Summary: Researchers have identified a neural network in the brains of monkeys that may represent a common evolutionary origin for social communication and human speech.
Source: Rockefeller University.
Most animals, including our primate cousins, communicate: they gesture, grimace, grunt, and sing. As a rule, however, they do not speak. So how, exactly, did humans acquire their unique talent for verbal discourse? And how do our brains manage this complex bit of communicative magic?
Scientists in the lab of Winrich Freiwald have shed new light on the underpinnings of human speech by identifying neural circuitry in the brains of monkeys that could represent a common evolutionary origin for social communication. As reported in the journal Neuron, these circuits are involved in face recognition, facial expression, and emotion. And they may very well have given rise to our singular capacity for speech.
Working with rhesus macaque monkeys, Freiwald had previously identified neural networks responsible for recognizing faces—networks that closely resemble ones found in the human brain.
Other researchers, meanwhile, had suggested that particular areas of the brain might be responsible for producing facial expressions. But no one had imaged these facial motor regions while they were active, much less when they were being used for communication. Nor did scientists understand how these networks might interact with each other and with areas of the brain that handle emotion, another integral component of social interaction.
Freiwald and Stephen Shepherd, a former research associate in the lab, decided to investigate the patterns of activation that occur within and between these various networks to better understand how the brain coordinates the intricate task of social communication. They used a novel experimental setup to take MRI scans of the brains of monkeys as they watched video clips of other monkeys making communicative facial expressions. In some of the clips, the videotaped monkeys looked off to the side, mimicking a situation in which the subject monkeys were passively observing communication between other animals without participating in it. In others, the prerecorded animals appeared to be looking directly at the subject monkeys, simulating face-to-face social interaction.
These differences in social context proved to be significant. When the monkeys in the clips made a friendly lip-smacking gesture, the subject monkeys responded in kind—but only when their prerecorded peers appeared to be making direct eye contact with them.
The brain scans taken during these different kinds of simulated events were even more illuminating.
Based on previous research, the scientists expected the face-perception regions of the monkeys’ brains to simply feed information to a region associated with emotion, which would then stimulate the regions responsible for producing facial expressions.
All of those areas were indeed activated. But much to the researchers’ surprise, they did not shuttle information to one another in straightforward, sequential fashion.
What’s more, videos that simulated social interaction through direct eye contact caused an unexpected third neural circuit to light up. This suggests that specific areas of the animals’ brains are sensitive to social context, and perform the specialized cognitive functions necessary for social communication.
Producing facial expressions in response to the videotaped monkeys prompted an entirely different pattern of brain activation. Generating a friendly lipsmack, in particular, activated a region that resembles Broca’s area, a portion of the human brain concerned with the production of speech.
As Freiwald explains, this suggests that monkey facial expressions like lipsmacks might be evolutionary precursors to human speech—a possibility that some scientists had previously discounted on the grounds that such gestures were too simple or reflexive to pave the way for something as subtle and sophisticated as human verbal communication.
Currently, the researchers are measuring the electrical activity in individual neurons in all three of the networks revealed in the scans. This allows them to more precisely gauge the activity in each of these areas during social communication and form a more detailed picture of how the neural circuits responsible for face processing, facial expression, and social context interact.
“Understanding this in monkeys will help us understand communication in humans, where things are so much more complicated,” says Freiwald, who describes the findings as “an important building block” in the quest to understand our species’ unique way with words.
[cbtabs][cbtab title=”MLA”]Rockefeller University”A Possible Origin of Human Speech.” NeuroscienceNews. NeuroscienceNews, 23 July 2018. <https://neurosciencenews.com/human-speech-origin-9597/>.[/cbtab][cbtab title=”APA”]Rockefeller University(2018, July 23). A Possible Origin of Human Speech. NeuroscienceNews. Retrieved July 23, 2018 from https://neurosciencenews.com/human-speech-origin-9597/[/cbtab][cbtab title=”Chicago”]Rockefeller University”A Possible Origin of Human Speech.” https://neurosciencenews.com/human-speech-origin-9597/ (accessed July 23, 2018).[/cbtab][/cbtabs]
Functional Networks for Social Communication in the Macaque Monkey
All primates communicate. To dissect the neural circuits of social communication, we used fMRI to map non-human primate brain regions for social perception, second-person (interactive) social cognition, and orofacial movement generation. Face perception, second-person cognition, and face motor networks were largely non-overlapping and acted as distinct functional units rather than an integrated feedforward-processing pipeline. Whereas second-person context selectively engaged a region of medial prefrontal cortex, production of orofacial movements recruited distributed subcortical and cortical areas in medial and lateral frontal and insular cortex. These areas exhibited some specialization, but not dissociation, of function along the medio-lateral axis. Production of lipsmack movements recruited areas including putative homologs of Broca’s area. These findings provide a new view of the neural architecture for social communication and suggest expressive orofacial movements generated by lateral premotor cortex as a putative evolutionary precursor to human speech.