SUMMARY Genetic studies have revealed significant overlaps of risk genes among psychiatric disorders. However, it is not clear how different mutations of the same gene contribute to different disorders. We characterized two lines of mutant mice with Shank3 mutations linked to ASD and schizophrenia. We found both shared and distinct synaptic and behavioral phenotypes. Mice with the ASD-linked InsG3680 mutation manifest striatal synaptic transmission defects before weaning age and impaired juvenile social interaction, coinciding with the early onset of ASD symptoms. On the other hand, adult mice carrying the schizophrenia-linked R1117X mutation show profound synaptic defects in prefrontal cortex and social dominance behavior. Furthermore, we found differential Shank3 mRNA stability and SHANK1/2 upregulation in these two lines. These data demonstrate that different alleles of the same gene may have distinct phenotypes at molecular, synaptic, and circuit levels in mice, which may inform exploration of these relationships in human patients.
SUMMARYTranscription factor programming of pluripotent stem cells (PSCs) has emerged as an approach to generate human neurons for disease modeling. However, programming schemes produce a variety of cell types, and those neurons that are made often retain an immature phenotype, which limits their utility in modeling neuronal processes, including synaptic transmission. We report that combining NGN2 programming with SMAD and WNT inhibition generates human patterned induced neurons (hpiNs). Single-cell analyses showed that hpiN cultures contained cells along a developmental continuum, ranging from poorly differentiated neuronal progenitors to well-differentiated, excitatory glutamatergic neurons. The most differentiated neurons could be identified using a CAMK2A::GFP reporter gene and exhibited greater functionality, including NMDAR-mediated synaptic transmission. We conclude that utilizing single-cell and reporter gene approaches for selecting successfully programmed cells for study will greatly enhance the utility of hpiNs and other programmed neuronal populations in the modeling of nervous system disorders.
Rett syndrome (RTT) arises from loss-of-function mutations in methyl-CpG binding protein 2 gene (Mecp2), but fundamental aspects of its physiological mechanisms are unresolved. Here, by whole-cell recording of synaptic responses in MeCP2 mutant mice in vivo, we show that visually driven excitatory and inhibitory conductances are both reduced in cortical pyramidal neurons. The excitation-to-inhibition (E/I) ratio is increased in amplitude and prolonged in time course. These changes predict circuit-wide reductions in response reliability and selectivity of pyramidal neurons to visual stimuli, as confirmed by two-photon imaging. and increases KCC2 expression to normalize the KCC2/NKCC1 ratio. Thus, loss of MeCP2 in the brain alters both excitation and inhibition in brain circuits via multiple mechanisms. Loss of MeCP2 from a specific interneuron subtype contributes crucially to the cell-specific and circuit-wide deficits of RTT. The joint restoration of inhibition and excitation in cortical circuits is pivotal for functionally correcting the disorder.MeCP2 | E/I balance | parvalbumin neurons | IGF1 | chloride transporters S ynaptic excitation (E) and inhibition (I), along with the neuronal balance of excitation and inhibition (E/I), is key to the function of brain circuits, and is often disrupted in neurodevelopmental disorders, including autism spectrum disorders (ASDs) (1-3). Rett syndrome (RTT) is a severe neurodevelopmental and adult disorder that arises from sporadic loss-of-function mutations in the X-linked (Xq28) methyl-CpG binding protein 2 gene (Mecp2) encoding the protein MeCP2 (4-7). MeCP2 is a critical regulator of brain development and adult neural function (8), and arrested brain maturation due to synaptic dysfunction is one of the hallmarks of RTT (3). However, the effects of MeCP2 on excitatory and inhibitory synaptic mechanisms in vivo, and on neuronal and circuit function underlying RTT pathophysiology, are unknown.MeCP2 is ubiquitously expressed in multiple cell types and subregions of the brain (4, 6, 9), including inhibitory interneurons, and has cell-autonomous as well as non-cell-autonomous effects (10); thus, it has been particularly challenging to identify its role in cell-specific brain circuits. Anatomically diverse inhibitory interneuron subtypes with distinct physiological signatures influence different aspects of neocortical function and behavior (11,12). Soma-targeting parvalbumin-expressing (PV + ) and dendritetargeting somatostatin-expressing (SOM + ) interneurons are the two major nonoverlapping populations of interneurons in mice that target cortical pyramidal neurons (13). Inhibition by PV + and SOM + neurons powerfully influences neuronal responses and circuit computations in visual cortex (14-17). Deletion of MeCP2 from all forebrain GABAergic interneurons recapitulates key aspects of RTT (18), demonstrating that altered inhibitory function is an important facet of RTT pathophysiology. Indeed, a major phenotype of MeCP2 reduction in individuals with RTT and in mouse models is ...
