Protein-protein interaction interfering peptide rescues dysregulated NMDA receptor signaling

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Abstract

The complex and heterogeneous genetic architecture of neuropsychiatric illnesses compels us to look beyond individual risk genes for therapeutic strategies and target the interactive dynamics and convergence of their protein products. A mechanistic substrate for convergence of synaptic neuropsychiatric risk genes are protein-protein interactions (PPIs) in the NMDAR complex. NMDAR hypofunction in schizophrenia is associated with hypoactivity of Src kinase, resulting from convergent alterations in PPIs of Src with its partners. Of these, the association of Src with PSD-95, which inhibits the activity of this kinase in the NMDAR complex, is known to be increased in schizophrenia. Here, we devised a strategy to suppress the inhibition of Src by PSD-95 by employing a cell penetrating and Src activating PSD-95 inhibitory peptide (TAT-SAPIP). TAT-SAPIP enhanced synaptic NMDAR currents in Src+/- and Sdy-/- mice manifesting NMDAR hypofunction phenotypes. Chronic ICV injection of TAT-SAPIP rescued cognitive deficits in trace fear conditioning in Src +/- mice. Moreover, TAT-SAPIP enhanced Src activity in synaptoneurosomes derived from dorsolateral prefrontal cortex of 14 subjects including patients and healthy subjects. We propose blockade of the Src-PSD-95 interaction as a proof of concept for the use of interfering peptides as a therapeutic strategy to reverse NMDAR hypofunction in schizophrenia and other illnesses.

Authors

Robert E. Featherstone, Hongbin Li, Ameet S. Sengar, Karin E. Borgmann-Winter, Olya Melnychenko, Lindsey M. Crown, Ray L. Gifford, Felix Amirfathi, Anamika Banerjee, AiVi Tran, Krishna Parekh, Margaret Heller, Wenyu Zhang, Robert J. Gallop, Adam D. Marc, Pragya Komal, Michael W. Salter, Steven J. Siegel, Chang-Gyu Hahn

Single-cell immune transcriptomics reveals an inflammatory–inhibitory set-point spectrum in autoimmune diabetes

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Abstract

Autoimmune diabetes encompasses rapidly progressive type 1 diabetes mellitus (T1D) and indolent latent autoimmune diabetes in adults (LADA), representing distinct inflammatory set points along a shared autoimmune spectrum. Yet the immunological mechanisms that determine these divergent inflammatory states remain unresolved. We performed single-cell RNA sequencing with paired T and B cell receptor profiling on over 400,000 peripheral blood mononuclear cells (PBMCs) from patients with LADA, newly diagnosed T1D, and healthy controls. PBMC composition was comparable across cohorts, indicating that qualitative rather than quantitative immune differences underlie disease heterogeneity. In T1D, pan-lineage activation of NF-κB, EGFR, MAPK, and hypoxia pathways, coupled with a TNF-centered communication hub, enhanced MHC signaling, and disrupted adhesion, promoted systemic inflammation. LADA, by contrast, exhibited global suppression of NF-κB/EGFR activity, retention of moderate JAK/STAT tone, reinforced natural killer cell inhibitory checkpoints via HLA-C–KIR2DL3/3DL1 interaction, and stabilized CD8⁺ T cell synapses through HLA-C–CD8 binding, collectively restraining effector activation. Single-cell V(D)J analysis revealed multiclonal, patient-unique adaptive repertoires, emphasizing the primacy of signaling context over receptor convergence. These findings define autoimmune diabetes as an inflammatory–inhibitory set-point continuum, positioning the NF-κB/EGFR–JAK/STAT gradient and HLA-C–KIR axis as potential therapeutic targets to preserve residual β-cell function.

Authors

Ivan I. Golodnikov, Elizaveta S. Podshivalova, Vadim I. Chechekhin, Anatoliy V. Zubritskiy, Alina A. Matrosova, Nikita A. Sergeev, Margarita D. Samsonova, Yaroslav V. Dvoryanchikov, Tatiana V. Nikonova, Ekaterina V. Bondarenko, Marina Yu. Loguinova, Yulia A. Medvedeva, Dmitry N. Laptev, Rita I. Khusainova, Ildar R. Minniakhmetov, Marina V. Shestakova, Natalia G. Mokrysheva, Ivan I. Dedov

Transcriptional signature of induced neurons differentiates virologically suppressed people with HIV from people without HIV

