Abstract
To decipher neural circuits anatomy is the central basis for all kinds of neurobiological
studies. Here in this thesis, I will start with extensive overview of the current methods that
have been intensively employed in labeling and mapping neurons and neuronal activities,
including tracing techniques, imaging/recording systems and manipulation tools. This will
be followed by the introduction of the two model systems that are being studied in this
thesis.
Specifically, the ultimate goal of this thesis is to examine the anatomical neural circuits of
involving median prefrontal cortex and the serotonergic nuclei, by developing a
standardized brain atlas for automatic processing and analyzing anatomical image data,
which facilitate functional studies of the serotonergic neurons in rats.
In paper I, we characterized the inputs to two major serotonergic nuclei using a retrograde
trans-synaptic virus. We reconstructed a whole brain input map with customized software,
and found previously undefined inputs. We also confirmed the existence of the functional
connection from basal ganglia, lateral habenula, and prefrontal cortex to the raphe nuclei
serotonergic neurons. In paper II, we developed a versatile interactive framework for
automatic detection, registration, and analysis. In paper III, we characterized both the local
and long-range inputs to four cell types in the mouse medial prefrontal cortex. A new viral
strategy for tracing both local and long-range inputs at the same time was developed. We
have confirmed the findings by other tracing techniques, and rebuilt our own connectivity
map. In paper IV, we explored the roles of serotonergic neurons in impulsive behavior by
manipulating and recording the neurons.
In summary, we have developed new methods for neural circuitry study, added our
knowledge of the serotonergic and median prefrontal cortex circuitry, and gained deeper
insights of functional roles of serotonergic neurons.