SAMD9 and SAMD9L germline mutations have recently emerged as a new class of predispositions to pediatric myeloid neoplasms. Patients commonly have impaired hematopoiesis, hypocellular marrows, and a greater risk of developing clonal chromosome 7 deletions leading to MDS and AML. We recently demonstrated that expressing SAMD9 or SAMD9L mutations in hematopoietic cells suppresses their proliferation and induces cell death. Here we generated a mouse model that conditionally expresses mutant Samd9l to assess the in vivo impact on hematopoiesis. Using a range of in vivo and ex vivo assays, we showed that cells with heterozygous Samd9l mutations have impaired stemness relative to wild-type counterparts, which was exacerbated by inflammatory stimuli, and ultimately led to bone marrow hypocellularity. Genomic and phenotypic analyses recapitulated many of the hematopoietic cellular phenotypes observed in patients with SAMD9 or SAMD9L mutations, including lymphopenia, and pinpointed TGF-β as a potential targetable pathway. Further, we observed non-random genetic deletion of the mutant Samd9l locus on mouse chromosome 6, mimicking chromosome 7 deletions observed in patients. Collectively, our study has enhanced our understanding of mutant Samd9l hematopoietic phenotypes, emphasized the synergistic role of inflammation in exaggerating the associated hematopoietic defects, and provided insights into potential therapeutic options for patients.
Sherif Abdelhamed, Melvin E. Thomas III, Tamara Westover, Masayuki Umeda, Emily Xiong, Chandra Rolle, Michael P. Walsh, Huiyun Wu, Jason R. Schwartz, Virginia Valentine, Marcus Valentine, Stanley Pounds, Jing Ma, Laura J. Janke, Jeffery M. Klco
Abdominal aortic aneurysm (AAA) is a life-threatening vascular disease. BAF60c, a unique subunit of the SWItch/Sucrose Non-Fermentable (SWI/SNF) chromatin remodeling complex, is critical for cardiac and skeletal myogenesis; yet, little is known about its function in the vasculature and, specifically, in AAA pathogenesis. Here, we found that BAF60c was downregulated in human and mouse AAA tissues, with primary staining to vascular smooth muscle cells (VSMC), confirmed by single-cell RNA-sequencing. In vivo studies revealed that VSMC-specific knockout of Baf60c significantly aggravated both AngII- and elastase-induced AAA formation in mice, with a significant increase in elastin degradation, inflammatory cell infiltration, VSMC phenotypic switch, and apoptosis. In vitro studies showed that BAF60c knockdown in VSMC resulted in the loss of contractile phenotype, increased VSMC inflammation, and apoptosis. Mechanistically, we demonstrated that BAF60c preserved VSMC contractile phenotype by strengthening serum response factor (SRF) association with its co-activator P300 and the SWI/SNF complex, suppressed VSMC inflammation by promoting a repressive chromatin state of the NFκB-target genes, as well as prevented VSMC apoptosis through transcriptional activation of KLF5-dependent BCL2 expression. Together, our identification of the essential role of BAF60c in preserving VSMC homeostasis expands its therapeutic potential in preventing and treating AAA.
Guizhen Zhao, Yang Zhao, Haocheng Lu, Ziyi Chang, Hongyu Liu, Huilun Wang, Wenying Liang, Yuhao Liu, Tianqing Zhu, Oren Rom, Yanhong Guo, Lin Chang, Bo Yang, Minerva T. Garcia-Barrio, Jiandie D. Lin, Y. Eugene Chen, Jifeng Zhang
BACKGROUND. Studies in cell cultures and rodents suggest that toll-like receptor (TLR)4 is involved in the pathogenesis of insulin resistance, but direct data in humans are limited. We tested the hypothesis that pharmacologic blockade of TLR4 with the competitive inhibitor eritoran would improve insulin resistance in humans. METHODS. In Protocol I, 10 lean, healthy subjects received the following 72-h intravenous (I.V.) infusions in a randomized crossover design: saline (30 ml/h)+vehicle; Intralipid® (30 ml/h)+vehicle; or Intralipid® (30 ml/h)+eritoran (12 mg I.V. every 12 h). In Protocol II, 9 obese, non-diabetic subjects received eritoran (12 mg I.V. every 12 h) or vehicle for 72 h, also in a randomized crossover design. The effects of eritoran were assessed with a euglycemic, hyperinsulinemic clamp. RESULTS. In Protocol I, lipid infusion significantly decreased peripheral insulin sensitivity (M value) by 14% and increased fasting plasma glucose (FPG), fasting plasma insulin (FPI) and HOMA insulin resistance index (HOMA-IR) by 7%, 22%, and 26%, respectively. Eritoran did not prevent lipid-induced alterations in these metabolic parameters. Eritoran also failed to improve any baseline metabolic parameters (M, FPG, FPI, HOMA-IR) in obese, insulin-resistant subjects (Protocol II). CONCLUSIONS. Acute TLR4 inhibition with eritoran did not protect against lipid-induced insulin resistance. Short-term eritoran administration also failed to improve obesity-associated insulin resistance. These data do not support a role for TLR4 in insulin resistance. Future studies with a different class of TLR4 inhibitors, longer drug exposure, and/or lipid-enhancing interventions richer in saturated fats may be needed to further clarify the role of TLR4 on metabolic dysfunction in humans. TRIAL REGISTRATIONS. ClinicalTrials.gov NCT02321111, NCT02267317 FUNDING. NIH grants R01DK080157, P30AG044271, P30AG013319 and UL1TR002645.
