Lewy Body-like Inclusions in Human Midbrain Organoids Carrying Glucocerebrosidase and α-Synuclein Mutations.

OBJECTIVE: We utilized human midbrain-like organoids (hMLOs) generated from human pluripotent stem cells carrying glucocerebrosidase gene (GBA1) and α-synuclein (α-syn; SNCA) perturbations to investigate genotype-to-phenotype relationships in Parkinson disease, with the particular aim of recapitulating α-syn- and Lewy body-related pathologies and the process of neurodegeneration in the hMLO model. METHODS: We generated and characterized hMLOs from GBA1-/- and SNCA overexpressing isogenic embryonic stem cells and also generated Lewy body-like inclusions in GBA1/SNCA dual perturbation hMLOs and conduritol-b-epoxide-treated SNCA triplication hMLOs. RESULTS: We identified for the first time that the loss of glucocerebrosidase, coupled with wild-type α-syn overexpression, results in a substantial accumulation of detergent-resistant, ß-sheet-rich α-syn aggregates and Lewy body-like inclusions in hMLOs. These Lewy body-like inclusions exhibit a spherically symmetric morphology with an eosinophilic core, containing α-syn with ubiquitin, and can also be formed in Parkinson disease patient-derived hMLOs. We also demonstrate that impaired glucocerebrosidase function promotes the formation of Lewy body-like inclusions in hMLOs derived from patients carrying the SNCA triplication. INTERPRETATION: Taken together, the data indicate that our hMLOs harboring 2 major risk factors (glucocerebrosidase deficiency and wild-type α-syn overproduction) of Parkinson disease provide a tractable model to further elucidate the underlying mechanisms for progressive Lewy body formation. ANN NEUROL 2021;90:490-505.

Neural circuit analysis using a novel intersectional split intein-mediated split-Cre recombinase system.

The defining features of a neuron are its functional and anatomical connections with thousands of other neurons in the brain. Together, these neurons form functional networks that direct animal behavior. Current approaches that allow the interrogation of specific populations of neurons and neural circuits rely heavily on targeting their gene expression profiles or connectivity. However, these approaches are often unable to delineate specific neuronal populations. Here, we developed a novel intersectional split intein-mediated split-Cre recombinase system that can selectively label specific types of neurons based on their gene expression profiles and structural connectivity. We developed this system by splitting Cre recombinase into two fragments with evolved split inteins and subsequently expressed one fragment under the influence of a cell type-specific promoter in a transgenic animal, and delivered the other fragment via retrograde viral gene transfer. This approach results in the reconstitution of Cre recombinase in only specific population of neurons projecting from a specific brain region or in those of a specific neuronal type. Taken together, our split intein-based split-Cre system will be useful for sophisticated characterization of mammalian brain circuits.

Visualizing Microglia with a Fluorescence Turn-On Ugt1a7c Substrate.

Microglia, the brain-resident macrophage, are involved in brain development and contribute to the progression of neural disorders. Despite the importance of microglia, imaging of live microglia at a cellular resolution has been limited to transgenic mice. Efforts have therefore been dedicated to developing new methods for microglia detection and imaging. Using a thorough structure-activity relationships study, we developed CDr20, a high-performance fluorogenic chemical probe that enables the visualization of microglia both in vitro and in vivo. Using a genome-scale CRISPR-Cas9 knockout screen, the UDP-glucuronosyltransferase Ugt1a7c was identified as the target of CDr20. The glucuronidation of CDr20 by Ugt1a7c in microglia produces fluorescence.

Direct Induction and Functional Maturation of Forebrain GABAergic Neurons from Human Pluripotent Stem Cells.

Gamma-aminobutyric acid (GABA)-releasing interneurons play an important modulatory role in the cortex and have been implicated in multiple neurological disorders. Patient-derived interneurons could provide a foundation for studying the pathogenesis of these diseases as well as for identifying potential therapeutic targets. Here, we identified a set of genetic factors that could robustly induce human pluripotent stem cells (hPSCs) into GABAergic neurons (iGNs) with high efficiency. We demonstrated that the human iGNs express neurochemical markers and exhibit mature electrophysiological properties within 6-8 weeks. Furthermore, in vitro, iGNs could form functional synapses with other iGNs or with human-induced glutamatergic neurons (iENs). Upon transplantation into immunodeficient mice, human iGNs underwent synaptic maturation and integration into host neural circuits. Taken together, our rapid and highly efficient single-step protocol to generate iGNs may be useful to both mechanistic and translational studies of human interneurons.

