Dichotomous Keys and the Five Kingdoms

Feb 12 (Dichotomous Keys)

Feb 12(The Five Kingdoms)

Learning Objectives 

  • Use and create a dichotomous key
  • Compare and contrast the characteristics of the five kingdoms
    • Compare and contrast prokaryotes and eukaryotes 
    • Identify the characteristics that differentiates the kingdoms from each other

What is a Dichotomous Key? 

  • A step-by-step key used to identify an organism, usually a plant or animal.
  • Each step presents descriptions of two distinguishing characters with a direction to another stage in the key until the species is identified

Using a dichotomous key is actually quite simple.

  1. Start with the organism you want to identify
  2. Start with number 1 on the key
  3. Identify whether the organism has the characteristic in number one and follow the instructions to a) identify the organism or b) follow the directions and move to the next number.
  4. Continue until you arrive at the species.

Woodpeckers Dichotomous Key

An example of a dichotomous key for the woodpeckers above may look something like this

  1. Is the bird tan-coloured? 
    1. Yes …. Go to number 2
    2. No ….. Go to number 3
  2. Does the bird have a red spot on its head? 
    1. Yes… Northern flicker
    2. No … Gilded flicker
  3. Does the bird have white wing bars? 
    1. Yes … Go to number 4
    2. No …. Williamson’s sapsucker
  4. Does the bird have black bars behind its eyes? 
    1. Yes … Red-naped sapsucker
    2. No …. Red breasted sapsucker

The Five Kingdoms 

The five kingdoms system separates all life on Earth into five categories:

Kingdom Characteristics Energy Source
Monerans Prokaryotic

Unicellular

Heterotrophic

Autotrophic

Chemotrophic

Protista The “miscellaneous pile”

Unicellular

Eukaryotic

Have characteristics of fungi, plants and animals

Heterotrophic

Autotrophic

And both

Fungi Eukaryotic

Generally made of hyphae (thin strands of cells)

Cell walls are made of chitin

Heterotrophic
Plantae Eukaryotic

Multicellular

Cell walls out of cellulose

Have chloroplasts

Autotrophic
Animalia Eukaryotic

Multicellular

No cell walls or chloroplasts

Heterotrophic

Prokaryotes: are organisms whose cells lack a nucleus and other organelles. They are generally much smaller than eukaryotic cells.
Eukaryotes: are organisms whose cells contain a nucleus and other organelles.

Autotrophic: organisms which are able to obtain their food from inorganic sources such as light and chemicals
Heterotrophic: organisms which obtain their food from organic sources

Inorganic Substances: Non-living substances
Organic Substances: Substances that is derived from something that was or is alive.

Linnaean Taxonomy

PowerpointFeb 11

“Chaos is reality, order is illusion” – what every taxonomist knows, but hates to admit.

Learning objectives

  • Use binomial nomenclature to identify organisms
  • List the kingdom, phylum (sub-phylum), class, order, family, genus and species
  • Identify the characteristics of a good classification system
  • Identify the criteria (evolutionary relationships) that are used to classify organisms
  • Explain why we use these criteria vs. others, in other words, why don’t we use criteria like morphology and habitat?

Taxonomy is the branch of science concerned with the description, identification, naming and classification of organisms.

The purpose of taxonomy is to produce a system that helps scientists and people to better organize, understand and make sense of the living world. Having such a system also allows scientists to have a common language to communicate with each other. In order to produce such a system, the ideal system must have a few characteristics:

  1. Specific – the system should be as specific as possible. For example, talking to another scientist about Canis familiaris is far more specific than saying “that adorable, furry, four legged animal smaller than a wolf that lives with humans”.
  2. Clear and objective as possible – the criteria for grouping organisms should be based on criteria that are as objective and clear-cut as possible. For example, we may have a group for flying animals and furry land animals, both of which a bat might fall into. Or, we may have a group for “worm-like” creatures and “insects”, which a caterpillar and butterfly would fall into, even though these are of the same species.
  3. Descriptive – a good classification system should also be descriptive. Based on what group the organism falls into, I should have a good idea the “type” of organism I am thinking of. For example, if we are talking about “flying” creatures, I may immediately envision wings and feathers.

