Paleozoic Life History: Invertebrates - PowerPoint PPT Presentation

1 / 137
About This Presentation

Paleozoic Life History: Invertebrates


Chapter 12 Paleozoic Life History: Invertebrates ... – PowerPoint PPT presentation

Number of Views:155
Avg rating:3.0/5.0
Slides: 138
Provided by: hartnellE
Learn more at:


Transcript and Presenter's Notes

Title: Paleozoic Life History: Invertebrates

Chapter 12
Paleozoic Life History Invertebrates
Burgess Shale
  • Diorama of the environment and biota
  • of the Phyllopod bed of the Burgess Shale,
  • British Columbia, Canada

Burgess Shale Soft-Bodied Fossils
  • On August 30 and 31, 1909,
  • Charles D. Walcott,
  • geologist and head of the Smithsonian
  • discovered the first soft-bodied fossils
  • from the Burgess Shale,
  • a discovery of immense importance in deciphering
    the early history of life
  • Walcott and his collecting party split open
    numerous blocks of shale,
  • many of which yielded the impressions
  • of a number of soft-bodied organisms
  • beautifully preserved on bedding planes

Thousands of Fossil Specimens
  • Walcott returned to the site the following summer
  • and located the shale stratum
  • that was the source of his fossil-bearing rocks
  • in the steep slope above the trail
  • He quarried the site
  • and shipped back
  • thousands of fossil specimens
  • to the United States National Museum of Natural
  • where he later catalogued and studied them

More Complete Picture of a Middle Cambrian
  • The importance of Walcott's discovery
  • is that it allowed geologists a rare glimpse into
    a world previously almost unknown
  • that of the soft-bodied animals that lived some
    530 million years ago
  • The beautifully preserved fossils
  • from the Burgess Shale
  • present a much more complete picture
  • of a Middle Cambrian community
  • than deposits containing only fossils of the hard
    parts of organisms

Sixty Percent Soft-Bodied
  • In fact, 60 of the total fossil assemblage
  • of more than 100 genera is composed of
    soft-bodied animals,
  • a percentage comparable to present-day marine
  • What conditions led to the remarkable
    preservation of the Burgess Shale fauna?
  • The site of deposition of the Burgess Shale
  • was located at the base of a steep submarine

Reason for the Preservation
  • The animals
  • whose exquisitely preserved fossil remains
  • are found in the Burgess Shale
  • lived in and on mud banks
  • that formed along the top of this escarpment
  • Periodically, this unstable area
  • would slump and slide down the escarpment
  • as a turbidity current
  • At the base, the mud and animals carried with it
  • were deposited in a deep-water anaerobic
    environment devoid of life

Carbonaceous Impressions
  • In such an environment,
  • bacterial degradation did not destroy the buried
  • and they were compressed by the weight of the
    overlying sediments
  • and eventually preserved as carbonaceous

Study of Paleozoic Life
  • We will examine the history of Paleozoic life
  • as a system of interconnected biologic and
    geologic events
  • Evolution and plate tectonics
  • are the forces that drove this system
  • The opening and closing of ocean basins,
  • transgressions and regressions of epeiric seas,
  • the formation of mountain ranges,
  • and the changing positions of the continents
  • had a profound effect on the evolution
  • of the marine and terrestrial communities

Tremendous Biologic Change
  • A time of tremendous biologic change
  • began with the appearance of skeletonized animals
  • near the Precambrian-Cambrian boundary
  • Following this event, marine invertebrates
  • began a period of adaptive radiation and
  • during which the Paleozoic marine invertebrate
    community greatly diversified
  • Indeed, the history of the Paleozoic marine
    invertebrate community
  • was one of diversification and extinction,
  • culminating at the end of the Paleozoic Era
  • in the greatest mass extinction in Earth history

The Cambrian Explosion
  • At the beginning of the Paleozoic Era,
  • animals with skeletons
  • appeared rather abruptly in the fossil record
  • In fact, their appearance is described
  • as an explosive development
  • of new types of animals
  • and is referred to as
  • the "Cambrian explosion" by most scientists

The Cambrian Explosion
  • This sudden and rapid appearance
  • of new animals in the fossil record
  • is rapid, however, only in the context of
    geologic time,
  • having taken place over millions of years
  • during the Early Cambrian Period

