Motor learning involves the acquisition of a motor skill and its consolidation into memory, two distinct processes with separate neural substrates. Although the motor cortex has been implicated in the early consolidation of motor skills, it is unclear what constitutes the long-term memorization of these skills and how the peripheral musculature can quickly re-acquire motor performance after long periods of non-use.
To investigate this issue, we used birdsong acquisition as a model system, as songbirds have evolved a well-described specialized neural motor circuitry and vocal organ, both dedicated exclusively to song.
First, we determined the contribution of synaptic plasticity in the brain circuitry controlling singing behaviour to skill savings. One of the song control areas in the songbird forebrain, nucleus HVC, is located at a central position in the motor circuitry that drives the the songbird vocal organ, the syrinx. We analyzed the the density of neuronal dendritic spines, the loci where most of the synaptic connections are formed, in HVC at different stages during the development, loss, and re-development of song. We found that the number of spines in HVC strongly reduces when a bird develops song for the first time. Moreover, this reduction is maintained when birds stop singing, suggesting that a lasting memory has formed that could enable birds to quickly re-acquire song performance (Vellema et al., 2018; BioRxiv doi:
https://doi.org/10.1101/440388(odnośnik otworzy się w nowym oknie)).
Secondly, we investigated the contribution of vocal muscles during vocal skill development. The songbird vocal organ, the syrinx, is a well-described bipartite structure specifically adapted for producing the high variety of sounds that is unique to birdsong. Eight pairs of muscles envelop the two sound sources that can be operated independently to increase vocal performance. Because we previously found that the speed of vocal muscles increases significantly during song development (Mead et al., eLife 2017; 6: e29425), and influences motor behaviors on a millisecond scale (Srivastava, K., 2017; Proc. Natl. Acad. Sci. U.S.A. 114: 1171-1176), we investigated if muscle speeds were maintained between periods of song development. We quantified muscle kinetics during the development, loss, and redevelopment of song, and found no direct evidence that muscles are involved in storing motor skills.
Together these results suggest that during development motor skills are stored in the brain circuits that control the behaviour in question, and quickly drive the peripheral musculature towards previously acquired motor performance.