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Abstract

Neurocognitive impairment is a prevalent co-morbidity in virologically suppressed people living with HIV (PLWH), yet the underlying mechanisms remain elusive and treatments lacking. We explored use of participant-derived directly induced neurons (iNs) to model neuronal biology and injury in PLWH. iNs retain age- and disease-related donor features, providing unique opportunities to reveal important aspects of neurological disorders. We obtained primary dermal fibroblasts from six virologically suppressed PLWH (range: 27-64 years, median: 53; 83% Male) and seven matched people without HIV (PWOH) (range: 27-66, median: 55; 71% Male). iNs were generated using transcription factors NGN2 and ASCL1, and validated by immunocytochemistry, single-cell-RNAseq, and electrophysiological recordings. Transcriptomic aging analyses confirmed retention of donor age-related signatures. Bulk-RNAseq identified 29 significantly differentially expressed genes between PLWH and PWOH iNs. Of these, 16 were downregulated and 13 upregulated in PLWH iNs. Protein-protein interaction network mapping indicates iNs from PLWH exhibit differences in extracellular matrix organization and synaptic transmission. IFI27 was upregulated in PLWH iNs, complementing independent post-mortem studies demonstrating elevated IFI27 expression in PLWH-derived brain tissue. FOXL2NB-FOXL2-LINC01391 expression was reduced in PLWH iNs and negatively correlated with neurocognitive impairment. Thus, we identified an iN gene signature of HIV revealing mechanisms of neurocognitive impairment in PLWH.

Authors

Philipp N. Ostermann, Youjun Wu, Scott Bowler, Samuel Martínez-Meza, Mohammad A. Siddiqui, David H. Meyer, Alberto Herrera, Brandon A. Sealy, Mega Sidharta, Kiran Ramnarine, Leslie Ann St. Bernard, Desiree Byrd, R. Jones, Masahiro Yamashita, Douglas F. Nixon, Lishomwa C. Ndhlovu, Ting Zhou, Teresa H. Evering

Proteomics-based evaluation of AAV dystrophin gene therapy outcomes in mdx skeletal muscle

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Abstract

Duchenne muscular dystrophy (DMD) is a fatal genetic muscle-wasting disease characterized by loss of dystrophin protein. Therapeutic attempts to restore a functional copy of dystrophin to striated muscle are under active development, and many utilize adeno-associated viral (AAV) vectors. However, the limited cargo capacity of AAVs precludes delivery of full-length dystrophin, a 427 kDa protein, to target tissues. Recently, we developed a novel method to express large dystrophin constructs using the protein trans-splicing (PTS) mechanism mediated by split inteins and myotropic AAV vectors. The efficacy of this approach to restore muscle function in mdx4cv mice was previously assessed using histology, dystrophin immunolabeling, and western blotting. Here, we expand our molecular characterization of dystrophin constructs with variable lengths using a mass spectrometry-based proteomics approach, providing insight into unique protein expression profiles in skeletal muscles of wild-type, dystrophic mdx4cv, and AAV-treated mdx4cv. Our data reveal several affected cellular processes in mdx4cv skeletal muscles with changes in the expression profiles of key proteins to muscle homeostasis, whereas successful expression of dystrophin constructs results in an intermediate to complete restoration. This study highlights several biomarkers that could be used in future preclinical or clinical studies to evaluate the effectiveness of therapeutic strategies.

Authors

Erynn E. Johnson, Theodore R. Reyes, Jeffrey S. Chamberlain, James M. Ervasti, Hichem Tasfaout

Cellular immune endophenotypes separating early and late-onset myasthenia gravis

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Abstract

The two main subgroups of autoimmune myasthenia gravis, a neuromuscular junction disorder associated with muscle weakness, are the early and late-onset forms, defined by onset before or after 50 years of age. Both carry acetylcholine-receptor autoantibodies, but differ in sex ratios, genetics and occurrence of disease-specific thymus inflammation. By applying multimodal techniques, including deep spectral cytometric phenotyping and single cell sequencing to peripheral blood and thymic lymphocyte samples we explored the possibility to discriminate the two forms by cellular immune phenotyping. Analyzing two independent cohorts we identified distinct immunological differences driven by three main lymphocyte populations. Lower frequencies of mucosa-associated invariant T cells and naïve CD8 T cells were observed in late-onset myasthenia, suggesting enhanced immune senescence. Further, a highly differentiated, canonical natural killer cell population was reduced in early-onset myasthenia, which was negatively correlated with the degree of thymic inflammation. Using only the frequency of these three populations, correct myasthenia subgroup assignment could be predicted with an accuracy of 90%. The NK cell population negatively associated to early-onset disease had a similar association to thymic hyperlasia, whereas the two T-cell populations point to enhanced immune senescence in late-onset myasthenia gravis. These distinct immunocellular endophenotypes for early- and late onset disease suggest differences in the immunopathogenic processes. Together with demographic factors and other disease subgroup-specific features, the frequency of the identified cell subpopulations may improve clinical classification, in turn of relevance for channeling to interventions.

