As you may know, I have been teaching BIO101 (and also the BIO102 Lab) to non-traditional students in an adult education program for about twelve years now. Every now and then I muse about it publicly on the blog (see this, this, this, this, this, this and this for a few short posts about various aspects of it – from the use of videos, to the use of a classroom blog, to the importance of Open Access so students can read primary literature). The quality of students in this program has steadily risen over the years, but I am still highly constrained with time: I have eight 4-hour meetings with the students over eight weeks. In this period I have to teach them all of biology they need for their non-science majors, plus leave enough time for each student to give a presentation (on the science of their favourite plant and animal) and for two exams. Thus I have to strip the lectures to the bare bones, and hope that those bare bones are what non-science majors really need to know: concepts rather than factoids, relationship with the rest of their lives rather than relationship with the other sciences. Thus I follow my lectures with videos and classroom discussions, and their homework consists of finding cool biology videos or articles and posting the links on the classroom blog for all to see. A couple of times I used malaria as a thread that connected all the topics – from cell biology to ecology to physiology to evolution. I think that worked well but it is hard to do. They also write a final paper on some aspect of physiology.
Another new development is that the administration has realized that most of the faculty have been with the school for many years. We are experienced, and apparently we know what we are doing. Thus they recently gave us much more freedom to design our own syllabus instead of following a pre-defined one, as long as the ultimate goals of the class remain the same. I am not exactly sure when am I teaching the BIO101 lectures again (late Fall, Spring?) but I want to start rethinking my class early. I am also worried that, since I am not actively doing research in the lab and thus not following the literature as closely, that some of the things I teach are now out-dated. Not that anyone can possibly keep up with all the advances in all the areas of Biology which is so huge, but at least big updates that affect teaching of introductory courses are stuff I need to know.
I need to catch up and upgrade my lecture notes. And what better way than crowdsource! So, over the new few weeks, I will re-post my old lecture notes (note that they are just intros – discussions and videos etc. follow them in the classroom) and will ask you to fact-check me. If I got something wrong or something is out of date, let me know (but don’t push just your own preferred hypothesis if a question is not yet settled – give me the entire controversy explanation instead). If something is glaringly missing, let me know. If something can be said in a nicer language – edit my sentences. If you are aware of cool images, articles, blog-posts, videos, podcasts, visualizations, animations, games, etc. that can be used to explain these basic concepts, let me know. And at the end, once we do this with all the lectures, let’s discuss the overall syllabus – is there a better way to organize all this material for such a fast-paced class.
Today, we discuss animal behavior. Note that I tend to do a lot of drawing on the whiteboard in this lecture, which is not seen in these notes. I also show a lot of short YouTube videos that show examples of strange animal behaviors.
Imagine that you are a zebra, grazing in the savanna. Suddenly, you smell a lion. A moment later, you hear a lion approaching and, out of the corner of your eye, you see the lion running towards you.
What happens next? You start running away, of course. How does that happen? Your brain received information from your sensory organs, processed that information and made a decision to pursue a particular action. That decision is relayed to the muscles that do the actual running.
In short, that is behavior and it can be schematically depicted like this:
Environment———> Sensor ———-> Integrator———> Effector
Here, the change in the environment (appearance of a lion) is perceived by the sensors (eyes, nose, ears), processed by the integrator (the brain) and results in the activity of the effectors (muscles).
But, it is usually not that simple. The flow chart, as depicted, may be accurate when describing behavior of a bacterium, a protist, a fungus or a plant. A molecule in the cell membrane of a bacterium may sense nutrients, toxins or light. This information is processed by the cell as a whole, and as a result, the cilia or flagella move the bacterium in an appropriate direction.
Specialized cells in the shoot-tips or root-tips may detect up and down, or the position of the Sun, and guide growth in an appropriate direction (shoots up, roots down). Sunflowers and some other plants track the position of the Sun throughout the day. Many plants open and close their flowers or leaves at particular times of day. Some flowers, e.g, Venus flytrap and some orchids, can move even faster in order to capture insects.
Pilobolus, a fungus (seen as fine white fuzz on manure), shoots its spores towards the Sun at a particular angle at a particular time of day. Those are all simple behaviors involving a single sensor, a single integrator and a single effector in a simple unidirectional flow of information.
Once we get to animals with central nervous systems, things get a little bit more complicated. There are often multiple sensors. In the zebra example, the changes in environment are detected by three separate sensors: for vision, audition and olfaction. Effectors are many muscles, working in a highly coordinated manner.
Sensors located in the muscles feed the information about their activity back to the integrator. Integrator feeds back to the sensors as well – raising the sensitivity of the sensory organs, including vision, hearing, smell and the tactile sense (touch), while reducing the sensitivity of other sensors, e.g., for pain. The subjective perception of the rate of passage of time slows down, allowing for more fine-grained sensation and faster decision-making by the integrator.
