Animalia: the Cambrian Explosion

The Invertebrates

Animalia: The Cambrian Explosion

Number of organisms in the fossil record is increasing

New groups were evolving fast

Bodies were larger

Skeletons and hard parts like shells

Specialized cells also appeared

Different groups of cells became specialized

As animals evolved they became more complex

Specialized cells organized into tissues

Tissues organized to form organs

Organ evolved into organ systems

Animalia: Invertebrates

Animals without a backbone

Many, many invertebrate phyla

Three trends in Invertebrate evolution

Germ layers, Coelom, Segmentation

Invertebrates: Three germ layers

Common ancestors of multicellular animals evolved two distinct cell layers: an ectoderm layer (outside) and an endoderm layer (inside)

Sponges and some jellyfish have these two only

Other jellyfish and all other animals have a middle layer, mesoderm, that develops into muscles and skeletons

Invertebrates: Coelom

The existence of a mesoderm lined cavity inside the body. This is space for organs to grow without being affected by the movement of the body

Look at diagram on page 738 and 741

Invertebrates: Body plan built from segmentation

Body is compartmentalized in segments

Allow increases in size with minimal new genetic information (just repeat what you have)

Segments can be specialized for specific functions

Look at the diagrams on page 738 and 741

Invertebrates: Body plan symmetry

Look at the diagrams on page 738 and 741

Some invertebrates have no symmetry

Some have radial symmetry (body parts repeat around an imaginary line drawn through the center of the body)

Some have bilateral symmetry (animals have identical right and left sides, fronts and backs, upper and lower sides)

Invertebrates: Habitats

Life in fresh water, salt water and on land;

Some live part of their life in water another part on land and vice versa

Survey: 9 phyla of invertebrates

Porifera (sponges)

Simplest of all invertebrates; no symmetry

Cnidaria (jellyfish, sea anemones, hydra)

Mostly salt water, some fresh water, radial symmetry

Platyhelminthes (flatworms)

Simplest animal with bilateral symmetry

Many are parasites

Nematoda (roundworms)

Fist to show a tube like digestive system

Range in size from microscopic to more than a meter long

Mollusca (mollusks, clams, snails, squids)

Most are salt water, some fresh water

Most have shells; octopus (8 tentacles) and squids (10 tentacles) have no shells

Annelida (segmented worms, earthworms)

Live on land and in water

Echinodermata (star fish, sea cucumbers, sea urchins)

Show five-part radial symmetry

Arthropoda (spiders, crustaceans, insects)

THE most successful of all the animals

Jointed appendages and exoskeleton

Lobsters, shrimps and crabs

Invertebrate chordates (sea squirts)

Link between invertebrates and vertebrates

Endoskeleton with a notochord

Invertebrate physiology: Skeletons

Three kinds of skeletons are seen in Invertebrates

Hydrostatic

Muscles surround and are supported by a water filled cavity

No hard structures for muscles to pull against

Diagram on page 814

Exoskeleton

External skeleton, muscles are attached to the inside

Arthropods are the best examples

Made of the carbohydrate chitin (remember from fungus)

All exoskeletons are thin a flexible at the joints

Advantage: very adaptable, very strong

Disadvantage: in order to grow the anima has to molt

Endoskeleton

Located inside the body

Present in sponges and echinoderms

Vertebrate are the best examples

Invertebrate physiology: Digestion

Two strategies:

Digestion inside cells and digestion outside cells

Diagrams on page 784

Inside cells:

1) Intracellular digestion

In sponges, cells filter particles of food in the water, digestion occurs inside the cell, digested products transported to other cells

2) Gastovascular cavity digestion (seen in cnidarians and flatworms)

Food goes into a digestive cavity with only one opening to the outside, food broken down in the cavity, smallest particles taken into the cell, waste eliminated through the opening

Outside cells:

1)Tube within a tube plan, food enters a mouth and exits an anus

Food is digested inside this digestive tract; digested food is adsorbed into the cells

Invertebrate physiology: Internal transport

Two kinds of circulatory systems

1) Open circulatory system

2) Closed circulatory system

Open circulatory system

Blood form the heart is not contained inside blood vessels

Example: insects (page 791)

Blood contacts all the tissues of the body

Closed circulatory system

Blood is contained in a system of closed vessels that pass through various parts of the body and return to the heart

Example: earthworms (diagram on page 792)

Provides more rapid and efficient control of blood flow

Invertebrate physiology: Respiration

Two physiology problems:

1)Surface area needs to be large enough so that gas exchange by diffusion is adequate to support the animal

2)Gas exchange surfaces must be kept wet because gas exchange happens by diffusion only across wet membranes

Diagrams on page 788-790

Adaptations

Worms respire through their skin

Crustaceans have gills

Spiders have book lungs

Insects have trachea (tubes that carry oxygen to each cell)

Invertebrate physiology: Excretion

Purpose is elimination of toxic waste

Closely related to control of water loss

Breakdown of amino acids produces ammonia, which is water-soluble

Elimination of ammonia means losing water

Salt-water animals eliminate ammonia by diffusion into the water

Freshwater flatworms have specialized cells Flame Cells to remove excess water (why??, remember osmosis) and ammonia

Annelids, mollusks, invertebrate chordates have specialized organs to remove ammonia from water, eliminate the ammonia in urine and return most of the water to the organism

Land invertebrates convert ammonia to urea, which can be made more concentrated than ammonia, but is still soluble in water

Insects and some spiders convert ammonia into uric acid, which is removed by organs called Malpighian tubules. Uric acid is excreted as a solid waste. This system conserves the most water.

Invertebrate physiology: Response

Specialized cells for response to the environment are called nerve cells

No matter what the animal, nerve cells look and function pretty much the same

Primitive invertebrate have nets of nerves distributed throughout the body

Some jellyfishes show Centralization where nerve cells are concentrated into a system around certain organs like the mouth

Clumps of nerve cells are called ganglia. Ganglia located near the head result in cephalization, gathering nerve cells in the front of the organism where the animal first senses its environment.

Insects and mollusks show development of ganglia into brains

Nervous system development coincides with the development of specialized sensory cells like eyes.

Invertebrate physiology: Reproduction

All invertebrate are capable of sexual reproduction

Creates and helps maintain genetic diversity