Platelet SHARPIN regulates platelet adhesion and inflammatory responses through associations with αIIbβ3 and LUBAC

Platelets form hemostatic plugs to prevent blood loss and they modulate immunity and inflammation in several ways. A key event during hemostasis is activation of integrin αIIbβ3 through direct interactions of the β3 cytoplasmic tail with talin and kindlin-3. Recently, we showed that human platelets express the adapter molecule, SHARPIN, that can associate directly with the αIIb cytoplasmic tail and can separately promote NF-κB pathway activation as a member of the Met-1 linear ubiquitination activation complex (LUBAC). Here we investigated the role of SHARPIN in platelets after crossing Sharpin flox/flox (fl/fl) mice with PF4-Cre or GPIbα-Cre mice to selectively delete SHARPIN in platelets. SHARPIN-null platelets adhered to immobilized fibrinogen through αIIbβ3, and they spread more extensively than littermate control platelets in a manner dependent on feedback stimulation by platelet adenosine diphosphate (ADP) (P < 0.01). SHARPIN-null platelets showed increased colocalization of αIIbβ3 with talin as assessed by super-resolution microscopy and increased binding of soluble fibrinogen in response to sub-maximal concentrations of ADP (P < 0.05). However, mice with SHARPIN-null platelets showed compromised thrombus growth on collagen and slightly prolonged tail bleeding times. Platelets lacking SHARPIN also showed reduced NF-κB activation and linear ubiquitination of protein substrates upon challenge with classical platelet agonists. Furthermore, the loss of platelet SHARPIN resulted in significant reduction in inflammation in murine models of colitis and peritonitis (P < 0.01). Thus, SHARPIN plays differential and context-dependent roles in platelets to regulate important inflammatory and integrin adhesive functions of these anucleate cells.

The Role of the Dopamine D1 Receptor in Cognition

<p>The dopamine D1 receptor (DD1R) has been linked to cognitive functioning in various human and animal studies using diverse methods from pharmacological manipulations to brain imaging. Moreover, suboptimal or supraoptimal functioning of the DD1R has been linked to cognitive dysfunction. However, the previous research on this topic has mainly relied on correlational evidence, or the use of drugs that are not selective to the DD1R. Therefore, the current study investigated whether cognitive dysfunction is due to suboptimal functioning of the DD1R. The DD1R mutant rat (Smits et al., 2006) provides an opportunity to examine the role of the DD1R in cognitive functioning. The performance of the DD1R mutant rats was compared to that of littermate control rats (wildtypes). Across five experiments we found tentative evidence to suggest that the DD1R is necessary for normal cognitive ability. First, the DD1R mutant rats were unable to improve their performance when an egocentric strategy was required in the starmaze, using both positive and negative reinforcement. Second, compared to wildtype rats, the DD1R mutants were impaired in learning an allocentric strategy in the starmaze with positive reinforcement when they had been previously trained in an egocentric task. Third, the mutants were unable to improve when an egocentric strategy was required in the Y-maze. Finally, the DD1R mutant rats took longer than the wildtypes to reverse their learning when a baited arm was switched after two weeks of training with a different arm as the baited arm in the T-maze. Despite some of the limitations of the experiments, these initial findings suggest an impairment in cognition. Ideas for future research and applications are discussed.</p>