Hanyu Liang, Nattapol Sathavarodom, Claudia Colmenares, Jonathan Gelfond, Sara E. Espinoza, Vinutha Ganapathy, Nicolas Musi
The molecular mechanisms underlying obesity-induced increase in β cell mass, and the resulting β cell dysfunction need to be elucidated further. Our study revealed that GPR92, expressed in islet macrophages, is modulated by dietary interventions in metabolic tissues. Therefore, we aimed to define the role of GPR92 in islet inflammation by using high fat diet (HFD)-induced obese mouse model. GPR92 knockout mice exhibited glucose intolerance and reduced insulin level, despite the enlarged pancreatic islets, and increased islet macrophage content and inflammation level (compared to those in wild type mice). These results indicate that the lack of GPR92 in islet macrophages can cause β cell dysfunction, leading to disrupted glucose homeostasis. Alternatively, GPR92 agonist, farnesyl pyrophosphate (FPP) stimulation results in the inhibition of HFD-induced islet inflammation and increased insulin secretion in WT mice, but not in GPR92 KO mice. Thus, our study suggests that GPR92 can be a potential target to alleviate β cell dysfunction via the inhibition of islet inflammation associated with the progression of diabetes.
Camila O. de Souza, Vivian A. Paschoal, Xue-Nan Sun, Lavanya Vishvanath, Qianbin Zhang, Mengle Shao, Toshiharu Onodera, Shiuhwei Chen, Nolwenn Joffin, Lorena M.A. Bueno, Rana K. Gupta, Da Young Oh
Increasing evidences advocate for an important function of T cells in controlling immune homeostasis and pathogenesis after myocardial infarction (MI), although the underlying molecular mechanisms remain elusive. In this study, a broad analysis of immune markers in 283 patients revealed a significant CD69 overexpression on Treg cells after MI. Our results in mice showed that CD69 expression on Treg cells increased survival after left-anterior-descending coronary artery (LAD)-ligation. Cd69-/- mice developed strong IL-17+ γδT cell responses after ischemia that increased myocardial inflammation and, consequently, worsened cardiac function. CD69+ Treg cells, by induction of AhR-dependent CD39 ectonucleotidase activity, induced apoptosis and decreased IL-17A production in γδT cells. Adoptive transfer of CD69+ Treg cells to Cd69-/- mice after LAD-ligation reduced IL-17+ γδT cell recruitment, thus increasing survival. Consistently, clinical data from two independent cohorts of patients indicated that increased CD69 expression in peripheral blood cells after acute MI was associated with a lower risk of re-hospitalization for heart failure (HF) after 2.5 years of follow-up. This result remained significant after adjustment for age, sex and traditional cardiac damage biomarkers. Our data highlight CD69 expression on Treg cells as a potential prognostic factor and a therapeutic option to prevent HF after MI.
Rafael Blanco-Domínguez, Hortensia de la Fuente, Cristina Rodríguez, Laura Martín-Aguado, Raquel Sánchez-Díaz, Rosa Jiménez-Alejandre, Iker Rodriguez-Arabaolaza, Andrea Curtabbi, Marcos M. Garcia-Guimaraes, Alberto Vera, Fernando Rivero, Javier Cuesta, Luis Jesus Jimenez-Borreguero, Alberto Cecconi, Albert Duran-Cambra, Manel Taurón, Judith Alonso, Héctor Bueno, María Villalba-Orero, José Antonio Enriquez, Simon C. Robson, Fernando Alfonso, Francisco Sánchez-Madrid, José Martínez-González, Pilar Martín
Although first-line epidermal growth factor receptor (EGFR) tyrosine kinase inhibitor (TKI) therapy is effective for treating EGFR-mutant non-small cell lung cancer (NSCLC), it is now understood that drug-tolerant persister (DTP) cells escaping from initial treatment eventually drives drug resistance. Here, through integration of metabolomics and transcriptomics, we found that the neurotransmitter acetylcholine (ACh) was specifically accumulated in DTP cells, and illustrated that treatment with EGFR-TKI heightens the expression of the rate-limiting enzyme choline acetyltransferase (ChAT) in ACh biosynthesis via YAP mediation. Genetic and pharmacological manipulation of ACh biosynthesis or ACh signaling could predictably regulate the extent of DTP formation in vitro and in vivo. Strikingly, pharmacologically targeting ACh/M3R signaling with an FDA-approved drug, Darifenacin, retarded tumor relapse in vivo. Mechanistically, upregulated ACh metabolism mediated drug tolerance in part through activating WNT signaling via ACh muscarinic receptor-3 (M3R). Importantly, aberrant ACh metabolism in NSCLC patients represented a potential role in predicting EGFR-TKI response rate and progression-free survival. Our study therefore defines a new therapeutic strategy—targeting ACh-M3R-WNT axis—for manipulating EGFR TKI drug tolerance in the treatment of NSCLC.