Not a Recent Discovery
  • Early geologists observed
  • that the remains of skeletonized animals
  • appeared rather abruptly in the fossil record
  • Charles Darwin addressed this problem
  • in On the Origin of Species
  • and observed that,
  • without a convincing explanation,
  • such an event was difficult to reconcile
  • with his newly expounded evolutionary theory

Sharp Contrast
  • The sudden appearance of shelled animals
  • during the Early Cambrian
  • contrasts sharply with the biota living
  • during the preceding Proterozoic Eon
  • Up until the evolution of the Ediacaran fauna,
  • Earth was populated primarily
  • by single-celled organisms
  • The Ediacaran fauna,
  • which is found on all continents except
  • consists primarily of multicelled soft-bodied

Soft-Bodied Organisms
  • Microscopic calcareous tubes,
  • presumably housing worm-like suspension feeding
  • have also been found at some localities
  • In addition, trails and burrows,
  • which represent the activities of worms
  • and other sluglike animals
  • are also found associated
  • with Ediacaran faunas throughout the world
  • The trails and burrows
  • are similar to those made by present-day
    soft-bodied organisms

Time Between
  • Until recently, it appeared that
  • a fairly long time period existed
  • between the extinction of the Ediacaran fauna
  • and the evolution of the first Cambrian fossils
  • That gap has been considerably narrowed
  • in recent years with the discovery
  • of new Proterozoic fossiliferous localities
  • that continue right to the base of the Cambrian

Hotly Debated Topic
  • Nonetheless, the cause of the sudden appearance
  • of so many different animal phyla
  • during the Early Cambrian
  • is still a hotly debated topic
  • Newly developed molecular techniques
  • that allow evolutionary biologists
  • to compare the similarity of molecular sequences
  • of the same gene from different species
  • is being applied to the phylogeny of many

Early Invertebrate History
  • In addition, new fossil sites
  • and detailed stratigraphic studies
  • are shedding light
  • on the early history and ancestry
  • of the various invertebrate phyla

Triggering Mechanism
  • It appears likely that the Cambrian explosion
  • probably had its roots firmly planted in the
  • However, the mechanism
  • that triggered this event is still unknown and
  • was likely a combination of factors,
  • both biological and geological
  • For example, geologic evidence
  • indicates Earth was glaciated
  • one or more times during the Proterozoic,
  • followed by global warming during the Cambrian

Hox Genes
  • These global environmental changes
  • may have stimulated evolution
  • and contributed to the Cambrian explosion
  • Recent work on Hox genes, which are
  • sequences of genes that control the development
    of individual regions of the body,
  • shows that the basic body plans for all animals
  • was apparently established
  • by the end of the Cambrian explosion,
  • and was only slightly modified since then

Major Event in Earth's History
  • Whatever the ultimate cause of the Cambrian
  • the appearance of a skeletonized fauna
  • and the rapid diversification of that fauna
  • during the Early Cambrian
  • was a major event in Earth's history

The Emergence of a Shelly Fauna
  • The earliest organisms with hard parts
  • are Proterozoic calcareous tubes
  • found associated with Ediacaran faunas
  • from several locations throughout the world
  • These are followed by other microscopic
    skeletonized fossils
  • from the Early Cambrian
  • and the appearance of large skeletonized animals
  • during the Cambrian explosion

Lower Cambrian Shelly Fossil
  • A conical sclerite of Lapworthella from
  • a piece of the armor covering
  • This specimen is several millimeters in size

Lower Cambrian Shelly Fossil
  • Archaeooides, an enigmatic spherical fossil from
    the Mackenzie Mountains, Northwest Territories,
  • This specimen is several millimeters in size

Lower Cambrian Shelly Fossil
  • The tube of an anabaritid from the Mackenzie
    Mountains, Northwest Territories, Canada
  • This specimen is several millimeters in size

Why Skeletons
  • Along with the question of
  • why did animals appear so suddenly in the fossil
  • is the equally intriguing one of
  • why they initially acquired skeletons
  • and what selective advantage this provided
  • A variety of explanations
  • about why marine organisms evolved skeletons
  • have been proposed,
  • but none is completely satisfactory or
    universally accepted