The Role of the Dopamine D1 Receptor in Cognition

<p>The dopamine D1 receptor (DD1R) has been linked to cognitive functioning in various human and animal studies using diverse methods from pharmacological manipulations to brain imaging. Moreover, suboptimal or supraoptimal functioning of the DD1R has been linked to cognitive dysfunction. However, the previous research on this topic has mainly relied on correlational evidence, or the use of drugs that are not selective to the DD1R. Therefore, the current study investigated whether cognitive dysfunction is due to suboptimal functioning of the DD1R. The DD1R mutant rat (Smits et al., 2006) provides an opportunity to examine the role of the DD1R in cognitive functioning. The performance of the DD1R mutant rats was compared to that of littermate control rats (wildtypes). Across five experiments we found tentative evidence to suggest that the DD1R is necessary for normal cognitive ability. First, the DD1R mutant rats were unable to improve their performance when an egocentric strategy was required in the starmaze, using both positive and negative reinforcement. Second, compared to wildtype rats, the DD1R mutants were impaired in learning an allocentric strategy in the starmaze with positive reinforcement when they had been previously trained in an egocentric task. Third, the mutants were unable to improve when an egocentric strategy was required in the Y-maze. Finally, the DD1R mutant rats took longer than the wildtypes to reverse their learning when a baited arm was switched after two weeks of training with a different arm as the baited arm in the T-maze. Despite some of the limitations of the experiments, these initial findings suggest an impairment in cognition. Ideas for future research and applications are discussed.</p>

PSX-A-3 Late-Breaking: Analysis of serum chemistry for metabolic function in GnRH-II receptor knockdown and littermate control boars

Pigs are the only livestock species encoding functional proteins for both the second form of gonadotropin-releasing hormone (GnRH-II) and its receptor (GnRHR-II), which are uniquely expressed in reproductive and non-reproductive tissues. To examine the physiological role of the GnRH-II/GnRHR-II system, we produced a swine line with reduced endogenous levels of GnRHR-II (GnRHR-II KD); males exhibit 70% diminished testicular GnRHR-II mRNA levels and 82% reduced circulating testosterone concentrations. Given that testosterone impacts metabolism, blood was collected from GnRHR-II KD (n = 5) and littermate control (n = 5) boars via indwelling jugular catheters, with serum isolated and subjected to veterinary diagnostic panels for metabolic analyte examination (PhysLab, Lincoln, NE). Statistical analyses utilized the MIXED procedure of SAS; the model included line as fixed and litter as random effects. Creatine kinase and blood urea nitrogen (BUN):creatinine ratios were elevated, creatinine was reduced (P &lt; 0.01), and thyroxine tended to be decreased (P &lt; 0.10) in GnRHR-II KD compared with control boars. Glucose, BUN, amylase, and lipase levels were not different. Liver products differed in transgenic versus control boars; levels of lactic dehydrogenase, aspartate and alanine aminotransferases (AST; ALT), and gamma-glutamyl transpeptidase were higher, whereas AST:ALT ratios, total protein, albumin, and globulin levels were lower (P &lt; 0.05) in GnRHR-II KD boars. Albumin:globulin ratios and bilirubin (total and direct) did not differ. Additionally, serum cholesterol was decreased (P &lt; 0.05), non-high density lipoproteins (HDLs) and low density lipoproteins (LDLs) tended to be decreased (P &lt; 0.10), and triglycerides, HDLs, and cholesterol:HDL ratios did not differ between GnRHR-II KD and control males. These data suggest metabolic disruption in GnRHR-II KD boars, which may be due to suppressed gonadal steroidogenesis or ubiquitous knockdown of GnRHR-II expression. Supported by USDA/NIFA AFRI (2017-67015-26508) and Hatch Multistate (NEB-26–244) funds. USDA is an equal opportunity provider and employer.

Differences in extent of mechano-induced QT-changes in SQTS, WT and LQTS rabbit models

