Glucans are structurally diverse fungal biopolymers that stimulate innate immunity and are fungal pathogen-associated molecular patterns. Dectin-1 is a C-type lectin-like pattern recognition receptor that binds glucans and induces innate immune responses to fungal pathogens. We examined the effect of glucan structure on recognition and binding by murine recombinant Dectin-1 with a library of natural product and synthetic (133)-/(136)--glucans as well as nonglucan polymers. Dectin-1 is highly specific for glucans with a pure (133)--linked backbone structure. Although Dectin-1 is highly specific for (133)--D-glucans, it does not recognize all glucans equally. Dectin-1 differentially interacted with (133)--D-glucans over a very wide range of binding affinities (2.6 mM-2.2 pM). One of the most striking observations that emerged from this study was the remarkable high-affinity interaction of Dectin-1 with certain glucans (2.2 pM). These data also demonstrated that synthetic glucan ligands interact with Dectin-1 and that binding affinity increased in synthetic glucans containing a single glucose side-chain branch. We also observed differential recognition of glucans derived from saprophytes and pathogens. We found that glucan derived from a saprophytic yeast was recognized with higher affinity than glucan derived from the pathogen Candida albicans. Structural analysis demonstrated that glucan backbone chain length and (136)- side-chain branching strongly influenced Dectin-1 binding affinity. These data demonstrate: 1) the specificity of Dectin-1 for glucans; 2) that Dectin-1 differentiates between glucan ligands based on structural determinants; and 3) that Dectin-1 can recognize and interact with both natural product and synthetic glucan ligands.
Comparative LDH secretion, Ext_data_figure2.ep a, Assessment of Candida induced cell death of PBMCs after 24 hours Extended Data Fig. 2.Extended Data Fig. 3 Relative C. auris induced ROS production and heatsensitivity of the cell wall components responsible for the C. auris induced cytokine production. Ext_data_figure3.ep sa, Neutrophil ROS release after 1-hour stimulation without (RPMI; negative control) or with heat-killed C. albicans, C. auris strains or zymosan (positive control), depicted in relative light units (RLU) either as time-course (left) or as area under the curve (AUC, right), n=9. b, PBMC ROS release after 1-hour stimulation without (RPMI; negative control) or with heat-killed C. albicans, C. auris strains or zymosan (positive control), depicted in RLU either as time-course (left) or as AUC (right), n=6. c, TNF-α, IL-6, IL-1β, and IL-1Ra levels in the supernatant of PBMCs after stimulation without (RPMI; negative control) or with heat-killed C. albicans and C. auris from all five geographical clades for 24 hours, n=8. d, PBMC production of cytokines IFN-γ (n=10; n=7 for C. auris 10051895), IL-10 (n=6), IL-17 (n=6), and IL-22 (n=14; n=6 for C. auris 10051893; n=11 for C. auris 10051895) after stimulation without (RPMI; negative control) or with heat-killed C. albicans and C. auris for 7 days. Graphs represent mean ± SEM, data are pooled from at least two independent experiments. * p < 0.05, ** p < 0.01, *** p < 0.001, **** p = 0.001, a-b Time curves (left panels) were assessed for statistical differences between C. auris strains and C. albicans by a two-way ANOVA, Area Under curve (AUC) means (right panels) were compared using the two-sided Wilcoxon signed rank test, c-d twosided Wilcoxon matched pairs signed-rank test comparing respective C. auris strains with C. albicans as control or reference species. Data used to make this figure can be found in Source Data Extended Data Fig. 3.Extended Data Fig. 4 Transcriptional changes induced by purified cell wall components and their respective exposure on C. albicans and C. auris Ext_data_figure4.ep s . a, Heatmap displaying the Log 2 Fold change (color scale) of the top 50 DEG of C. albicans live, for both Candida species and their cell wall components, β-glucan and mannan, at 4 hour (left panel) and 24 hours (right panel). b, Flow cytometry plot based on forward scatter component (FSC) and side scatter component (SSC), demonstrating C. surface. auris strains are slightly smaller and of higher complexity than C. albicans. c, Flow cytometry-based comparison of cell wall components of C. albicans and C. auris strains. Mean fluorescent intensity (MFI) of thimerosal-fixed Candida cells stained for Fc-Dectin-1, a marker for β-glucan (left), and ConA, a marker for mannans (right). Graphs represent mean ± SEM of the 3 means, each performed with three replicates in three independent measurements, * p < 0.05, Kruskall Wallis test with two-sided Dunn's multiple comparison test was performed comparing the respective C. auris strains with the two C. albicans refere...