Advantages of an Exoskeleton
  • The formation of an exoskeleton
  • confers many advantages on an organism
  • (1) It provides protection against ultraviolet
    radiation, allowing animals to move into
    shallower waters
  • (2) it helps prevent drying out in an intertidal
  • (3) it provides protection against predators
  • Recent evidence of actual fossils of predators
  • and specimens of damaged prey,
  • as well as antipredatory adaptations in some
  • indicates that the impact of predation during the
    Cambrian was great

Cambrian Predator
  • Reconstruction of Anamalocaris
  • a predator from the Early and Middle Cambrian
  • It was about 45 cm long and probably fed on
  • Its gripping appendages presumably carried food
    to its mouth

Wounded Trilobite
  • Wounds to the body of the trilobite Olenellus
  • The wounds have healed, demonstrating that they
    occurred when the animal was alive and were not
    inflicted on an empty shell

Advantages of an Exoskeleton
  • With predators playing an important role
  • in the Cambrian marine ecosystem,
  • any mechanism or feature
  • that protected an animal
  • would certainly be advantageous
  • and confer an adaptive advantage to the organism
  • (4) A fourth advantage is that
  • a supporting skeleton, whether an exo- or
  • allows animals to increase their size
  • and provides attachment sites for muscles

It Is Unknown Why Organisms Evolved Mineralized
  • There currently is no clear answer about
  • why marine organisms evolved mineralized
  • during the Cambrian explosion and shortly
  • They undoubtedly evolved
  • because of a variety of biologic and
    environmental factors

Mineralized Skeletons Were Successful
  • Whatever the reason,
  • the acquisition of a mineralized skeleton
  • was a major evolutionary innovation
  • allowing invertebrates to successfully occupy
  • a wide variety of marine habitats

Paleozoic Invertebrate Marine Life
  • Having considered the origin, differentiation,
    and evolution
  • of the Precambrian-Cambrian marine biota,
  • we now examine the changes
  • that occurred in the marine invertebrate
  • during the Paleozoic Era

Marine Invertebrate Communities
  • Rather than focusing on
  • the history of each invertebrate phylum,
  • we will survey the evolution
  • of the marine invertebrate communities through
  • concentrating on the major features and changes
    that took place
  • To do that, we need to briefly examine
  • the nature and structure
  • of living marine communities so that
  • we can make a reasonable interpretation
  • of the fossil record

The Present Marine Ecosystem
  • In analyzing the present-day marine ecosystem,
  • we must look at where organisms live,
  • how they get around,
  • as well as how they feed
  • Organisms that live in the water column
  • above the seafloor
  • are called pelagic
  • They can be divided into two main groups
  • the floaters, or plankton,
  • and the swimmers, or nekton

  • Plankton are mostly passive and go where currents
    carry them
  • Plant plankton
  • such as diatoms, dinoflagellates, and various
  • are called phytoplankton and are mostly
  • Animal plankton are called zooplankton and are
    also mostly microscopic
  • Examples of zooplankton include foraminifera,
    radiolarians, and jellyfish

  • The nekton are swimmers
  • and are mainly vertebrates
  • such as fish
  • the invertebrate nekton
  • include cephalopods

  • Organisms that live
  • on or in the seafloor make up the benthos
  • They can be characterized
  • as epifauna (animals) or epiflora (plants),
  • for those that live on the seafloor,
  • or as infauna,
  • which are animals living in and moving through
    the sediments

Sessile and Mobile
  • The benthos can be further divided
  • into those organisms that stay in one place,
  • called sessile,
  • and those that move around on or in the seafloor,
  • called mobile

Marine Ecosystem
  • Where and how animals and plants live in the
    marine ecosystem

Plankton Jelly fish
Nekton fish cephalopod
Sessile epiflora seaweed
Sessile epifauna bivalve
Benthos d-k
Marine Ecosystem
Infauna worm, bivalve
Mobile epifauna gastropod, starfish
Feeding Strategies
  • The feeding strategies of organisms
  • are also important in terms of their
  • with other organisms in the marine ecosystem
  • There are basically four feeding groups
  • suspension-feeding animals remove or consume
    microscopic plants and animals as well as
    dissolved nutrients from the water
  • herbivores are plant eaters
  • carnivore-scavengers are meat eaters
  • and sediment-deposit feeders ingest sediment and
    extract the nutrients from it