Background Electro-mechanical (EMC) and mechano-electrical coupling (MEC) are essential for normal cardiac function. Alterations in these can result in increased arrhythmia formation. In “electrical” cardiac diseases, long-QT and short-QT syndrome, regional mechanical function is altered via EMC. Purpose In this study, we aimed to investigate how acute changes in mechanics may impact on electrical function (MEC) in these diseases. Methods To determine how acute changes in preload impact on QT duration, adult rabbits of both sexes were given a 6ml/kg BW bolus of 0.9% NaCl IV and 12-lead-ECGs were assessed first in wildtype (WT) and acquired drug-induced (E4031 to block IKr) LQT2 (“aLQT2”) rabbits, and in a second step in transgenic short-QT type 1 (“SQT1”, KCNH2-N588K) and WT littermate control rabbits (“WT-LMC”). Results At baseline, aLQT2 rabbits demonstrated a markedly prolonged heart-rate corrected QTc duration compared to WT (p&lt;0.0001; n=13), with increased QT-dispersion (QTMax-Min [ms], WT 21.4±5.7 vs. aLQT2 25.8±5.8; p=0.003; n=13) and increased short-term variability of QT (STVQT [ms], WT 3.5±1.0 vs. aLQT2 5.3±1.7; p=0.02; n=13), markers for regional and temporal heterogeneity of repolarization, respectively. SQT1 rabbits (n=8) demonstrated a shorter QTc duration compared to WT-LMC (n=10; p=0.04), with no differences in QT-dispersion and STVQT between the two groups. Increased preload acutely prolonged QT and heart-rate corrected QTc in all groups (despite a slight increase in heart-rate by an average of 25 beats/min): in WT [ms] 171.6±11.6 to 213.3±20.3 (p&lt;0.0001) vs. aLQT2 208.9±19.6 to 271.0±37.5 (p&lt;0.0001; n=13 each), and in WT-LMC 171.3±4.8 to 199.2±5.4 (p&lt;0.0001; n=10) vs. SQT1 156.0±4.7 to 177.3±3.5 (p=0.0004; n=8). Importantly, the extent of mechano-induced electrical changes differed among genotypes, with less pronounced QTc prolongation in SQT1 compared to WT-LMC (delta QTc [ms], SQT1 21.2±3.4 (n=8) vs. WT-LMC 27.9±2.8 (n=10; p=0.15)), and a more pronounced QTc prolongation in aLQT2 compared to WT (delta QTc [ms], WT 41.6±14.9 vs. aLQT2 62.1±32.1; p=0.006; n=13 each). Moreover, QT-dispersion was increased significantly upon global mechanical change only in aLQTS (QTMax-Min [ms], 25.8±5.5 to 32.7±12.3; p=0.03; n=13). Conclusion Acute changes in mechanical function result in electrical changes via MEC in SQT1, WT and aLQT2 rabbits. The extent of these changes, however, depends on the underlying QTc duration, with the least pronounced QTc prolongation in SQT1 rabbits, with the shortest QTc, and the most pronounced QTc prolongation in aLQT2 rabbits, with the longest QTc. The most pronounced MEC effects on global QT duration as well as on regional QT dispersion in aLQT2 indicate that acute MEC effects may play an additional role in LQTS-related arrhythmogenesis. FUNDunding Acknowledgement Type of funding sources: Foundation. Main funding source(s): German Research Foundation (DFG) andSwiss National Science Foundation (SNF)

Abstract P409: GSK-3β Deficiency In Cardiomyocyte Induces Cardiac Progenitor Cell Proliferation In The Ischemic Heart

The cardiomyocytes are terminally differentiated cells and ischemia-induced cardiomyopathy is an irreparable loss. Novel strategies are needed to induce resident cardiac progenitor cells (CPCs) proliferation in situ to enhance the possibility of cardiac regeneration. Here we sought to identify a potential role for glycogen synthase kinase-3β (GSK-3β), a critical regulator of cell proliferation and differentiation, in CPCs proliferation in the ischemic heart. Cardiomyocyte-specific conditional GSK-3β knockout (cKO) and littermate control mice were recruited and challenged with myocardial infarction (MI). The cardiac function was assessed using trans-thoracic M-mode echocardiography. The level of CPC proliferation in the ischemic cKO hearts was determined at 2, 4 and 8 weeks post-MI through immunofluorescence labeling of stem cell marker c-Kit. To confirm the lineage of identified c-Kit -positive cells (KPCs) in the heart, a hematopoietic lineage marker was stained along with c-Kit. The cardiac left ventricular chamber dimension (LVID) and contractile functions were comparable until 2 weeks post-MI. The cKO mice displayed significantly preserved LV chamber [LVIDd(mm); 5.01±0.67 vs.6.09±0.65, p =0.01] and contractile function [LVEF(%); 31.98±8.52 vs. 18.06±7.11., p =0.01] in comparison to control mice at 4 week post-MI. Consistent with protective phenotypes, an increased percentage of KPC was observed in the cKO hearts at 4 and 6-weeks post-MI which was accompanied by an increased level of cardiomyocyte proliferation. Further analysis revealed that the observed increased number of KPCs in the ischemic cKO hearts were mostly from a cardiac lineage as the majority of identified KPCs were negative for the hematopoietic marker, CD45. In conclusion, our findings strongly suggest that GSK-3β inhibits CPCc proliferation post-ischemia, and loss of GSK-3β in cardiomyocytes promotes resident CPCc proliferation potentially through paracrine mechanisms.

