Tag Archives: Classification

Plant Divisions: Flowering Plants

Leaf Variety in Magnoliophyta

Leaf Variety in Magnoliophyta

Plants in the Magnoliophyta Division may also be called Angiosperms or flowering plants, they include grasses, palms, oak trees, orchids and daisies. Magnoliophyta is the only division that contains plants with true flowers and fruits, and all plants in this division use those flowers and fruits to reproduce. It is not known exactly when flowers first appeared, but definitely by 125mya and probably as far back as 160mya.

Flowers have proved to be an extremely successful adaptation, and despite its recent appearance, Magnoliophyta is by far the largest and most diverse plant division with over 250,000 different species and 500 families. (For comparisons to other divisions and their sizes see here)

Leaf Variety in Magnoliophyta

Leaf Variety in Magnoliophyta

Flowers

In Magnoliophyta, flowers replaced the cones of more primitive plants, as a means of reproduction. Some flowers are brightly coloured, have a scent or produce nectar in order to entice animals to pollinate them, but others use wind or water and, having no need to draw attention, are barely noticeable.

Flower Variety in Magnoliophyta

Flower Variety in Magnoliophyta

Flower Variety in Magnoliophyta

Flower Variety in Magnoliophyta

Fruit and what that really means…

All plants in this Division produce fruits of some kind, even though what they produce may not be easily recognised as fruit. The botanical definition of a fruit is a matured ovary (the ovary is the female part of the flower that contains the ovules which become the seeds once fertilised), this includes peppers, tomatoes, aubergines, nuts, peas, wheat grains, but not apples or rhubarb. There is another meaning for the word fruit, which is culinary and refers to a sweet part of a plant that is eaten, this is the more familiar term and includes rhubarb and apples, but not tomatoes and nuts, etc. ‘Vegetable’ is only a culinary term, referring to parts of a plant used in savoury cooking, it may refer to any part of the plant: leaves (lettuce) flower buds (broccoli), stems (celery) or roots (carrots) and has no botanical equivalent.

Classification

Being such a large and interesting division means that the classification of Magnoliophyta has received more attention and undergone more changes than any other division.

How Many Flowering Plants Are There?

It was believed for some time that there were over 400,000 flowering plants, but it turns out that many species of plant (not known as yet how many) have actually been named twice or even three or four times. The binominal naming system (using two Latin names, eg Helianthus annuus) was designed to make plant naming international and straightforward, but with people all over the world discovering and naming plants and no comprehensive way of cross referencing them, we have ended up with a lot of confusion. Now, partly due to the international power of the internet, serious attempts are being made to work out how many actual species there are and to remove duplications. The Plant List is a collaboration between a number of botanical gardens around the world and has an impressive online collection of these names.

DNA Alters The Family Tree – Cronquist to APG III

Before DNA testing was possible (or DNA was known about) plants were collected into families, classes and orders according to detailed studies of how they looked.

Over the past few hundred years there have been many different classification systems, but one of the most commonly used and straightforward was the Cronquist System, devised in 1968. This System grouped plants into families, with the families grouped into orders, orders then grouped into sub classes and sub classes grouped into two classes: monocotyledons and dicotyledons. However, with genetic testing, it has been found that many of these groupings were wrong. A new system, called APG (Angiosperm Phylogeny Group), was introduced in 1998, but has subsequently been updated twice since then and will no doubt change in the future.

Frustratingly, what was once a very neat and straightforward system of classification has become an unwieldy, confused and messy system, because nature is never neat. The new system, called APG III, does not use classes and subclasses, instead it groups orders within clades, nested within other clades, nested within other clades; with some families not fitting into any clade at all.

The following diagrams are an attempt to show the changes in a simple manner, using images of plants to represent different orders and showing how those orders have altered their connection to others. It is clear that some assumptions were completely wrong, for example some dicots are more closely related to monocots than other dicots; the buttercup is not kindred with the water lily; cacti are more connected to Heuchera than originally thought and oak trees are closer to Euphorbia than London planes.

Cronquist system

Cronquist system

APG III System

APG III System

Key to Magnoliophyta plants

Key to Magnoliophyta plants

Note: I was unable to take photos of a tulip tree or Rhododendron in flower, so used photos I got online from here: Rhododendron and tulip tree

 

It was also fairly tricky to find all the necessary information about where plants appear in the Cronquist system, if anyone spots any faults, please contact me at the email to the right. Most of my information came from Wikipedia, and from here

To enlarge the key click the thumbnail

Anthurium and Ctenanthe - two flowering plants

Anthurium and Ctenanthe – two flowering plants

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Kingdom

The Four Kingdom System

There are four kingdoms found in the Eukaryota Domain, they are Fungi, Plantae, Animalia and Protista. Plants and animals are familiar to most people, although there are specific criteria for each that may not be so familiar and a few very odd exceptions. Fungi were once included with plants, but are now known to be very different, and in some ways more similar to animals. Protista is a bit of a hodge podge as kingdoms go, it is unlikely to last much longer as one kingdom, and indeed many scientists have already rejected it because it doesn’t make much sense in evolutionary terms, however, the reordering is still in flux, so I will include Protista as one kingdom.