Target mechanism-based whole-cell screening identifies bortezomib as an inhibitor of caseinolytic protease in mycobacteria.

UNLABELLED: A novel type of antibacterial screening method, a target mechanism-based whole-cell screening method, was developed to combine the advantages of target mechanism- and whole-cell-based approaches. A mycobacterial reporter strain with a synthetic phenotype for caseinolytic protease (ClpP1P2) activity was engineered, allowing the detection of inhibitors of this enzyme inside intact bacilli. A high-throughput screening method identified bortezomib, a human 26S proteasome drug, as a potent inhibitor of ClpP1P2 activity and bacterial growth. A battery of secondary assays was employed to demonstrate that bortezomib indeed exerts its antimicrobial activity via inhibition of ClpP1P2: Down- or upmodulation of the intracellular protease level resulted in hyper- or hyposensitivity of the bacteria, the drug showed specific potentiation of translation error-inducing aminoglycosides, ClpP1P2-specific substrate WhiB1 accumulated upon exposure, and growth inhibition potencies of bortezomib derivatives correlated with ClpP1P2 inhibition potencies. Furthermore, molecular modeling showed that the drug can bind to the catalytic sites of ClpP1P2. This work demonstrates the feasibility of target mechanism-based whole-cell screening, provides chemical validation of ClpP1P2 as a target, and identifies a drug in clinical use as a new lead compound for tuberculosis therapy. IMPORTANCE: During the last decade, antibacterial drug discovery relied on biochemical assays, rather than whole-cell approaches, to identify molecules that interact with purified target proteins derived by genomics. This approach failed to deliver antibacterial compounds with whole-cell activity, either because of cell permeability issues that medicinal chemistry cannot easily fix or because genomic data of essentiality insufficiently predicted the vulnerability of the target identified. As a consequence, the field largely moved back to a whole-cell approach whose main limitation is its black-box nature, i.e., that it requires trial-and-error chemistry because the cellular target is unknown. We developed a novel type of antibacterial screening method, target mechanism-based whole-cell screening, to combine the advantages of both approaches. We engineered a mycobacterial reporter strain with a synthetic phenotype allowing us to identify inhibitors of the caseinolytic protease (ClpP1P2) inside the cell. This approach identified bortezomib, an anticancer drug, as a specific inhibitor of ClpP1P2. We further confirmed the specific "on-target" activity of bortezomib by independent approaches including, but not limited to, genetic manipulation of the target level (over- and underexpressing strains) and by establishing a dynamic structure-activity relationship between ClpP1P2 and growth inhibition. Identifying an "on-target" compound is critical to optimize the efficacy of the compound without compromising its specificity. This work demonstrates the feasibility of target mechanism-based whole-cell screening methods, validates ClpP1P2 as a druggable target, and delivers a lead compound for tuberculosis therapy.

Role of the striatopallidal pathway in renewal and reacquisition of alcohol seeking.

The ventral pallidum (VP) is a key component of the neural circuitry mediating relapse to drug seeking, but the critical afferent pathways to VP recruited during relapse remain poorly understood. We studied the role of the nucleus accumbens core (AcbC) → VP pathway in ABA renewal and reacquisition of alcohol seeking. Rats received application of adenoviral vectors encoding eYFP, ChR2(H134R), or eNpHr3.0 to AcbC and implantation of fiber optic cannulas into VP to permit photostimulation of AcbC terminals there. Rats were then trained to self-administer alcoholic beer in 1 context (A), extinguished in a second context (B), tested in the extinction (ABB) and training (ABA) contexts, and were then tested for reacquisition of alcoholic beer seeking. There was ABA renewal of alcohol seeking, but neither optogenetic excitation nor inhibition of the AcbC → VP pathway affected this renewal. In contrast, optogenetic inhibition of the AcbC → VP striatopallidal pathway reduced reacquisition of alcohol seeking-measured either by the number of active nosepokes emitted or by the number of alcohol rewards earned and consumed. Moreover, optogenetic excitation of the AcbC → VP striatopallidal pathway increased magazine entries during reacquisition test. This finding shows the importance of the AcbC → VP pathway in controlling relapse when the drug reinforcer is present on test and is consistent with a role for the AcbC → VP pathway in regulating the hedonic or incentive motivational properties of drug reinforcers.