The GhsrQ343X allele favors the storage of fat by acting on nutrient partitioning

The Growth Hormone Secretagogue Receptor (GHSR) mediates key properties of the gut hormone ghrelin on metabolism and behavior. Nevertheless, most recent observations also support that the GHSR is a constitutively active G protein-coupled receptor endowed of a sophisticated tuning involving a balance of endogenous ligands. Demonstrating the feasibility of shifting GHSR canonical signaling in vivo, we previously reported that a model with enhanced sensitivity to ghrelin (GhsrQ343X mutant rats) developed fat accumulation and glucose intolerance. Herein, we investigated the contribution of energy homeostasis to the onset of this phenotype, as well as behavioral responses to feeding or pharmacological challenges, by comparing GhsrM/M rats to wild-type littermate rats 1) as freely behaving animals and 2) in feeding and locomotor paradigms. Herein, GhsrM/M rats showed enhanced locomotor response to a GHSR agonist while locomotor or anorexigenic responses to amphetamine or cabergoline (dopamine receptor 2 agonist), respectively, were preserved. Ad libitum fed GhsrM/M rats consumed and conditioned for sucrose similarly to littermate control rats. In calorie-restricted conditions, GhsrM/M rats retained food anticipatory activity and maintained better their body weight and glycemia. Importantly, prior to fat accumulation, male GhsrM/M rats preferentially used carbohydrates as fuel substrate without alterations of energy intake, energy expenditure or physical activity and showed alterations of the GHSR system (i.e. enhanced ratio of GHSR hormones LEAP2:acyl-ghrelin and increased Ghsr expression in the hypothalamus). Overall, the present study provides proof of concept that shifted GHSR signaling can specifically alter nutrient partitioning resulting in modified balance of carbohydrate/lipid utilization.

Anti-inflammatory protein TNFα-stimulated gene-6 (TSG-6) reduces inflammatory response after brain injury in mice

Background Current research suggests that the glial scar surrounding penetrating brain injuries is instrumental in preserving the surrounding uninjured tissue by limiting the inflammatory response to the injury site. We recently showed that tumor necrosis factor (TNF)-stimulated gene-6 (TSG-6), a well-established anti-inflammatory molecule, is present within the glial scar. In the present study we investigated the role of TSG-6 within the glial scar using TSG-6 null and littermate control mice subjected to penetrating brain injuries. Results Our findings show that mice lacking TSG-6 present a more severe inflammatory response after injury, which was correlated with an enlarged area of astrogliosis beyond the injury site. Conclusion Our data provides evidence that TSG-6 has an anti-inflammatory role within the glial scar.

