Allelomimetic behavior
Allelomimetic behavior, or allomimetic behavior, is a range of activities in which the performance of a behavior increases the probability of that behavior being performed by other nearby animals. Allelomimetic behavior is sometimes called contagious behavior and has strong components of social facilitation, imitation, and group coordination. It is usually considered to occur between members of the same species. An alternate definition is that allelomimetic behavior is a more intense or more frequent response or the initiation of an already known response, when others around the individual are engaged in the same behavior. It is often referred to as synchronous behavior, mimetic behavior, imitative behavior, and social facilitation.
Allelomimetic behavior is displayed in all animals and can occur in any stage of life, but usually starts at a young age. This behavior will continue throughout life, especially when an individual is living in a large group that emphasizes group cohesion. Cohesion is seen as a prerequisite for group living, with synchronous activity being crucial for social cohesion. However, animals in large cohesive groups face trade-offs when allelomimetic behavior is adopted. If the behavior is adopted then the risk of predation or capture decreases significantly but the inter-individual competition for immediate resources, such as food, mates, and space, will increase when cohesion is still stressed. Many collective group decisions in animals are the result of allelomimetism and can be explained by allelomimetic behaviors. Some examples are the cockroaches choosing a single aggregation site, schooling behaviors in fishes, and pheromone-based path selection in ants that allows all the workers to go down the same path to a specific food source. Allelomimetic behavior can also be seen as an animal welfare indicator. For example, if cattle do not have enough room to all lie down simultaneously then it indicates that there are not enough resources present and this can result in lameness of the animals that are forced to stand. Allomimicry is affected by circadian rhythms and circadian cycles of activity within groups which can give the overall appearance of poor animal welfare, if allomimetic behavior were to be used as a welfare indicator then it must be measured several times throughout the course of a day. Most mechanisms involved in performing allelomimetic behavior do not require circadian rhythms to function. Decisions at the individual level are, more often than not, enough to encourage allelomimetism. Patterns of allelomimetic behavior can vary from species to species and can possibly explain other behaviors seen in the animal kingdom.
Function
Group cohesion: Social animals often benefit by behaving in a similar manner to others within their group. This means that when animals switch behaviors, e.g. from lying to grazing, a degree of synchrony is beneficial. Sometimes this synchrony can be provided by environmental cues, at other times it is provided by the group members themselves. In 1978, Clayton wrote "...where environmental stimuli only provide gross synchrony, socially facilitated behavior will provide finer-scale synchrony, and, what is functionally important, greater cohesion of the social group’.Threats
Synchronous behavior is also threatened when animals in a mixed-sex herd have differing nutritional or physical necessities. This causes group instability which often splits the herd up into two separate groups; generally all male and all female, to recreate the mimetic behavior in a smaller, same-sex group that has more similar needs to the individual. Synchronized, allelomimetic behavior is also affected by many factors, such as age, general group size, sex, space, resource availability, and domestication. Domestication can also be seen as a threat to allelomimetic behavior. The process of domestication removes many threats like predation, food shortages, and competition from many individuals for breeding by providing basically unlimited food and resources while providing protection from outside predators. Domestication may favour less synchronization for animals and provide an adaptation to mimetic behavior to save energy in domesticated animals. Domestication also changes the inter-individual distances between animals and behavioral synchrony in general, both of which are important for anti-predator strategies and responses.In horses
Horses, like many animals, learn through imitation of their parents, most often the mother or "broodmare", or the owner of the foal if the broodmare is not available. If the foal is paired with its mother it will not only mimic the mare's walking style and speed, but it will also mimic the mare's temperament and general behaviors. If a foal was to spend much of its early life around a mare that had an unstable temperament, irrational fears and was difficult to work with then it would grow to be an unstable adult that would develop behavioral abnormalities such as balking. Miller also adds that behavioral issues can also be removed through allelomimetic processes. Balking is a common behavior in horses and mules that occur from insecurities and fears, and is observed as hesitance with a general fear of moving forward due to the possibility of attack or invasion of their personal space. This behavior can be eliminated if the owner is fearless, looking forward with their head raised high and marching in place. This shows the horse that there is nothing to fear and eventually the horse will