Marine Ecosystem
Suspension feeders
Marine Ecosystem
worm sediment-deposit feeder
Herbivores gastropod
Carnivores-scavengers starfish
Organism's Place
  • We can define an organism's place
  • in the marine ecosystem
  • by where it lives
  • and how it eats
  • For example, an articulate brachiopod
  • is a benthonic,
  • epifaunal suspension feeder,
  • whereas a cephalopod
  • is a nektonic carnivore

Trophic Levels
  • An ecosystem includes several trophic levels,
  • which are tiers of food production and
  • within a feeding hierarchy
  • The feeding hierarchy
  • and hence energy flow
  • in an ecosystem comprise
  • a food web of complex interrelationships among
  • the producers,
  • consumers,
  • and decomposers

Primary Producers
  • The primary producers, or autotrophs,
  • are those organisms that manufacture their own
  • Virtually all marine primary producers are
  • Feeding on the primary producers
  • are the primary consumers, which are mostly
    suspension feeders

Other Consumers
  • Secondary consumers feed on
  • the primary consumers,
  • and thus are predators, while tertiary consumers,
    which are also predators, feed on the secondary
  • Besides the producers and consumers,
  • there are also transformers and decomposers
  • These are bacteria that break down the dead
  • that have not been consumed
  • into organic compounds that are then recycled

Marine Food Web
  • Showing the relationships
  • among the
  • producers,
  • consumers,
  • and decomposers

When the System Changes
  • When we look at the marine realm today,
  • we see a complex organization of organisms
  • interrelated by trophic interactions
  • and affected by changes in the physical
  • When one part of the system changes,
  • the whole structure changes,
  • sometimes almost insignificantly,
  • other times catastrophically

Changing Marine Ecosystem
  • As we examine the evolution of the Paleozoic
    marine ecosystem,
  • keep in mind how geologic and evolutionary
  • can have a significant impact on its composition
    and structure

Changing Marine Ecosystem
  • For example, the major transgressions onto the
  • opened up vast areas of shallow seas
  • that could be inhabited
  • The movement of continents
  • affected oceanic circulation patterns
  • as well as causing environmental changes

Cambrian Marine Community
  • The Cambrian Period was a time
  • during which many new body plans evolved
  • and animals moved into new niches
  • As might be expected, the Cambrian
  • witnessed a higher percentage of such experiments
  • than any other period of geologic history

Cambrian Skeletonized Life
  • Although almost all the major invertebrate phyla
  • evolved during the Cambrian Period
  • many were represented by only a few species
  • While trace fossils are common
  • and echinoderms diverse,
  • the organisms that comprised the majority of
    Cambrian skeletonized life were
  • trilobites,
  • inarticulate brachiopods,
  • and archaeocyathids

Cambrian Marine Community
  • Floating jellyfish, swimming arthropods,
    benthonic sponges, and scavenging trilobites
  • Reconstruction

  • Trilobites were
  • by far the most conspicuous element
  • of the Cambrian marine invertebrate community
  • and made up about half of the total fauna
  • Trilobites were
  • benthonic
  • mobile
  • sediment-deposit feeders
  • that crawled or swam along the seafloor

  • They first appeared in the Early Cambrian,
  • rapidly diversified,
  • reached their maximum diversity
  • in the Late Cambrian,
  • and then suffered mass extinctions
  • near the end of the Cambrian
  • from which they never fully recovered
  • As yet no consensus exists on what caused the
    trilobite extinctions

Trilobite Extinctions
  • A combination of factors were likely involved in
    the extinctions,
  • including a possible reduction of shelf space,
  • increased competition,
  • and a rise in predators
  • It has also been suggested
  • that a cooling of the seas may have played a
  • particularly for the extinctions
  • that took place
  • at the end of the Ordovician Period

Cambrian Brachiopods
  • Cambrian brachiopods
  • were mostly primitive types called inarticulates
  • They secreted a chitinophosphate shell,
  • composed of the organic compound chitin
  • combined with calcium phosphate
  • Inarticulate brachiopods
  • also lacked a tooth-and-socket-arrangement
  • along the hinge line of their shells

Articulate Brachiopods
  • The articulate brachiopods,
  • which have a tooth-and-socket arrangement,
  • were also present
  • but did not become abundant
  • until the Ordovician Period

