The latest re-post of my BIO101 lecture notes (this one originally from June 05, 2006). I know I will have to rewrite everything about theThree Domain Hypothesis, but you also tell me if I got other stuff wrong or if this can be in some way improved for the classroom use.

---------------------------------------------
BIO101 - Bora Zivkovic - Lecture 4, Part 3

In the first two parts of this lecture we tackled the Origin of Life and Biological Diversity and the mechanisms of the Evolution of Biological Diversity. Now, we'll take a look at what those mechanisms have produced so far - the current state of diversity on our planet.

The Three Domains

The organisms living on Earth today are broadly divided into three large domains: Bacteria, Archaea and Eukarya (Protista, Plants, Fungi and Animals). Our understanding of the relationship between the three domains is undergoing big changes right now. The old divisions have been based on morphological and biochemical differences, but recent genetic data are forcing us to rethink and revise the way we think about the three Domains.

It was thought before that Bacteria arose first, that Archaea evolved from a branch off of bacterial line, while the first Eukarya (protists) evolved through the process of endosymbiosis: small bacteria and archaea finding permanent homes within the cell of larger bacteria and forming organelles. It was thought that bacteria were always simple, that Archaea are somewhet more complex, and that Eukarya are the most complex.

Neither Bacteria nor Archaea possess any organelles or subcellular compartments. The chemistry of cell walls is strikingly different between the two groups. The genes of Archaea, like Eukaryia, have introns. Until recently, it was thought that bacterial genes have no introns, however remnants of bacterial introns have been recently discovered, suggesting that Bacteria used to have introns in the past but have secondarily lost them - becoming simpler over the 3.6 billions of evolution. The enzymes involved in transcription of DNA in Archaea are much more similar to the equivalent enzymes in Eukarya than those in Bacteria.

Molecular data, as well as what we know from evolutionary theory how population size affects the strength of natural selection, a new picture has emerged. The earliest Bacteria were simple, hugging the Left Wall of Complexity. While their population sizes were still small, Bacteria evolved greater and greater complexity, leaving the left wall somewhat, evolving more complex genomes, more complex mechanisms of DNA transcription (including introns), and perhaps even some organelles. Likewise, the Archaea split off of Bacteria (or perhaps they even appeared first) and evolved much greater complexity in parallel with the Bacteria. Eukarya also split off of Bacterial tree early on and evolved its own complexity. Thus there were three groups simultaneously evolving greater and greater complexity.

Then, Bacteria and Archaea grew up in population sizes. Instead of small pockets somewhere in the ocean, now bacteria and archaea occupied every spot on Earth in huge numbers. Large population size makes natural selection very strong. Greater complexity is not fit, thus it is selected against. Thus, the originally complex bacteria and archaea became simpler over time - they turned into lean, mean evolving machines that we see today - the dominant life forms on our planet throughout its history. They lost introns, they lost organelles, and lost many complicated enzymatic pathways, each species reducing its genome and strongly specializing for one particular niche.

On the other hand, Eukarya did not grow in numbers as much. The population sizes remained small, thus the selection against complexity was relaxed - the eukaryotes were free to evolve away from the Left Wall. They increased in complexity, engulfing other microorganisms that later became mitochondria and chloroplasts.

Thus, though we, for egocentric reasons, like to think of greater complexity as being better than being simple, the Big Story of the evolution of life on Earth is that of simplification. Natural selection harshly eliminated organisms that experimented with greater complexity - the Eukarya being the exception: an evolutionary accident that happened due to their existence in small, isolated populations in which selection against complexity is relaxed.

Bacteria

Bacteria are small, single-celled organisms with no internal structures or organelles. Bacteria may have cell walls on the surface of their cell membranes, and may have evolved cilia or flagella for locomotion. The DNA is usually organized in a single circular chromosome. Some bacteria congregate into collonies or chains, while in other species each cell lives on its own.

In the laboratory, bacteria can be easily separated into two major groups by the way their cell walls get stained by a particular stain into Gram positive (purple stain) and Gram negative (red stain) bacteria. By shape, bacteria are divided into cocci (spherical cells), bacilli (rod-like shapes) and spirilli (thread-like or worm-like cells).

Bacteria are capable of sensing their environment and responding to it - i.e., they are capable of exhibiting behavior. Bacteria are also capable of communicating with each other - for instance, they can sense how many of them are present in a particular place and they can all change their behavior once the poulation size reaches a sertain treshold - this kind of sensing is called quorum sensing.