Meng Nie, Na Chen, Huanhuan Pang, Tao Jiang, Wei Jiang, Panwen Tian, LiAng Yao, Yangzi Chen, Ralph J. DeBerardinis, Weimin Li, Qitao Yu, Caicun Zhou, Zeping Hu
CLN1 disease is a fatal neurodegenerative lysosomal storage disorder resulting from mutations in the CLN1 gene encoding the soluble lysosomal enzyme, palmitoyl-protein thioesterase-1 (PPT1). Therapies for CLN1 disease have proven challenging because of the aggressive disease course and the need to treat widespread areas of the brain and spinal cord. Indeed, gene therapy has proven less effective for CLN1 disease than for other similar lysosomal enzyme deficiencies. We therefore tested the efficacy of enzyme replacement therapy (ERT) by delivering monthly infusions of recombinant human PPT1 (rhPPT1) in PPT1-deficient mice (Cln1−/−), and CLN1R151X sheep to assess scale up for translation. In Cln1−/− mice, intracerebroventricular rhPPT1 delivery was the most effective route of administration, resulting in therapeutically relevant CNS levels of PPT1 activity. rhPPT1 treated-mice had improved motor function, reduced disease-associated pathology, and diminished neuronal loss. In CLN1R151X sheep, intracerebroventricular infusions resulted in widespread rhPPT1 distribution and positive treatment effects measured by quantitative structural magnetic resonance imaging and neuropathology. These findings demonstrate the feasibility and therapeutic efficacy of intracerebroventricular rhPPT1 enzyme replacement therapy. This represents a key step towards clinical testing of ERT in children with CLN1 disease and highlights the importance of a cross-species approach to developing a successful treatment strategy.
Hemanth R. Nelvagal, Samantha L. Eaton, Sophie H. Wang, Elizabeth M. Eultgen, Keigo Takahashi, Steven Q. Le, Rachel Nesbitt, Joshua T. Dearborn, Nicholas Siano, Ana C. Puhl, Patricia I. Dickson, Gerard Thompson, Fraser Murdoch, Paul M. Brennan, Mark Gray, Stephen N. Greenhalgh, Peter Tennant, Rachael Gregson, Eddie Clutton, James Nixon, Chris Proudfoot, Stefano Guido, Simon G. Lillico, C. Bruce A. Whitelaw, Jui-Yun Lu, Sandra L. Hofmann, Sean Ekins, Mark S. Sands, Thomas M. Wishart, Jonathan D. Cooper
BACKGROUND. Cognitive impairment is a common symptom of Parkinson’s Disease (PD), which increases in risk and severity as the disease progresses. The stage at which patients exhibit cognitive deficit on neuropsychological tests but daily social and occupational functioning is unaffected is termed mild cognitive impairment (MCI). Currently, an unmet clinical need is accurately predicting the risk of progression from the MCI stage to PDD which negatively affects the patients quality of life and incurs a greater cost on society and caregivers. METHODS. We investigated the use of a supervised learning algorithm called Support Vector Machine (SVM) to retrospectively stratify patients based on brain fluorodeoxyglucose (FDG) –PET. Of 43 PD-MCI patients scanned at baseline, 23 progressed to PDD within a 5 year follow-up period, whereas 20 remained stable MCI. The baseline FDG-PET scans were used to train an SVM model which optimally separated patients as PDD converters vs. stable MCI with 95% sensitivity and 91% specificity. RESULTS. The high classification performance was confirmed with 10-fold cross-validation (87% sensitivity and 85% specificity). The hyperplane of the resulting SVM model was topographically characterized by hypometabolism in the posterior temporal and parietal lobes and hypermetabolism in the anterior cingulum, putamen, insular gyrus, mesiotemporal lobe, postcentral gyrus and supplementary motor area. The statistical significance of the hyperplane topology was verified by a permutation test, suggesting that these brain metabolic signatures robustly predicted PDD conversions within 5 years from PD-MCI status. The performance of the SVM model was tested on an independent dataset from two brain imaging centers located in Seoul (South Korea) and Winnipeg (Canada) which confirmed that the model is also sensitive to later stage PDD (17 of 19; 89% sensitivity) and Dementia with Lewy Bodies (DLB; 16 of 17; 94% sensitivity). Only 12% of cognitively normal PD patients (2 of 17) were classified as PDD converters while none of the 18 normal control subjects were classified as such. Finally, anti-PD medication status did not change the SVM classification of the another set of 10 PD patients (3 of 10 patients were classified as PDD converters) who were scanned twice ON and OFF medication. CONCLUSIONS. These results potentially indicate that the proposed FDG-PET-based SVM classifier has high utility for providing accurate prognosis of dementia development in PD-MCI patients.