Early efforts to classify tried to incorporate these three characteristics by describing the organisms in as much detail as possible. For example, the Hoary plantain (Plantago media) was named:

“Plantain with pubescent ovate-lanceolate leaves, a cylindric spike and a terete scape”

And this was not the longest of names; some names reached twenty Latin words or more! You can imagine just how cumbersome it was to have organisms with such lengthy names. Not only that, with new organisms being discovered all the time, organism names will have to be even more detailed to differentiate them!

Carolus Linnaeus (1707-78), a Swedish taxonomist, knew right away that this system was definitely not going to work at this rate. To circumvent the impending problems, he invented the system we use today, known as binomial nomenclature and taxa.

Instead of giving every organism a very lengthy descriptive name, each organism was grouped into seven hierarchial groups:

Kingdom

Phylum (sub-phylum)

Class

Order

Family

Genus

Species

The organism’s names were reduced to two words: genus and species. According to convention, the groups are always italicized, with the genus capitalized, followed by the species name:

Homo sapiens

This new system is much less cumbersome. It is specific since all organisms have a unique name and grouping. It is also descriptive, since each of the levels says something about the organism’s characteristics. For example, the cat:

Kingdom Animalia – multicellular, mobile organisms

Phlyum Chordata – has a hollow nerve cord on the back (dorsal side) of the animal

Class Mammalia – has fur and mammary glands and gives birth to live young

Order Carnivora – organisms that mainly feed on meat

Family Felidae – cat like creatures, including lions, tigers, panthers, etc.

Genus Felis – small cat like creatures, including wild cats and domesticated cats

Species Catus – family cat

Finally, the system is made as clear and objective as possible by using evolutionary relationships as the basis for classification. Although during Linnaeus’ time, the theory of evolution was not to come for another 100 years, Linnaeus was able to infer that some organisms were more related than others. For example, even though a butterfly and a bird both have wings, the two organisms are clearly different.

Today, we infer evolutionary relationships based on three factors:

  1. Homologous structures – “parts of different organisms, often quite dissimilar that developed from the same ancestral parts”. Homologous structures are a product of adaptive radiation, or divergent evolution. An example of this is the forearm of bats, birds, reptiles and mammals. The bones in the arm are derived from a common ancestor.
    1. Note: it can be tricky to differentiate homologous structures from analogous structures, which are products of convergent evolution. For example, the fins of a shark and dolphin
  2. Biochemical relationships – are chemicals that are vital to living organisms. Many of the chemical substances, the ones that are not ingested are produced from the DNA. Therefore, a difference in these chemicals suggests a difference in the DNA of the organism. And since organisms that are more distantly related tend to have DNA codes that are more different (from mutations that have accumulated over time), we can infer how closely related organisms are based on the differences in the chemicals.
  3. Embryological Relationships – the same applies to embryological relationships. Just like similarities and differences can be accumulated over time, so can differences in embryological development. In the early stages of fish, turtles, chick, pigs, mouse and human development, the embryos look very similar which suggests that similar genes are being expressed. But as more genes are being expressed, more and more differences begin to surface. This suggests that all these organisms once shared a common ancestor.

Tree of life explorer (find your closest common ancestor to an organism here!): https://www.evogeneao.com/explore/tree-of-life-explorer

 

Introduction to Taxonomy

Below is a file with pictures of many different organisms. Try to organize them into groups anyway that you see fit.

As you are arranging your organisms, keep a record of:

  1. Your groupings and the criteria for the grouping
  2. Keep a record of any problems or questions you faced while grouping

Organism Pictures Inquiry

 

Upload your pictures here (Please put your name(s) next to your picture) and how you grouped the organisms.

https://docs.google.com/document/d/1YgG3SvWwxALDMzdOA9faHjSLif9ePv69zXW_pgq3eXo/edit?usp=sharing