Furthermore, the integrator will stimulate secretion of the hormones which, in turn, may increase the ability of effectors (muscles) to do their work. Integrator will also raise the activity of other organ systems that are important in allowing muscles to perform at their maximal level, e.g., circulatory and respiratory systems that bring oxygen and energy to the muscles.
At the same time, the brain temporarily shuts down the activity of organ systems not necessary for short-term survival, but which may take the valuable energy away from the muscles. Thus, the digestive, immune, excretory and reproductive systems are inhibited.
As the zebra runs away, the act of running results in subsequent changes in the environment, which are again detected by the sensors. The integrator makes decisions to suddenly swerve if the lion gets closer, or to buck and kick if the lion gets very close, or to stop and find the safest route back to the herd if the lion has abandoned the chase.
All the changes described in the zebra example above are elements of the stress response, which is an excellent example of a complex behavior. There are multiple sensors, multiple effectors, various modifications of the body’s physiology, and several kinds of information feedbacks involved. Behavioral biology studies all aspects of it.
In addition, it is not just the activity itself, but also the propensity for such activity that is studied by behavioral biology. Probability of a behavior happening depends on the motivation, or the state of the effector. The state can be modified by hormones, hunger, tiredness, libido, general energy levels, etc. The effector (e.g, the brain) also possesses timing mechanism (clocks and calendars) which make some behaviors much more likely during the day or during the night, some more likely during spring or summer, others more likely during fall or winter.
What Is Behavior?
It is difficult to define behavior without resorting to just listing examples of various kinds of behaviors, but let’s try to define it anyway: Behavior is a change in body’s position, shape or color, or a change in potential for such change, in response to changes in the external or internal environment. Behavior is endogenously generated (i.e., if I move your arm – that is not your behavior, it’s mine), purposive (meant to achieve a goal), and is an evolved adaptation that contributes to survival or reproduction, thus increases one’s fitness (which is obvious in the case of the fleeing zebra).
How to study behavior?
The most informative and profitable way to study behavior is an integrative approach. This means that the behavior under study is approached at all levels of organization (from molecules to ecosystems) and from four different angles. The first angle is Mechanism, which denotes study of the physiology underlying behavior. Most of the analysis of the zebra’s behavior described above focused on this aspect – the physiology of the sensory, neural, muscular and other systems and the way they work together to produce the behavior.
The second one is Ontogeny, the study of embryonic and post-embryonic development of the behavior – how does an individual acquire the behavior, how much is the behavior inherited vs. learned, at what time in one’s life cycle can the behavior be learned or expressed, at what times of day or year are the behaviors most likely to be expressed, etc.
These first two angles – mechanism and ontogeny – are sometimes called Proximate Causes of behavior and are designed to ask and answer the “How” questions of behavior (how does it work, how does it develop). The next two are called Ultimate Causes of behavior and are designed to ask and answer the “Why” questions (why behave in such way).
History is the third approach. It studies the evolutionary history of a behavioral trait, usually by employing the comparative method, i.e., comparison of a number of related species, trying to discover if the behavior is common in all of them, in which case it is present due to the deep phylogenetic history, or of it most reliably varies with the type of environment the species lives in, suggesting that the behavior is a recent adaptation for a particular way of life.
Finally, the fourth approach is Function. It tests the hypothesis that the behavior in question increases the animal’s fitness, aids in survival and/or reproduction, and has evolved for that function – is it an adaptation.
Recently a fifth question has been added to this list. Animal cognition asks “Can animals think?” Here, careful use of some unusual (and quite controversial) methods, including anecdotes, introspection and anthropomorphism, aids in the development of testable hypotheses about the inner worlds of animals.
No other area of biology is as integrative as behavioral biology. It is possible for a biochemist to ignore ecology or for an ecologist to ignore biochemistry (though at the risk of performing irrelevant research), but a behavioral biologist cannot ignore any aspect of the biology of the species under study. This makes the study of behavior the glue that holds all of biology together. This makes behavioral biology difficult to do, as one needs to have strong background in many areas of biology, technical expertise in a broad range of laboratory and field techniques, and lots of time to follow up on the literature in a number of related fields.
Only a few – the best – behavioral biologists are capable of exploring every aspect of a behavior at all levels. Mostly, the problem is divided among a number of laboratories around the world, each researcher using a slightly different approach and different techniques. The laboratories then communicate with each other via formal channels – the publications in scientific journals – and via informal channels – conferences and personal communication (and more recently, on the Web). Thus, a big picture is slowly being built out of its smaller parts, each piece of research being informed by all other pieces of research.