Cardiac MyD88 Mediates Inflammatory Injury and Adverse Remodeling in Diabetes

Background: Hyperglycemia-associated inflammation contributes to adverse remodeling and fibrosis in diabetic heart. MyD88 is an adapter protein of many Toll-like receptors (TLRs) and is recruited to TLRs to initiate inflammatory signalling pathway in endotoxin-activated innate immunity. However, the role of MyD88 in diabetic cardiomyopathy is unknown. Methods: For genetic deficiency, cardiomyocyte-specific MyD88 knockout and littermate control mice were induced type 1 diabetes (T1D) by intraperitoneal injection of 50 mg/kg/day streptozotocin for five days consecutive and then fed for 4 moths. For pharmacological inhibition, MyD88 inhibitor LM8 were administered daily for 8 weeks by oral gavage in T1D and T2D (db/db) mice. The effect of genetic and pharmacological inhibition MyD88 to myocardial injure which were induced by 33 mM glucose in vivo.Results: In this study, we first found that MyD88 expression was increased in cardiomyocytes of diabetic mouse hearts. Cardiomyocyte-specific MyD88 knockout protected mice against hyperglycemia-induced cardiac inflammation, injury, hypertrophy, and fibrosis in T1D model. In cultured cardiomyocytes, MyD88 inhibition either by siRNA or by small-molecular inhibitor LM8 markedly blocked TLR4-MyD88 complex formation, reduced pro-inflammatory MAPKs/NF-κB cascade activation and decreased pro-inflammatory cytokine expression under high glucose condition. Moreover, pharmacologic inhibition of MyD88 by LM8 showed significantly anti-inflammatory, anti-hypertrophic and anti-fibrotic effects in the hearts of both T1D and T2D mice. These beneficial effects of MyD88 inhibition were correlated to the reduced activation of TLR4-MyD88-MAPKs/NF-κB signaling pathways in the hearts.Conclusion: Taken together, MyD88 in cardiomyocytes mediates diabetes-induced cardiac inflammatory injuries and genetic or pharmacologic inhibition of MyD88 shows significantly cardioprotective effects, indicating MyD88 as a potential therapeutic target for diabetic cardiomyopathy.

Silencing Myeloid Netrin-1 Induces Inflammation Resolution and Plaque Regression

Rationale: Therapeutic efforts to decrease atherosclerotic cardiovascular disease risk have focused largely on reducing atherogenic lipoproteins, yet lipid lowering therapies alone are insufficient to fully regress plaque burden. We postulate that arterial repair requires resolution of a maladaptive immune response, and that targeting factors that hinder inflammation resolution will facilitate plaque regression. Objective: The guidance molecule netrin-1 is secreted by macrophages in atherosclerotic plaques, where it sustains inflammation by enhancing macrophage survival and blocking macrophage emigration. We tested whether silencing netrin-1 in advanced atherosclerosis could resolve arterial inflammation and regress plaques. Methods and Results: To temporally silence netrin-1 in myeloid cells, we generated genetically modified mice in which Ntn1 could be selectively deleted in monocytes and macrophages using a tamoxifen-induced CX3CR1-driven cre-recombinase ( Ntn1 fl/fl Cx3cr1 creERT2+ ) and littermate control mice ( Ntn1 fl/fl Cx3cr1 WT ). Mice were fed western diet in the setting of hepatic PCSK9 overexpression to render them atherosclerotic, and then treated with tamoxifen to initiate deletion of myeloid netrin-1 (Mø ΔNtn1 ) or not in controls (Mø WT ). Morphometric analyses performed 4 weeks later showed that myeloid Ntn1 silencing reduced plaque burden in the aorta (-50%) and plaque complexity in the aortic root. Monocyte-macrophage tracing experiments revealed lower monocyte recruitment, macrophage retention, and proliferation in Mø ΔNtn1 compared to Mø WT plaques, indicating a restructuring of monocyte-macrophage dynamics in the artery wall upon netrin-1 silencing. Single cell RNA-sequencing of aortic immune cells prior to and after netrin-1 silencing revealed upregulation of gene pathways involved in macrophage phagocytosis and migration, including the Ccr7 chemokine receptor signaling pathway required for macrophage emigration from plaques and atherosclerosis regression. Additionally, plaques from Mø ΔNtn1 mice showed hallmarks of inflammation resolution, including higher levels of pro-resolving macrophages, interleukin-10, and efferocytosis, as compared to plaques from Mø WT mice. Conclusions: Our data show that targeting netrin-1 in advanced atherosclerosis ameliorates atherosclerotic inflammation and promotes plaque regression.