mimic the owner's behavior, sync their gait to the owner and follow along. Repeating this behavior as needed will eventually allow the horse to fully incorporate the owner's fearless behavior into its repertoire and prevent balking from reoccurring. Bad habits are also learned through mimicry if the vast majority of the animals present a specific habit. Cribbing is an example of one such habit. If a foal is raised in an environment where this abnormal behavior is performed by the older members of the team, then it will mimic the habit as well, even if the behavior is dangerous to the individual's health. However, the same mimetic behavior that produces these bad habits can help remove them as well. If a broodmare is unable to train her offspring then it falls to the owner to properly train the foal on proper walking gait, speed, and normal behaviors. If the owner spends enough time with their foal keeping a proper stance then the foal will mimic and perform the proper movements for the rest of its life.In sheep
Sheep provide a good basis for the evaluation of allelomimetic behavior due to their large group sizes and social behavior. Using them as an experimental subject allows for the determination of the imitative quality and intensity of allelomimetic behavior within a specific herd. Merino sheep, or Ovis aries, are a prey species and a domesticated breed of sheep that require a healthy balance between predator avoidance and foraging space for each individual in the herd. They achieve this balance by spreading out to forage for a period of time then quickly running back to the centre of the herd, creating a fastpacking event. A fastpacking event is specifically when an individual on the outskirts of the herd changes its behavior from grazing to running and moves towards the centre of the herd. Fastpacking events are seen as an adaptive behavior for reducing predation due to the intensity of the response presented in other sheep when one individual is seen running from the outer edges to the centre of the herd. This behavioral change is also referred to as activation/inactivation rates or switching behavior. This change influences other sheep to start running to the centre of the herd until all sheep simultaneously stop in the middle and form a tightly packed herd. The cycle will restart when the herd starts to spread out to forage again. The individual that is displaying the switching behavior from inactivity to activity or vice versa is generally referred to as the herd leader, and other individuals who mimic the switch from inactivity to activity or activity to inactivity are displaying allelomimetic behavior. These activation and inactivation rates are generally more strongly presented in males compared to females and increase as the number of individuals performing an activity increase which is a good indication of imitation present in the herd. For example, if a herd had the majority of individuals active the likelihood of another random individual becoming active increases. The same goes for a herd with a majority of individuals being inactive. In experiments, these events are not specific to a singular spot or caused by any external stimuli that would warrant an alarm response in the sheep. In an experiment performed by Gautrais, members of the same sex more often performed mimetic behavior with each other than when compared to members of a mixed-sex group. Gautrais also focused on behavioral synchrony of activity and inactivity since cohesion of a group involves individuals being active and inactive at the same time rather than syncing every activity to another individual.Even in the absence of other animals, individuals will switch between behaviors that require activity and inactivity. Gautrais believes that this physiological need is what prompted the first individual in his herd experiment to switch from activity to inactivity or vice versa and the other members in the herd to follow suit. However, as the number of individuals in a herd decreases, the option to perform mimetic behavior also decreases. This creates a higher rate of spontaneous switching between activity and inactivity-related behaviors. In contrast, the larger the herd is, the more likely it is for mimetic behaviors to occur with spontaneous switching behavior occurring in the "herd leader", with other members following suit in a brief period of time. This is due to the number of con-specifics present at any given time. If the herd is a small group then there are fewer con-specifics which gives less opportunity for imitation to occur in any given individual and a higher rate of switching from inactivity to activity to inactivity will occur. Two ideas are proposed when the original running individual can recruit others into the running group and the herd as a whole can coordinate when to stop running during these fastpacking events. The first idea is that the initiation and inhibition of the packing event is based on allelomimetic effects in local interactions, and the second idea was that a close enough distance between herd neighbours will stop running behavior. These conclusions stem from an idea about optimization processes in sheep that, at an individual level, allows for the balance of exploring as much space as possible to avoid competition for food and keeping in contact with other herd members to avoid predation and reinforce herd cohesion. These optimization processes can adjust the allelomimetic interaction strengths between individuals to ensure both of the above necessities are met.