A clear to understand website about the Protista Kingdom and one from which I got the photo of Giardia lamblia below. http://www.uic.edu/classes/bios/bios104/mike/bacteria01.htm

A website that talks about a possible Seven Kingdom system http://www.fossilmuseum.net/Tree_of_Life/Domain_Eukaryota.htm

Animal

Drosophila

Drosophila

What makes an animal, an animal? Animals are heterotrophs, they cannot make their own food. They can move, are multicellular and reproduce sexually.

Evolutionary history: The earliest animal fossils that have been found are from sponges, dated 665mya, however, animals may have originated 1000mya. Most animals appeared around 542mya and relations of millipedes are the first animals proved to have made it on land 428mya.

Common examples: Crabs, coral, flies, birds and humans.010 (2)

Number of phyla and species: 35 phyla, this includes 13 phyla for different worm-like creatures. The most familiar phyla are:

  • Chordata  – contains mammals, but also fish and reptiles, about 60,000 species
  • Arthropoda  – thought to contain 80% of all living animal species, includes insects, spiders and crustaceans. About a million species have been named, but there are many times that number not yet discovered or classified.

In total it is believed there are between 3 and 30 million species of animal.

LizardHabitats: Polar to desert, temperate to tropical, oceans to mountains.

 

Animal Cell

Animal Cell

Cellular and structural description: Animal cells do not have cell walls or chloroplasts and are often a round shape. Animals contain tissues and organs of a complex nature, for example the tympanal organ for hearing in insects and brain tissue in humans.

Abilities and behaviour: Most animals move at some point in their life-cycle, they breathe out carbon dioxide and breathe in oxygen. They eat food for energy – fungi, plants, bacteria, other animals. Most reproduce using sperm and an egg, although some animals are hermaphrodite or reproduce asexually.

Some exceptional animals: Coral are colonies of genetically identical animals that don’t move. Sponges also don’t move and lack true tissues or organs. Green sea slugs use chloroplasts from algae they eat to then photosynthesize like plants. One species of hornet, Vespa orientalis, may derive energy from the sun. (For some other unusual animals see the Odds and Ends of Nature tab)

Plant

Snowberry

What makes a plant, a plant? Plants are autotrophs, producers, they make food (carbohydrate), by photosynthesis. Plants can’t usually move and their reaction to their environment is slow. They are multicellular and have complex organs and tissues.

Evolutionary history: Although plants originated in the sea, unlike animals and fungi, they did not evolve much there. Green algae (a primitive prototype plant and member of the Protist Kingdom) lived in the sea, but in order to make the move to land, where they could access more sunlight for photosynthesis, they needed to adapt to different, drier conditions. The first plant to grow on land was the now extinct Cooksonia (433-393mya), it had a waxy cuticle to stop the leaves drying out and roots to anchor it to the ground and absorb water. From Cooksonia evolved mosses, liverworts and hornworts (475mya), plants with a very basic ability to transport water. Ferns, followed by conifers and finally all flowering plants, evolved later.

SunflowerCommon examples: Sycamore tree, fern, sunflower, moss and box hedge.

Number of phyla and species: 10 divisions, 270,000 species.

  • Anthocerotophyta – hornworts
  • Marchantiophyta – liverworts
  • Bryophyta – mosses
  • Lycopodiophyta – club and spike-mosses
  • Pteridophyta – ferns and horsetails
  • Gnetophyta – 3 extant genera of woody plants
  • Cycadophyta – cycads
  • Ginkgophyta – Ginkgo
  • Pinophyta/Coniferophyta – conifers
  • Magnoliophyta – flowering plants

More on Divisions and plant evolutionary history in future blogs.

Habitats: Diverse, just about anywhere with air and sunlight.

 

Plant Cell

Plant Cell

Cellular and structural description: Plants cells have cell walls made of cellulose and chloroplasts. They have a very rudimentary circulatory system and the ability to sense their environment, but only simply – they can detect sunlight, but not see images, they can react to touch but it is mostly a slow process. They have organs and tissues, for example, the leaf is an organ and on its surface is photosynthetic tissue.

Abilities and behaviour: Plants are generally rooted in one place and do not move on their own, however they can grow in response to their environment. They give off oxygen and take in carbon dioxide through photosynthesis, a process which uses sunlight to make carbohydrate, which is then broken down by the plant for energy, however it is often consumed by fungi or animals instead. Plants reproduce sexually by fusing egg and sperm, but being unable to move they need different methods to transport the sperm to where the egg is, for example using wind or insects.