Ligation of Dectin-1 by fungal glucans elicits a Th17 response that is necessary for clearing many fungal pathogens. Laminarin is a (1→3, 1→6)-β-glucan that is widely reported to be a Dectin-1 antagonist, however, there are reports that laminarin is also a Dectin-1 agonist. To address this controversy, we assessed the physical properties, structure, purity, Dectin-1 binding, and biological activity of five different laminarin preparations from three different commercial sources. The proton nuclear magnetic resonance analysis indicated that all of the preparations contained laminarin although their molecular mass varied considerably (4400-34,400 Da). Two of the laminarins contained substantial quantities of very low m.w. compounds, some of which were not laminarin. These low m.w. moieties could be significantly reduced by extensive dialysis. All of the laminarin preparations were bound by recombinant human Dectin-1 and mouse Dectin-1, but the affinity varied considerably, and binding affinity did not correlate with Dectin-1 agonism, antagonism, or potency. In both human and mouse cells, two laminarins were Dectin-1 antagonists and two were Dectin-1 agonists. The remaining laminarin was a Dectin-1 antagonist, but when the low m.w. moieties were removed, it became an agonist. We were able to identify a laminarin that is a Dectin-1 agonist and a laminarin that is Dectin-1 antagonist, both of which are relatively pure preparations. These laminarins may be useful in elucidating the structure and activity relationships of glucan/Dectin-1 interactions. Our data demonstrate that laminarin can be either a Dectin-1 antagonist or agonist, depending on the physicochemical properties, purity, and structure of the laminarin preparation employed.
Lipopolysaccharide (LPS) has been implicated in sepsis-mediated heart failure and chronic cardiac myopathies. We determined that LPS directly and reversibly affects cardiac myocyte function by altering regulation of intracellular Ca2+ concentration ([Ca2+]i) in immortalized cardiomyocytes, HL-1 cells. [Ca2+]i oscillated (<0.4 Hz), displaying slow and transient components. LPS (1 microg/ml), derived either from Escherichia coli or from Salmonella enteritidis, reversibly abolished Ca2+ oscillations and decreased basal [Ca2+]i by 30-40 nM. HL-1 cells expressed Toll-like receptors, i.e., TLR-2 and TLR-4. Thus, we differentiated effects of LPS on [Ca2+]i and Ca2+ oscillations by addition of utlrapure LPS, a TLR-4 ligand. Ultrapure LPS had no effect on basal [Ca2+]i, but it reduced the rate of Ca2+ oscillations. Interestingly, Pam3CSK4, a TLR-2 ligand, affected neither Ca2+ parameter, and the effect of ultrapure LPS and Pam3CSK4 combined was similar to that of utlrapure LPS alone. Thus, unpurified LPS directly inhibits HL-1 calcium metabolism via TLR-4 and non-TLR-4-dependent mechanisms. Since others have shown that endotoxin impairs the hyperpolarization-activated, nonselective cationic pacemaker current (I(f)), which is expressed in HL-1 cells, we utilized whole cell voltage-clamp techniques to demonstrate that LPS (1 microg/ml) reduced I(f) in HL-1 cells. This inhibition was marginal at physiologic membrane potentials and significant at very negative potentials (P < 0.05 at -140, -150, and -160 mV). So, we also evaluated effects of LPS on tail currents of fully activated I(f). LPS reduced the slope conductance of the tail currents from 498 +/- 140 pS/pF to 223 +/- 65 pS/pF (P < 0.05) without affecting reversal potential of -11 mV. Ultrapure LPS had similar effect on I(f), whereas Pam3CSK4 had no effect on I(f). We conclude that LPS inhibits activation of I(f), enhances its deactivation, and impairs regulation of [Ca2+]i in HL-1 cardiomyocytes via TLR-4 and other mechanisms.
9-Phenanthrol and flufenamic acid inhibit calcium oscillations in HL-1 mouse cardiomyocytes
It is well established that intracellular calcium ([Ca2+]i) controls the inotropic state of the myocardium, and evidence mounts that a “Ca2+ clock” controls the chronotropic state of the heart. Recent findings describe a calcium-activated nonselective cation channel (NSCCa) in various cardiac preparations sharing hallmark characteristics of the Transient Receptor Potential Melastatin 4, (TRPM4). TRPM4 is functionally expressed throughout the heart and has been implicated as a NSCCa that mediates membrane depolarization. However, the functional significance of TRPM4 in regards to Ca2+ signaling and its effects on cellular excitability and pacemaker function remains inconclusive. Here, we show by Fura2 Ca-imaging that pharmacological inhibition of TRPM4 in HL-1 mouse cardiac myocytes by 9-phenanthrol (10 μM) and flufenamic acid (10 & 100 μM) decreases Ca2+ oscillations followed by an overall increase in [Ca2+]i. The latter occurs also in HL-1 cells in Ca2+-free solution and after depletion of sarcoplasmic reticulum Ca2+ with thapsigargin (10 μM). These pharmacologic agents also depolarize HL-1 cell mitochondrial membrane potential. Furthermore, by on-cell voltage clamp we show that 9-phenanthrol reversibly inhibits membrane current; by fluorescence immunohistochemistry we demonstrate that HL-1 cells display punctate surface labeling with TRPM4 antibody; and by immunoblotting using this antibody we show these cells express a 130-150 kD protein, as expected for TRPM4. We conclude that 9-phenanthrol inhibits TRPM4 ion channels in HL-1 cells, which in turn decreases Ca2+ oscillations followed by a compensatory increase in [Ca2+]i from an intracellular store other than the sarcoplasmic reticulum. We speculate that the most likely source is the mitochondrion.
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