Aberrant expression of Lin28 and let-7 has been observed in many human malignancies. However, its functions and underlying mechanisms remain largely elusive. Here we show that aberrant expression of Lin28 and let-7 facilitates aerobic glycolysis, or Warburg effect, in cancer cells. Mechanistically, we discover that Lin28A and Lin28B enhance, whereas let-7 suppresses, aerobic glycolysis via targeting pyruvate dehydrogenase kinase 1, or PDK1, in a hypoxia-or hypoxia-inducible factor-1 (HIF-1)-independent manner, illustrating a novel pathway to mediate aerobic glycolysis of cancer cells even in ambient oxygen levels. Importantly, we further demonstrate that PDK1 is critical for Lin28A-and Lin28B-mediated cancer proliferation both in vitro and in vivo, establishing a previously unappreciated mechanism by which Lin28/let-7 axis facilitates Warburg effect to promote cancer progression. Our findings suggest a potential rationale to target PDK1 for cancer therapy in malignancies with aberrant expression of Lin28 and let-7.
River Scholar of China and the Foreign Academicians of the Russian Academy of Engineering and Russian Academy of Science. Her research interests mainly focus on bioeffects and safety evaluation of nanomaterials and environmental pollution analysis and control. Rui L. Reis obtained his Ph.D. and D.Sc. in polymer engineering-biomaterials & tissue engineering from the University of Minho, Portugal. He is vice president for Research and Innovation of UMinho and the director of the 3B's Research Group and ICVS/3B's Associate Laboratory. He is a full professor of Tissue Engineering, Regenerative Medicine and Stem Cells at UMinho and honorary professor in four different Asian Universities. His main area of research is the development of biomaterials from natural origin polymers, and using those in combination with different stem cells for several strategies for tissue engineering and regenerative medicine, applied to distinct human tissues.
Size, shape, and protein corona play a key role in cellular uptake and removal mechanisms of gold nanoparticles (Au NPs). The 15 nm nanoparticles (NP1), the 45 nm nanoparticles (NP2), and the rod‐shaped nanoparticles (NR) enter into cells via a receptor‐mediated endocytosis (RME) pathway. The star‐shaped nanoparticles (NS) adopt not only clathrin‐mediated, but also caveolin‐mediated endocytosis pathways. However, the 80 nm nanoparitcles (NP3) mainly enter into the cells by macropinocytosis pathway due to the big size. Furthermore, the results indicate that the presence of protein corona can change the uptake mechanisms of Au NPs. The endocytosis pathway of NP1, NP2, and NS changes from RME to macropinocytosis pathway and NR changes from RME to clathrin and caveolin‐independent pathway under the non‐fetal bovine serun (FBS)‐coated condition. Both FBS‐coated and non‐FBS‐coated of five types of Au NPs are released out through the lysosomal exocytosis pathway. The size, shape, and protein corona have an effect on the exocytosis ratio and amount, but do not change the exocytosis mechanism. The systematic study of the endocytosis and exocytosis mechanism of Au NPs with different sizes and shapes will benefit the toxicology evaluation and nanomedicine application of Au NPs.
Key Points Question Can multiparametric magnetic resonance imaging (MRI) radiomic profiles be used to predict axillary lymph node metastasis (ALNM) and disease-free survival (DFS) in patients with early-stage breast cancer? Findings In this prognostic study that included 1214 patients, 2 clinical-radiomic nomograms were developed that accurately predicted ALNM and stratified patients into low-risk and high-risk groups for DFS. Meaning In this study, clinical-radiomic nomograms were useful in clinical decision-making associated with personalized selection of surgical interventions and therapeutic regimens for patients with early-stage breast cancer.
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