Some exceptional plants: Mimosa pudica can move, responding instantly to touch by collapsing its leaves against the stem, this is a defensive measure that hides the leaves from animals that might eat them. Ivy broom rape does not photosynthesize, but parasitizes ivy, growing from its roots in a similar manner to fungi. Some plants trap insects and digest them for nutrients, but not for energy in the way that animals do, these plants often move also, for example Venus Fly Trap. The Socratea exorrhiza is a tree described as being able to walk, but this is not walking in the way an animal would; it involves having above ground roots that move towards the sunlight by growing more roots on one side and allowing those on the shady side of the plant to die, so that in time the plant shifts both over- and underground.

Fungi

Fungus

Fungus

What makes fungi, fungi? Fungi are heterotrophs, decomposers that cannot make food so they grow on living or dead organisms, breaking them down.

Evolutionary history: The first fungi were in the sea probably dating from 760-1060mya, fungi colonised the land long before animals or plants, probably 542-488mya.

Common examples: Athlete’s foot, coral spot (bright orange dots sometimes seen on leaves), white mushrooms, truffles, penicillin, bread mould.

 

 

Number of phyla and species: 6 phyla (although a seventh has been proposed). They are:

  • Chytridiomycota
  • Zygomycota
  • Ascomycota
  • Basidiomycota
  • Glomeromycota
  • Blastocladiomycota

10,000 species of fungus have been described, but there are thought to be at least a million. Fungi are more varied in the tropics than in areas closer to the North or South pole. For example in Britain and Ireland fungi outnumber plants 6:1, in Southeast Asia the ratio is 33:1.

Habitats: Fungi need plants, animals or other fungi to grow on or with. Most live on land, but a few live in water. Plenty live inside other organisms.

 

Fungal Cell

Fungal Cell

Cellular and structural description: Fungi have cell walls like plants, but made of chitin, the substance found in the hard exoskeletons of insects, rather than cellulose. The main part of a fungus is the mycelium, small threads that attach to other organisms to obtain food, these mycelium can grow for several km. Most fungi produce fruiting bodies these are what we think of as mushrooms, but are only a fraction of the actual fungus. Fungi have a simpler structure than plants or animals, but the fruiting body is an organ and it is made of tissue.

Abilities and behaviour: Fungi cannot photosynthesize and must consume food, they do this by attaching to other organisms (plants, animals or other fungi) by filaments and then take food from their host – sometimes this is a parasitic relationship, sometimes symbiotic (mutually beneficial, eg the fungi provides a means of extracting nutrients from the soil for its host plant) and sometimes saprophytic (consuming dead material, this is an essential part of the process whereby dead organisms break down, without these fungi the planet would be filled with dead bodies.)

Xanthoria Lichen

Xanthoria Lichen

Some exceptional fungi: Lichens are composite organisms, made up of fungi and algae working together. The alga can photosynthesize and so provides food for the fungus and the fungus protects the alga from desiccation in harsh environments. Lichens can grow in environments that neither algae or fungi could survive in alone. Along with bryophytes, lichens were probably some of the first organisms on land. Some lichens also contain Cyanobacteria (a bacteria).

Protist

Giardia lamblia

Giardia lamblia

What makes a protist, a protist? Essentially any organism that cannot be classified as a fungi, plant, animal, bacteria or archaea is classified as a protist, most protists are prototype fungi, plants and animals.

Evolutionary history: Algae were probably the first protists to appear, 1600-1700mya.

Common examples: Kelp, amoebas (Protozoa), seaweed, algae, the cause of malaria and sleeping sickness (NB: cyanobacteria are sometimes referred to as blue-green algae, but they are in the

Protozoa

Protozoa

Bacteria Domain), slime molds, diatoms (type of  algae). Volvox is a genus of single celled protists that live in colonies (see Odds and Ends of Nature tab for more about these and slime molds).

Number of phyla and species: 200,000 species. Usually ten phyla, although these often change.

Habitats: Protists live mostly in wet places, the sea, a damp corner, or an animal intestine.

Algae

Algae

Cellular and Structural description: Most are unicellular and invisibleto the naked eye. They are more complex than bacteria and have their nuclei wrapped in a membrane, but simpler than other eukaryotes having no specialised tissues, they do, however, have organelles in their cells such as mitochondria and chloroplasts.

Abilities and behaviour: Some protists are autotrophs, some are heterotrophs, some photosynthesize and expire oxygen, others consume and breathe in oxygen. The protists that move do so by a number of means such as pseudopodia or flagella.  Most Protists reproduce asexually, a few reproduce sexually and some alternate between the two.

Some exceptional protists: All protists are exceptions really.

Note: I recently received an email from someone helpfully pointing out that cells have only one Golgi apparatus, rather than the several that I had drawn. I have since altered these diagrams, sorry for the misinformation and thank you to the informer.