  • The third major group of Cambrian organisms
  • were the archaeocyathids
  • These organisms
  • were benthonic sessile suspension feeders
  • that constructed reeflike structures
  • The rest of the Cambrian fauna
  • consisted of representatives
  • of the other major phyla,
  • including many organisms
  • that were short-lived evolutionary experiments

Cambrian Reeflike Structure
  • Restoration of a Cambrian reeflike structure
    built by archeocyathids

Primitive Echinoderm
  • Helicoplacus was a primitive echinoderm
  • that became extinct 20 million years after its
    first appearance about 510 million years ago
  • and was a representative of one of several
    short-lived echinoderm classes
  • Such organisms illustrate the experimental
    nature of the Cambrian invertebrate fauna

The Burgess Shale Biota
  • No discussion of Cambrian life
  • would be complete without mentioning
  • one of the best examples
  • of a preserved soft bodied fauna and flora,
  • the Burgess Shale biota
  • As the Sauk Sea transgressed
  • from the Cordilleran shelf
  • onto the western edge of the craton
  • Early Cambrian sands were covered
  • by Middle Cambrian black muds
  • that allowed a diverse soft-bodied benthonic
    community to be preserved

Soft-Bodied Animals and Plants
  • These fossils were discovered in 1909 by Charles
  • near Field, British Columbia
  • They represent one of the most significant fossil
    finds of the 20th century
  • because they consist of impressions of
    soft-bodied animals and plants
  • which are rarely preserved in the fossil record

Rare Preservation Burgess Shale
  • Ottoia, a carnivorous worm

Rare Preservation Burgess Shale
  • Wiwaxia, a scaly armored sluglike creature whose
    affinities remain controversial

Rare Preservation Burgess Shale
  • Hallucigenia, a velvet worm

Rare Preservation Burgess Shale
  • Waptia, an anthropod

Rarely Preserved Organisms
  • This discovery therefore
  • provides us with a valuable glimpse
  • of rarely preserved organisms
  • as well as the soft-part anatomy
  • of many extinct groups

  • In recent years, the reconstruction,
    classification, and interpretation
  • of many of the Burgess Shale fossils
  • have undergone a major change
  • that has led to new theories and explanations
  • of the Cambrian explosion of life
  • Recall that during the Neoproterozoic
    multicellular organisms evolved,
  • and shortly thereafter animals
  • with hard parts made their first appearance

Basic Body Plans
  • These were followed by
  • an explosion of invertebrate groups
  • during the Cambrian,
  • many of which are now extinct
  • These Cambrian organisms
  • represent the root stock
  • and basic body plans
  • from which all present-day invertebrates evolved

How Many Phyla?
  • The question that paleontologists are still
    debating is
  • How many phyla arose during the Cambrian?
  • At the center of that debate are the Burgess
    Shale fossils
  • For years, most paleontologists
  • placed the bulk of the Burgess Shale organisms
  • into existing phyla,
  • with only a few assigned to phyla
  • that are now extinct

Cambrian Phyla
  • Thus, the phyla of the Cambrian world
  • were viewed as being essentially the same in
  • as the phyla of the present-day world,
  • but with fewer species in each phylum
  • According to this view, the history of life
  • has been simply a gradual increase in the
    diversity of species
  • within each phylum through time
  • The number of basic body plans
  • has therefore remained more or less constant
  • since the initial radiation of multicelled

Explosion of Varied Lifeforms
  • This view, however, has been challenged
  • by other paleontologists
  • who think that the initial explosion of varied
    life-forms in the Cambrian
  • was promptly followed by a short period of
  • and then extinction of many phyla
  • The richness and diversity of modern life-forms
  • are the result of repeated variations of the
    basic body plans
  • that survived the Cambrian extinctions

Strangeness of the Burgess Shale Biota
  • In other words, life was much more diverse
  • in terms of phyla
  • during the Cambrian
  • than it is today
  • The reason members of the Burgess Shale biota
  • look so strange to us
  • is that no living organisms
  • possess their basic body plan,
  • and therefore many of them have been placed into
    new phyla

Reassignment to Extant Phyla
  • Discoveries of Cambrian fossils
  • at localities such as Sirius Passet, Greenland,
    and Yunnan, China,
  • have resulted in reassignment
  • of some Burgess Shale specimens back into extant
  • If these reassignments to known phyla prove to be
  • then no massive extinction event followed the
    Cambrian explosion,
  • and life has gradually increased in diversity
    through time