Many bacteria are serious pathogens of plants and animals (including humans). Others are important decomposers of dead plants and animals, thus playing important roles in the ecology of the planet. Yet others are symbionts - living in mutualistic relationships with other organisms, e.g., with plants and animals.

The inside of out digestive tract provides a home for numerous microorganisms. The best way to think about out "intestinal flora" is in terms of an ecosystem. We acquire it at the moment of birth and build it up with the bacteria we get from the environment - mostly from our parents. The bacterial populations in the intestine go through stages of building an ecosystem, similarly to the secondary succession. If, due to disease or due to use of potent antibiotics, the balance of the ecosystem is disrupted, it may recover through phases akin to primary succession.

Experiments with completely internally sterile animals (mostly pigs and rabbits) demonstrated that we rely on our intestinal bacteria for some of our normal functions, e.g., digestion of some food components, including vitamins. In many ways, after millions of years of evolution, our internal bacteria have become an essential part of who we are, and there is now a push for sequencing the complete genome of our becterial flora and to include that information in the Human Genome. The composition of the bacterial ecosystem in out guts can affect the way we respond to disease, or even if we are going to get fat or not, thus there is much recent research on individual variation of the intestinal flora between human individuals, so-called "poo print" (yes, scientists do have a sense of humor).

Archaea

Archaea may have been the first life forms on the Earth. Today, they tend to occupy niches that no other organisms can. Thus, they are found living inside the rocks miles under the surface, they are found in extremely cold and extremely hot environments, in very salty, very acidic and very alkaline envrionments as well. The hot water of the Old Faithful geiser in Yellowstone national park are inhabited by a species of Archaea. They are difficult to study as they die in normal conditions in the laboratory - room temperature, neutral pH etc.

Deinococcus radiodurans is one famous Archean. It thrives inside nuclear reactors. Of course, our reactors are a very recent innovations, so the scientists were puzzled for a long time as to what natural environment selected these organisms to be able to survive in such a harsh environment. It turns out that dehydration (drying-out) has the same effects on the DNA as does radioactivity - fragmenting and tearing-up of pieces of the DNA molecule. Deinococcus evolved especially fast and accurate mechanisms for DNA repair. Bioengineering projects are underway to genetically engineer these Archaea in such a way that they can be used to clean up radioactive spills and digest nuclear waste.

Though some Archaea have been found to live inside our bodies, not a single one has, so far, been indentified as a pathogen. Only very recently (i.e., last few weeks) has it been shown that one archaean does have an effect on our health - not as a pathogen but as an enabler. It can migrate into roots of our teeth and set up colonies there. It then changes the environment in the tooth in such a way that it becomes conducive to the immigration and reproduction of a pathogenic bacterium than can then attack the tooth.

Protista

Protists are an artificial group of organisms - every eukaryote that cannot be classified as a plant, a fungus or an animal is placed in this category. Thus, the number of species of protists is very large and the diversity of shapes, sizes and types of metabolism is enormous.

Some protists are microscopic unicellular organisms, like the Silver Slipper (Paramecium), while others are multicellular and quite large (e.g, sea kelp). Some protists, e.g., cellular slime molds, have a single-celled and a multi-celled phase of their life-cycle.

Even some of the unicellular protists can be quite large - an Acetabularia ('mermaid's wineglass', see picture) cell is about 5 cm long, thus perfectly visible to the human eye. Most protists reproduce regularly by asexual processes, e.g., fission or budding, utilizing sexual reproduction (e.g., conjugation, which is gene-swapping) only in times of stress. Some protists are surrounded only by a plasma membrane, while some others form shells of silica (glass) around themselves. Some protists have flagella or cilia, while some others move by pseudopodia (false legs - ameboid movement).

Traditionally, protists have been artificially subdivided into three basic groups according to their metabolism: protists capable of photosynthesis (autotrophs) are called Algae, heterotrophs are called Protozoa, while the absorbers are Fungus-like protists. According to morphology, protists have been divided into about 15 phyla, grouped into six major groups. New molecular techniques are thoroughly changing the taxonomy and systematics of Protista. One group, the Green Algae, has recently been moved out of Protista and into the Kingdom Plantae. Another group, the Choanoflaggelata, has been moved to the Kingdom Animalia as they are most closely related to sponges.

Some protists are parasites that cause human diseases. Most well-known of those are Plasmodium (malaria), various species of Trypanosoma (sleeping sickness, leischmaniasis and Chagas Disease) and Giardia (Hiker's Diarrhea). Dinoflagellates live on the surface of the ocean and are almost as important for absorption of CO2 and production of O2 as are forests on land.