Antipsychotic drugs selectively decorrelate long-range interactions in deep cortical layers.

Psychosis is characterized by a diminished ability of the brain to distinguish externally driven activity patterns from self-generated activity patterns. Antipsychotic drugs are a class of small molecules with relatively broad binding affinity for a variety of neuromodulator receptors that, in humans, can prevent or ameliorate psychosis. How these drugs influence the function of cortical circuits, and in particular their ability to distinguish between externally and self-generated activity patterns, is still largely unclear. To have experimental control over self-generated sensory feedback, we used a virtual reality environment in which the coupling between movement and visual feedback can be altered. We then used widefield calcium imaging to determine the cell type-specific functional effects of antipsychotic drugs in mouse dorsal cortex under different conditions of visuomotor coupling. By comparing cell type-specific activation patterns between locomotion onsets that were experimentally coupled to self-generated visual feedback and locomotion onsets that were not coupled, we show that deep cortical layers were differentially activated in these two conditions. We then show that the antipsychotic drug clozapine disrupted visuomotor integration at locomotion onsets also primarily in deep cortical layers. Given that one of the key components of visuomotor integration in cortex is long-range cortico-cortical connections, we tested whether the effect of clozapine was detectable in the correlation structure of activity patterns across dorsal cortex. We found that clozapine as well as two other antipsychotic drugs, aripiprazole and haloperidol, resulted in a strong reduction in correlations of layer 5 activity between cortical areas and impaired the spread of visuomotor prediction errors generated in visual cortex. Our results are consistent with the interpretation that a major functional effect of antipsychotic drugs is a selective alteration of long-range layer 5-mediated communication.

Mouse Motor Cortex Coordinates the Behavioral Response to Unpredicted Sensory Feedback.

Motor cortex (M1) lesions result in motor impairments, yet how M1 contributes to the control of movement remains controversial. To investigate the role of M1 in sensory guided motor coordination, we trained mice to navigate a virtual corridor using a spherical treadmill. This task required directional adjustments through spontaneous turning, while unexpected visual offset perturbations prompted induced turning. We found that M1 is essential for execution and learning of this visually guided task. Turn-selective layer 2/3 and layer 5 pyramidal tract (PT) neuron activation was shaped differentially with learning but scaled linearly with turn acceleration during spontaneous turns. During induced turns, however, layer 2/3 neurons were activated independent of behavioral response, while PT neurons still encoded behavioral response magnitude. Our results are consistent with a role of M1 in the detection of sensory perturbations that result in deviations from intended motor state and the initiation of an appropriate corrective response.

Fluorescent Calcium Indicator Protein Expression in the Brain Using Tetracycline-Responsive Transgenic Mice.

To achieve robust long-term fluorescent calcium indicator protein (FCIP) expression in mammalian neurons in vivo, classical mouse transgenesis by pronuclear DNA injection using tetracycline (Tet)-controlled genetic switches can be deployed. This protocol describes methods for regulated expression of FCIP using Tet-responsive transgenic mice. The Tet-inducible system requires three components for inducible and reversible control of gene expression: (1) a potent transcriptional activator protein, either Tet transactivator (tTA) or reverse tTA (rtTA); (2) a minimal Tet-promoter (P(tet)) or a bidirectional Tet-promoter (P(tet)bi) to express one or more responder genes; and (3) Tet or one of its derivatives such as doxycycline (Dox) as an inducer. To ensure a high level of FCIP expression in neurons, transgenic founder mice are screened using an ear fibroblast culture method to identify those that are responsive to Dox treatment before use in experiments. The protocol describes the use of Dox to regulate gene expression and provides a short description of in vivo recording of luciferase activity.

Fluorescent Calcium Indicator Protein Expression in the Mouse Brain Using Recombinant Adeno-Associated Viruses.

One method for gene delivery and long-term fluorescent calcium indicator protein (FCIP) expression in mammalian neurons in vivo involves the introduction of FCIPs via recombinant adeno-associated virus (rAAV) vectors using constitutive and cell type-specific promoters. This protocol describes the use of rAAVs to express FCIPs in the brain for imaging. Human embryonic kidney 293 cells are first transfected using calcium phosphate. rAAV is then prepared using either an iodixanol gradient or a heparin column. After the virus is purified, its quality is assessed by sodium dodecyl sulfate polyacrylamide gel electrophoresis, estimation of genomic and functional virus titers by quantitative polymerase chain reaction, and expression in dissociated neurons. Mice are injected with rAAV using a stereotactic instrument and can be imaged ∼3 wk later.