Transient changes in the firing of midbrain dopamine neurons have been closely tied to the unidimensional value-based prediction error contained in temporal difference reinforcement learning models. However, whereas an abundance of work has now shown how well dopamine responses conform to the predictions of this hypothesis, far fewer studies have challenged its implicit assumption that dopamine is not involved in learning value-neutral features of reward. Here, we review studies in rats and humans that put this assumption to the test, and which suggest that dopamine transients provide a much richer signal that incorporates information that goes beyond integrated value.

The major pathological feature of Parkinson 's disease (PD), the second most common neurodegenerative disease and most common movement disorder, is the predominant degeneration of dopaminergic neurons in the substantia nigra, a part of the midbrain. Despite decades of research, the molecular mechanisms of the origin of the disease remain unknown. While the disease was initially viewed as a purely neuronal disorder, results from single-cell transcriptomics have suggested that oligodendrocytes may play an important role in the early stages of Parkinson's. Although these findings are of high relevance, particularly to the search for effective disease-modifying therapies, the actual functional role of oligodendrocytes in Parkinson's disease remains highly speculative and requires a concerted scientific effort to be better understood. This Unsolved Mystery discusses the limited understanding of oligodendrocytes in PD, highlighting unresolved questions regarding functional changes in oligodendroglia, the role of myelin in nigral dopaminergic neurons, the impact of the toxic environment, and the aggregation of alpha-synuclein within oligodendrocytes.

Understanding how corticostriatal circuits mediate behavioral selection and initiation in a naturalistic setting is critical to understanding behavior choice and execution in unconstrained situations. The central striatum (CS) is well poised to play an important role in these spontaneous processes. Using fiber photometry and optogenetics, we identify a role for CS in grooming initiation. However, CS-evoked movements resemble short grooming fragments, suggesting additional input is required to appropriately sustain behavior once initiated. Consistent with this idea, the anterior lateral motor area (ALM) demonstrates a slow ramp in activity that peaks at grooming termination, supporting a potential role for ALM in encoding grooming bout length. Furthermore, optogenetic stimulation of ALM-CS terminals generates sustained grooming responses. Finally, dual-region photometry indicates that CS activation precedes ALM during grooming. Taken together, these data support a model in which CS is involved in grooming initiation, while ALM may encode grooming bout length.

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Recent advances in the field of Voltage Imaging, with a special focus on new constructs and novel implementations.

Work related to place tuning, spatial navigation, orientation and direction. Mainly includes articles on connectivity in the hippocampus, retrosplenial cortex, and related areas.

Labeling the plasma membrane for advanced imaging remains a significant challenge. For time-lapse live cell imaging, probe internalization and photobleaching are major limitations affecting most membrane-specific dyes. In fixed or permeabilized cells, many membrane probes either lose signal after fixation or fail to remain localized to the plasma membrane. Thus, improved probes are critically needed for applications in spatial biology. In this study, we systematically compared a range of custom-synthesized and commercially available lipid-based probes for their efficiency in labeling the plasma membrane in live, fixed, and permeabilized cells. We identified a superior probe, which outperformed others due to its lipid structure. This comparison provides insights into ideal lipid probes for visualizing the plasma membrane using advanced imaging techniques.

During origin licensing, the origin recognition complex (ORC) loads two Mcm2-7 helicases onto DNA in a head-to-head conformation, establishing the foundation for subsequent bidirectional replication. Single-molecule experiments support a helicase-loading model in which one ORC loads both Mcm2-7 helicases at origins. For this to occur, ORC must release from its initial Mcm2-7 and DNA binding sites, flip over the helicase, and bind the opposite end of the Mcm2-7 complex and adjacent DNA to form the MO complex. Importantly, this binding-site transition occurs without ORC releasing into solution. Using a single-molecule FRET assay, we show that the N-terminal half of Orc6 tethers ORC to the N-terminal tier of Mcm2-7 (Mcm2-7N) during ORC\'s binding-site transition. This interaction involves both the folded Orc6 N-terminal domain (Orc6N) and the adjacent unstructured linker and forms before ORC releases from its initial Mcm2-7 interaction. The absence of this interaction increases the rate of ORC release into solution, consistent with a tethering function. CDK phosphorylation of ORC inhibits the tethering interaction, providing a mechanism for the known CDK inhibition of MO complex formation. Interestingly, we identify mutations in the Orc6 linker region that support MO complex formation but prevent double-hexamer formation by inhibiting stable second Mcm2-7 recruitment. Our study provides a molecular explanation for a one-ORC mechanism of helicase loading and demonstrates that Orc6 is involved in multiple stages of origin licensing.