The circadian clock is reset by external time cues for synchronization to environmental changes. In mammals, the light-input signalling pathway mediated by Per gene induction has been extensively studied. On the other hand, little is known about resetting mechanisms that are independent of Per induction. Here we show that activation of activin receptor-like kinase (ALK), triggered by TGF-beta, activin or alkali signals, evoked resetting of the cellular clock independently of Per induction. The resetting was mediated by an immediate-early induction of Dec1, a gene whose physiological role in the function of the circadian clock has been unclear. Acute Dec1 induction was a prerequisite for ALK-mediated resetting and upregulation was dependent on SMAD3, which was phosphorylated for activation in response to the resetting stimuli. Intraperitoneal injection of TGF-beta into wild-type or Dec1-deficient mice demonstrated that Dec1 has an essential role in phase-shift of clock gene expression in the kidney and adrenal gland. These results indicate that ALK-SMAD3-Dec1 signalling provides an input pathway in the mammalian molecular clock.
Recording neural activity during animal behavior is a cornerstone of modern brain research. However, integration of cutting-edge technologies for neural circuit analysis with complex behavioral measurements poses a severe experimental bottleneck for researchers. Critical problems include a lack of standardization for psychometric and neurometric integration, and lack of tools that can generate large, sharable data sets for the research community in a time and cost effective way. Here, we introduce a novel mouse behavioral learning platform featuring voluntary head fixation and automated high-throughput data collection for integrating complex behavioral assays with virtually any physiological device. We provide experimental validation by demonstrating behavioral training of mice in visual discrimination and auditory detection tasks. To examine facile integration with physiology systems, we coupled the platform to a two-photon microscope for imaging of cortical networks at single-cell resolution. Our behavioral learning and recording platform is a prototype for the next generation of mouse cognitive studies.
Lentiviral vectors deliver transgenes efficiently to a wide range of neuronal cell types in the mammalian central nervous system. To drive gene expression, internal promoters are essential; however, the in vivo properties of promoters, such as their cell type specificity and gene expression activity, are not well known, especially in the nonhuman primate brain. Here, the properties of five ubiquitous promoters (murine stem cell virus [MSCV], cytomegalovirus [CMV], CMV early enhancer/chicken β-actin [CAG], human elongation factor-1α [EF-1α], and Rous sarcoma virus [RSV]) and two cell type-specific promoters (rat synapsin I and mouse α-calcium/calmodulin-dependent protein kinase II [CaMKIIα]) in rat and monkey motor cortices in vivo were characterized. Vesicular stomatitis virus G (VSV-G)-pseudotyped lentiviral vectors expressing enhanced green fluorescent protein (EGFP) under the control of the various promoters were prepared and injected into rat and monkey motor cortices. Immunohistochemical analysis revealed that all of the VSV-G-pseudotyped lentiviral vectors had strong endogenous neuronal tropisms in rat and monkey brains. Among the seven promoters, the CMV promoter showed modest expression in glial cells (9.4%) of the rat brain, whereas the five ubiquitous promoters (MSCV, CMV, CAG, EF-1α, and RSV) showed expression in glial cells (7.0-14.7%) in the monkey brain. Cell type-specific synapsin I and CaMKIIα promoters showed excitatory neuron-specific expression in the monkey brain (synapsin I, 99.7%; CaMKIIα, 100.0%), but their specificities for excitatory neurons were significantly lower in the rat brain (synapsin I, 94.6%; CaMKIIα, 93.7%). These findings could be useful in basic and clinical neuroscience research for the design of vectors that efficiently deliver and express transgenes into rat and monkey brains.
At the final stage of the ventral visual stream, perirhinal neurons encode the identity of memorized objects through learning. However, it remains elusive whether and how object percepts alone, or concomitantly a nonphysical attribute of the objects ("learned"), are decoded from perirhinal activities. By combining monkey psychophysics with optogenetic and electrical stimulations, we found a focal spot of memory neurons where both stimulations led monkeys to preferentially judge presented objects as "already seen." In an adjacent fringe area, where neurons did not exhibit selective responses to the learned objects, electrical stimulation induced the opposite behavioral bias toward "never seen before," whereas optogenetic stimulation still induced bias toward "already seen." These results suggest that mnemonic judgment of objects emerges via the decoding of their nonphysical attributes encoded by perirhinal neurons.
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