Types of behaviors
Foraging behavior involves finding, catching, handling and ingesting food. It includes the formation and use of feeding territories, learning the hunting techniques, the physiology of hunger, as well as behavioral strategies for avoiding becoming prey.
Animal movement includes, most prominently, long-distance migration including the neural mechanisms of spatial orientation and navigation.
Communication is the ability of animals to communicate information to each other (within and between species) via several sensory channels (or modalities). Those modalities include vision (including infrared, ultraviolet and polarized light, as well as thermoreception), sound (including ultrasound, infrasound and substrate vibrations), chemical signals (smells, pheromones, taste), touch and electrical signals (as in electrical fish).
Reproductive behaviors encompass a broad range of behaviors. Mate-finding, male-male competition, mate-choice and courtship are behaviors involved in securing a mate. Mating behavior ensures fertilization. Nesting and parenting behaviors are meant to ensure the survival of the offspring.
Reproductive behaviors are important elements of evolutionary change. Many phenotypic traits are a result not of natural selection, but of sexual selection, where a trait is selected not by the physical environment but by potential mates. Traits favored by the individuals of the opposite sex tend to be more likely to be passed on to the next generation in that population. This leads to the evolution of exaggerated traits (e.g., the peacock’s tail) and to differences between sexes (e.g., in many bird species the male is brightly colored while the female looks drab).
Mate choice can, potentially, be involved in sympatric speciation, if different individuals in the population favor different traits in their mates, so the gene flow between the two groups gets progressively smaller with each generation. This kind of mating is called assortative mating (as opposed to random mating, where each individual is equally likely to mate with each individual of the opposite sex).
The most common types of mating systems are monogamy, polygyny, and polyandry. A good example of polygyny is the elephant seal in which only one male (after defeating all the other males in one-on-one fights) mates with all the females in his territory.
Polyandry is found only a little less often – one female mates with multiple males over the course of a breeding season, resulting in her offspring being of mixed paternity (i.e., different eggs were fertilized by different males). This has been studied mostly in frogs.
Monogamy is the rarest form of mating strategy in the animal kingdom. A distinction is made between social monogamy and sexual monogamy. Many animals that form breeding pairs, including most species of birds, are engaged in social monogamy – the male and the female build the nest together, mate and raise the chicks together. However, DNA fingerprinting has shown that a small proportion of the eggs is invariably fertilized by a different male – a fleshy neighbor who may not be a good “husband” and “father”, but whose size, bright colors or powerful song indicate other genetic qualities. Thus, some of the progeny of the same female will be fleshy sons, some will be “good husband” sons and some will be daughters – the female is hedging her bets about the production of grandoffspring.
Humans are not officially classified as monogamous animals – though human polygamy (both polygyny and polyandry) tends to be in the form of serial monogamy, i.e., sticking monogamously with one partner for a particular length of time, then changing the partner. Social norms have strongly opposed, but did not eradicate human non-monogamy. Increased life-span, invention of reliable contraception, and economic independence of women are making it more and more difficult to suppress the non-monogamous tendencies in humans, as seen from statistics for divorce (around 50%), re-marrying, and cheating (around 60% of both men and women) that have held quite steady over the past 50 years or so.
Social behaviors involve relationships between individuals of the same species. Some animals tend to live alone, each individual defending a territory, and a male and a female meeting only briefly during the mating season. Other animals tend to live in smaller or larger groups. Some animals change their social structure seasonally – for instance, European quail live in coveys (10-12 birds) during the winter), in huge flocks during spring and fall migrations, and in breeding pairs during summer.
Within groups, there is often a hierarchy of individuals – the so-called “pecking order”. The social hirearchy is established through aggression, often in form of ritualized displays. In many species, the ritualized aggressive behaviors are so-called “fixed-action patterns“, i.e., a strongly heritable order of particular movements. Mating behaviors are also often fixed-action patterns.
In some species, the mating fixed-action patterns are also used for aggressive encounters. In some cases, when a male mounts another male utilizing a typical mating pattern, this is actually a display of social dominance. However, in other species, a male mounting a male is actually homosexual behavior, evolved not to determine social hierarchy, but quite the opposite, to increase social coherence within the group (“making friends”). In pygmy chimps (bonobos), everyone in a troop mates with everyone else in the troop, regardless of gender. This makes the troop socially cohesive (which helps in group’s defense if attacked by another troop, predators or other enemies).
Previously in this series:
Biology and the Scientific Method
BIO101 – Cell Structure
BIO101 – Protein Synthesis: Transcription and Translation
BIO101: Cell-Cell Interactions
BIO101 – From One Cell To Two: Cell Division and DNA Replication
BIO101 – From Two Cells To Many: Cell Differentiation and Embryonic Development
BIO101 – From Genes To Traits: How Genotype Affects Phenotype
BIO101 – From Genes To Species: A Primer on Evolution