Authors

Jakob Theorell, Nicolas Ruffin, Andrew Fower, Chiara Sorini, Philip Ambrose, Valentina Damato, Lahiru Handunnetthi, Isabel Leite, Sarosh R. Irani, Susanna Brauner, Adam E. Handel, Fredrik Piehl

Diagnosis of head and neck cancer by AI-based tumor-educated platelet RNA profiling of liquid biopsies

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Abstract

Over 95% of head and neck cancers are squamous cell carcinoma (HNSCC). HNSCC is mostly diagnosed late, causing a poor prognosis despite the application of invasive treatment protocols. Tumor-educated platelets (TEPs) have been shown to hold promise as a molecular tool for early cancer diagnosis. We sequenced platelet mRNA isolated from blood of 101 HNSCC patients and 101 propensity-score matched non-cancer controls. Two independent machine learning classification strategies were employed using a training and validation approach to identify a cancer predictor: a particle swarm optimized support vector machine (PSO-SVM) and a least absolute shrinkage and selection operator (LASSO) logistic regression model. The best performing PSO-SVM predictor consisted of 245 platelet transcripts and reached a maximum area under the curve (AUC) of 0.87. For the LASSO-based prediction model 1,198 mRNAs were selected, resulting in an median AUC of 0.84, independent of HPV status. Our data show that TEP RNA classification by different AI tools is promising in the diagnosis of HNSCC.

Authors

N.E. Wondergem, J.B. Poell, S.G.J.G In 't Veld, E. Post, S.W. Mes, M.G. Best, W.N. van Wieringen, T. Klausch, R.J. Baatenburg de Jong, C.H.J. Terhaard, R.P. Takes, J.A. Langendijk, I.M. Verdonck-de Leeuw, F. Lamers, C.R. Leemans, E. Bloemena, T. Würdinger, R.H Brakenhoff

Pre-treatment naïve T cells are associated with severe irAE following PD-1/CTLA4 checkpoint blockade for melanoma

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Abstract

Immune checkpoint inhibitors (ICIs) such as anti-PD-1 and anti-CTLA-4 antibodies are used to induce an immune response against many types of tumors. However, ICIs often also induce autoimmune responses, referred to as immune-related adverse events (irAEs), which occur unpredictably and at varying levels of severity in ICI-treated patients. The immunologic factors that predispose patients to the development of severe irAE are largely unclear. Here, we utilized high dimensional mass cytometry immunophenotyping of longitudinal blood samples from patients with metastatic melanoma treated with combination anti-PD-1/CTLA4 ICI therapy in the context of a clinical trial to characterize alterations in immune profiles induced by combination ICI therapy and to identify immune features associated with development of severe irAEs. Deep T cell profiling highlighted that ICI therapy induces prominent expansions of activated, CD38hi CD4+ and CD8+ T cells, which are frequently bound by the therapeutic anti-PD-1 antibody, as well as substantial changes in regulatory T cell phenotypes. However, neither the baseline frequency nor the extent of expansion of these cell populations was associated with development of severe irAEs. Rather, single cell-association testing revealed naïve CD4+ T cell abundance pre-treatment as significantly associated with the development of severe irAEs. Biaxial gating of naïve CD4+ T cells confirmed a significant positive association of naïve CD4+ T cell proportion and development of a severe irAE and with the number of irAEs developed in this cohort. Results from this broad profiling study indicate the abundance of naïve CD4+ T cells as a predictive feature for the development of severe irAEs following combination anti-PD-1/CTLA4 ICI therapy.

