Raju Tomer scite author profile

CLARITY is a method for chemical transformation of intact biological tissues into a hydrogeltissue hybrid, which becomes amenable to interrogation with light and macromolecular labels while retaining fine structure and native biological molecules. This emerging accessibility of information from large intact samples has created both new opportunities and new challenges. Here we describe next-generation protocols spanning multiple dimensions of the CLARITY workflow, ranging from a novel approach to simple, reliable, and efficient lipid removal without electrophoretic instrumentation (passive CLARITY), to optimized objectives and integration with light-sheet optics (CLARITY-optimized light-sheet microscopy or COLM) for accelerating data collection from clarified samples by several orders of magnitude while maintaining or increasing quality and resolution. These methods may find application in the structural and molecular analysis of large assembled biological systems such as the intact mammalian brain.

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Intact-Brain Analyses Reveal Distinct Information Carried by SNc Dopamine Subcircuits

Lerner¹,

Shilyansky²,

Davidson³

et al. 2015

Cell

689

767

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SUMMARY Recent controversy regarding the diversity of midbrain dopamine neurons has highlighted the importance—and the challenges—of defining mammalian neuronal cell types. Although neurons may be best categorized using inclusive criteria spanning biophysical properties, wiring of inputs, wiring of outputs, and activity during behavior, linking all of these measurements to cell types within the intact brains of living mammals has been difficult. Here, using an array of intact-brain circuit interrogation tools, including CLARITY, optogenetics, viral tracing, and fiber photometry, we explore the diversity of dopamine neurons within the substantia nigra pars compacta (SNc). We identify two parallel nigrostriatal dopamine neuron subpopulations differing in biophysical properties, input wiring, output wiring to dorsomedial striatum (DMS) versus dorsolateral striatum (DLS), and natural activity patterns during free behavior. Our results reveal independently operating nigrostriatal information streams, with implications for understanding the logic of dopaminergic feedback circuits and the diversity of mammalian neuronal cell types.

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Quantitative high-speed imaging of entire developing embryos with simultaneous multiview light-sheet microscopy

et al. 2012

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Live imaging of large biological specimens is fundamentally limited by the short optical penetration depth of light microscopes. To maximize physical coverage, we developed the SiMView technology framework for high-speed in vivo imaging, which records multiple views of the specimen simultaneously. SiMView consists of a light-sheet microscope with four synchronized optical arms, real-time electronics for long-term sCMOS-based image acquisition at 175 million voxels per second, and computational modules for high-throughput image registration, segmentation, tracking and real-time management of the terabytes of multiview data recorded per specimen. We developed one-photon and multiphoton SiMView implementations and recorded cellular dynamics in entire Drosophila melanogaster embryos with 30-s temporal resolution throughout development. We furthermore performed high-resolution long-term imaging of the developing nervous system and followed neuroblast cell lineages in vivo. SiMView data sets provide quantitative morphological information even for fast global processes and enable accurate automated cell tracking in the entire early embryo.

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Molecular interrogation of hypothalamic organization reveals distinct dopamine neuronal subtypes

et al. 2016

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The hypothalamus contains the highest diversity of neurons in the brain. Many of these neurons can co-release neurotransmitters and neuropeptides in a use-dependent manner. Investigators have hitherto relied on candidate protein-based tools to correlate behavioral, endocrine and gender traits with hypothalamic neuron identity. Here we map neuronal identities in the hypothalamus by single-cell RNA sequencing. We distinguished 62 neuronal subtypes producing glutamatergic, dopaminergic or GABAergic markers for synaptic neurotransmission and harboring the ability to engage in task-dependent neurotransmitter switching. We identified dopamine neurons that uniquely coexpress the Onecut3 and Nmur2 genes, and placed these in the periventricular nucleus with many synaptic afferents arising from neuromedin S neurons of the suprachiasmatic nucleus. These neuroendocrine dopamine cells may contribute to the dopaminergic inhibition of prolactin secretion diurnally, as their neuromedin S inputs originate from neurons expressing Per2 and Per3 and their tyrosine hydroxylase phosphorylation is regulated in a circadian fashion. Overall, our catalog of neuronal subclasses provides new understanding of hypothalamic organization and function.

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Raju Tomer

Advanced CLARITY for rapid and high-resolution imaging of intact tissues

Intact-Brain Analyses Reveal Distinct Information Carried by SNc Dopamine Subcircuits

Quantitative high-speed imaging of entire developing embryos with simultaneous multiview light-sheet microscopy

Molecular interrogation of hypothalamic organization reveals distinct dopamine neuronal subtypes

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