Samuel Booth, Kye Won Park, Chong Sik Lee, Ji Hyun Ko
CBL-B is an E3 ubiquitin ligase that ubiquitinates proteins downstream of immune receptors to downregulate positive signaling cascades. Distinct homozygous mutations in CBLB were identified in three unrelated children with early onset autoimmunity, one of whom also had chronic urticaria. Patient T cells exhibited hyper-proliferation in response to anti-CD3 cross-linking. One of the mutations, p.R496X, abolished CBL-B expression, and a second mutation, p.C464W, resulted in preserved CBL-B expression. The third mutation, p.H285L in the SH2 domain of CBL-B, was expressed at half the normal level in the patient’s cells. Mice homozygous for the CBL-B p.H257L mutation, which corresponds to the patient’s p.H285L mutation, had T and B cell hyper-proliferation in response to antigen receptor cross-linking. CblbH257L mice had increased percentages of T regulatory cells (Tregs) that had normal in vitro suppressive function. However, T effector cells (Teffs) from the patient with the p.H285L mutation and CblbH257L mice were resistant to suppression by WT Treg cells. Bone marrow derived mast cells (BMMCs) from CblbH257L mice were hyper-activated after FcεRI cross-linking, and CblbH257L mice demonstrated exaggerated IgE-mediated passive anaphylaxis. This study establishes CBL-B deficiency as a cause of immune dysregulation.
Erin Janssen, Zachary Peters, Mohammed F. Alosaimi, Emma Smith, Elena Milin, Kelsey Stafstrom, Jacqueline G. Wallace, Craig D. Platt, Janet Chou, Yasmeen S. El Ansari, Tariq Al Farsi, Najim Ameziane, Ruslan Al-Ali, María Calvo, Maria Eugenia Rocha, Peter Bauer, Nouriya Abbas Al-Sannaa, Nashat Faud Al Sukaiti, Abdullah A. Alangari, Aida M. Bertoli-Avella, Raif S. Geha
Invasive bacterial infections remain a major cause of human morbidity. Group B Streptococcus (GBS) are Gram-positive bacteria that cause invasive infections in humans. Here, we show that Factor XIIIA (FXIIIA) -deficient female mice exhibited significantly increased susceptibility to GBS infections. Additionally, female wild-type mice had increased levels of FXIIIA and were more resistant to GBS infection compared to isogenic male mice. We observed that administration of exogenous FXIIIA to male mice increased host resistance to GBS infection. Conversely, administration of a FXIIIA transglutaminase inhibitor to female mice decreased host resistance to GBS infection. Interestingly, male gonadectomized mice exhibited decreased sensitivity to GBS infection, suggesting a role for gonadal androgens in host susceptibility. FXIIIA promoted GBS entrapment within fibrin clots by crosslinking fibronectin with ScpB, a fibronectin binding GBS surface protein. Thus, ScpB-deficient GBS exhibited decreased entrapment within fibrin clots in vitro and increased dissemination during systemic infections. Finally, using mice where FXIIIA expression was depleted in mast cells, we observed that mast cell derived FXIIIA contributes to host defense against GBS infection. Our studies provide insights into the effect of sexual dimorphism and mast cells on FXIIIA expression and its interactions with GBS adhesins that mediate bacterial dissemination and pathogenesis.
Adrian M. Piliponsky, Kavita Sharma, Phoenicia Quach, Alyssa Brokaw, Shayla Nguyen, Austyn Orvis, Siddhartha S. Saha, Nyssa Becker Samanas, Ravin Seepersaud, Yu Ping Tang, Emily Mackey, Gauri Bhise, Claire Gendrin, Anna Furuta, Albert J. Seo, Eric Guga, Irina Miralda, Michelle M. Coleman, Erin L. Sweeney, Charlotte A. Bäuml, Diana Imhof, Jessica M. Snyder, Adam J. Moeser, Lakshmi Rajagopal
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