Authors

Kathryne E. Marks, Alice Horisberger, Mehreen Elahee, Ifeoluwakiisi A. Adejoorin, Nilasha Ghosh, Michael A. Postow, Laura Donlin, Anne R. Bass, Deepak A. Rao

Influence of Oxidation Resistance 1 on disease progression in chronic myeloid leukemia

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Abstract

Survival in chronic myeloid leukemia (CML) was dramatically improved by development of tyrosine kinase inhibitors (TKIs) directed to the BCR::ABL1 oncogene. Unfortunately, ~30% of CML patients develop TKI-resistance during prolonged treatment, with enhanced blast crisis risk. Oxidation Resistance 1 (Oxr1) regulates anti-oxidant pathways that detoxify reactive oxygen species (ROS) generated by the phagocyte-NADPH oxidase. In the current studies, we found that Oxr1 expression increased in hematopoietic stem and progenitor cells (HSPCs) from CML mice versus controls; decreased during TKI-induced remission; and rose during chronic phase relapse. Oxr1 has long and short isoforms, and we found increased short, but decreased long, Oxr1 in mice or humans during CML relapse. We determined long Oxr1 prevents ROS accumulation in CML marrow, but short Oxr1 is a dominant negative. Previously, we found exaggerated and sustained emergency granulopoiesis in CML mice, with repeated episodes facilitating relapse during TKI-remission. In the current studies, we found knocking-down Oxr1 in murine marrow further accelerates CML progression during this physiologic stress. We found increased DNA-damage in HSPCs from these mice, including a BCR::ABL1 kinase-domain mutation found in TKI-resistant human CML. These studies suggest long Oxr1 detoxifies ROS to decrease mutagenesis in CML, but aberrant short Oxr1 expression enhances progression.

Authors

weiqi huang, Bin Liu, Liping Hu, Chi-Hao Luan, Priyam Patel, Elizabeth T. Bartom, Elizabeth A. Eklund

ANGPTL8 links refeeding to monocyte dynamics and metabolic inflammation via the CCL5-CCR5 axis

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Abstract

Metabolic inflammation is closely linked to dynamic changes in circulating monocyte populations, yet how nutritional signals regulate this process remains unclear. ANGPTL8, a hepatokine rapidly induced by refeeding, emerged as a key regulator of postprandial monocyte dynamics. We examined ANGPTL8 expression in human and murine fasting-refeeding models and manipulated ANGPTL8 expression specifically in hepatocytes to assess its role in metabolic inflammation and insulin resistance in obese mice. ANGPTL8 overexpression elevated circulating monocytes and proinflammatory cytokines, while its deletion reduced these parameters and conferred metabolic benefits. Mechanistically, recombinant ANGPTL8 stimulated CCL5 production in bone marrow-derived macrophages via P38 signaling activation, promoting monocyte recruitment and proinflammatory macrophage polarization. These effects were mitigated by CCR5 antagonism. Rescue experiments demonstrated that CCL5 supplementation in Angptl8-deficient mice restored monocyte levels and inflammatory responses. Functionally, ANGPTL8 worsened insulin resistance and glucose intolerance in obese mice, effects that were reversed by its deletion and recapitulated by CCL5 administration. These findings suggest that ANGPTL8 functions as a nutritional checkpoint linking feeding status to monocyte-mediated inflammation through the CCL5-CCR5 axis. By driving monocytosis and proinflammatory macrophage activation, ANGPTL8 exacerbates metabolic dysfunction. Targeting the ANGPTL8-CCL5-CCR5 pathway may therefore offer a promising therapeutic strategy for managing obesity-related metabolic diseases.

Authors

Ran-Ran Kan, Si-Yi Wang, Xiao-Yu Meng, Li Huang, Yu-Xi Xiang, Bei-Bei Mao, Hua-Jie Zou, Ya-Ming Guo, Li-Meng Pan, Pei-Qiong Luo, Yan Yang, Zhe-Long Liu, De-Lin Ma, Wen-Jun Li, Yong Chen, Dan-Pei Li, Xue-Feng Yu

FGF13 is not secreted from mouse neurons

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Abstract

FGF13, a noncanonical fibroblast growth factor (FGF) and member of the fibroblast growth factor homologous factor (FHF) subset, lacks a signal sequence and was previously reported to remain intracellular, where it regulates voltage-gated sodium channels (VGSCs) at least in part through direct interaction with the cytoplasmic C-terminus of VGSCs. Recent reports suggest that FGF13 is secreted and regulates neuronal VGSCs through interactions with extracellular domains of integral plasma membrane proteins, yet supportive data are limited. Using rigorous positive and negative controls, we showed that transfected FGF13 is not secreted from cultured cells in a heterologous expression system nor is endogenous FGF13 secreted from cultured neurons. Further, employing multiple unbiased screens including proximity protein proteomics, our results suggested FGF13 remains within membranes and is unavailable to interact directly with extracellular protein domains.

Authors

Mattia Malvezzi, Haiying Zhang, Patrick Towers, David C. Lyden, Steven O. Marx, Geoffrey S. Pitt