape. CONCLUSIONS: In conclusion, local blood flow plays an important role in the regulation of the glycerol level in human adipose tissue. Stimulation of blood flow may under certain conditions decrease the level of glycerol in the extracellular space of adipose tissue although the mobilization of glycerol from fat cells to this compartment is increased. Thus, changes in blood flow and glycerol should be considered together when adipose tissue lipolysis is investigated by microdialysis.