The role of hepatocyte growth factor/c-Met system in keloid pathogenesis.

BACKGROUND: Keloid scar is a fibroproliferative disorder characterized by increased deposition of extracellular matrix components. Hepatocyte growth factor (HGF), also known as the "scatter factor," and its receptor, a product of the Met oncogene, play multiple roles in regulating cell behavior. However, the role of this system in pathogenic fibrosis is still unclear. Our aim was to investigate and to clarify the role of HGF and its receptor c-Met in pathogenesis of keloid scars. METHODS: This study investigated the expression profile of HGF and c-Met in keloid and normal skin tissue. In addition, the role of normal and keloid keratinocytes in modulating the expression of fibroblast HGF (epithelial-mesenchymal interactions) was examined using a two-chamber serum-free coculture model. The effect of serum stimulation on fibroblast expression of HGF and c-Met was also studied. RESULTS: Increased levels of HGF and c-Met were observed in tissue extracts obtained from keloid tissue. Increased levels of HGF and c-Met localization were observed in the basal epidermis and in the dermis of keloid tissue compared with normal skin. Serum stimulation seemed to upregulate the expression of both HGF and c-Met in fibroblasts. Finally, coculture of keloid keratinocytes with keloid fibroblasts upregulated levels of both HGF and c-Met in keratinocyte cell lysates and conditioned media obtained from fibroblast culture. CONCLUSIONS: These findings emphasize the importance of the HGF/c-Met system in keloid biology and pathogenesis and suggest a possible target for therapeutic intervention in the prevention and treatment of keloids.

Syndecan-2 and decorin: proteoglycans with a difference--implications in keloid pathogenesis.

BACKGROUND: Growth factors and cytokines involved in the wound healing process seem to be immobilized at the cell surface and extracellular matrix via binding with proteoglycans, making them important modulators of cell dynamics. Our aim was to investigate the expression of two proteoglycans, namely syndecan-2 and decorin, and to elucidate their role in the pathogenesis of an aberrant wound healing process leading to keloid scar. METHODS: Intrinsic expression of syndecan-2, fibroblast growth factor (FGF)-2, and decorin in keloid tissue was investigated using Western blotting and immunohistochemistry. Normal and keloid fibroblasts were treated with serum to see the effects of serum growth factors on the expression of syndecan-2 and decorin. The role of epithelial-mesenchymal interactions in modulating syndecan-2, FGF-2, and decorin expression was investigated using an established two-chamber serum-free coculture model. Finally, the antifibrotic effect of decorin was investigated by studying its effect on the expression of extracellular matrix components. RESULTS: Syndecan-2 and FGF-2 were upregulated in keloid tissue; decorin was downregulated. Normal and keloid fibroblasts treated with serum led to increase in syndecan-2 and decrease in decorin expression. Under coculture conditions, syndecan-2 was shed in the conditioned media. FGF-2 was also upregulated under coculture conditions and, when added to fibroblast monocultures, increased shedding of syndecan-2. Decorin levels were upregulated under coculture conditions only in normal cocultures. Decorin was also able to decrease extracellular matrix proteins, highlighting its importance as an antifibrotic agent. CONCLUSION: Syndecan-2 and FGF-2 are not only overexpressed in keloid tissues but may interact with each other resulting in the shedding of syndecan-2, which in turn might activate a whole cascade of events responsible for a keloidic phenotype. In addition, decorin had an antifibrotic effect and could well be used as a potential therapeutic agent for keloids.