No Clear Answer to This Debate
  • Currently, there is no clear answer to this
  • and the outcome will probably be decided
  • as more fossil discoveries are made

Ordovician Marine Community
  • A major transgression that began
  • during the Middle Ordovician (Tippecanoe
  • resulted in the most widespread inundation of the
  • This vast epeiric sea,
  • which experienced a uniformly warm climate during
    this time,
  • opened numerous new marine habitats
  • that were soon filled by a variety of organisms

Striking Changes in Ordovician
  • Both sedimentation patterns and fauna
  • underwent striking changes
  • from the Cambrian to the Ordovician,
  • Whereas the Cambrian invertebrate community
  • was dominated by trilobites, inarticulate
    brachiopods, and archaeocyathids,
  • the Ordovician was characterized
  • by the adaptive radiation of many other animal
  • such as articulate brachiopods, bryozoans, and
  • with a consequent dramatic increase
  • in the diversity of the total shelly fauna

Middle Ordovician Seafloor Fauna
  • Recreation of a Middle Ordovician seafloor fauna
    with cephalopods, crinoids, colonial corals,
    trilobites, and brachiopods

  • The Ordovician was also a time
  • of increased diversity and abundance
  • of the acritarchs
  • organic-walled phytoplankton of unknown affinity
  • which were the major phytoplankton group
  • of the Paleozoic Era
  • and the primary food source
  • of the suspension feeders

Upper Ordovician Acritarch
  • Acritarch from the Upper Ordovician Sylvan Shale,
  • Acritarchs are organic-walled phytoplankton
  • and were the primary food source for suspension
    feeders during the Paleozoic Era

Upper Ordovician Acritarch
  • Acritarch from the Upper Ordovician Sylvan Shale,

Reef Builders
  • During the Cambrian, archaeocyathids
  • were the main builders of reeflike structures,
  • but beginning in the Middle Ordovician
  • bryozoans, stromatoporoids, and tabulate and
    rugose corals
  • assumed that role
  • Many of these reefs
  • were small patch reefs similar in size
  • to those of the Cambrian
  • but of a different composition,
  • whereas others were quite large

Suspension Feeders Dominated Reefs
  • As with present-day reefs,
  • Ordovician reefs exhibited a high diversity of
  • and were dominated by suspension feeders

Biostratigraphic Correlation
  • Three Ordovician fossil groups
  • have proved to be particularly useful
  • for biostratigraphic correlation
  • the articulate brachiopods,
  • graptolites,
  • and conodonts
  • The articulate brachiopods,
  • present since the Cambrian,
  • began a period of major diversification
  • in the shallow-water marine environment
  • during the Ordovician

  • Brachiopods became a conspicuous element
  • of the invertebrate fauna
  • during the Ordovician
  • and in succeeding Paleozoic periods

  • Most graptolites were
  • planktonic animals carried about by ocean
  • Because most graptolites were planktonic
  • and most individual species existed for less than
    a million years,
  • graptolites are excellent guide fossils
  • They were especially abundant
  • during the Ordovician and Silurian periods
  • Because of the fragile nature of their organic
  • graptolites are most commonly found in black
  • preserved as carbonaceous impressions

  • Conodonts are a group
  • of well-known, small toothlike fossils
  • composed of the mineral apatite
  • (calcium phosphate)
  • the same mineral that composes bone
  • Although conodonts have been known for more than
    150 years,
  • their affinity has been the subject of debate
  • until the discovery of the conodont animal in 1983

  • Conodonts are microscopic toothlike fossils
  • Cahabagnathus sweeti, Copenhagen Formation
  • Middle Ordovician, Monitor Range, Nevada

  • Conodonts are microscopic toothlike fossils
  • Scolopodus, sp., Shingle Limestone,
  • Shingle Pass, Nevada

  • The conodont animal
  • preserved as a carbonized impression 40 x 2 mm
  • in the Lower Carboniferous Granton Shrimp Bed in
    Edinburgh, Scotland

Conodont Animal
  • Several specimens of carbonized impressions
  • of the conodont animal
  • from Lower Carboniferous rocks of Scotland
  • reveal that it is a member of a group
  • of primitive jawless animals
  • assigned to the phylum Chordata
  • Study of the specimens
  • indicates that the conodont animal
  • was probably an elongate swimming organism

Excellent Guide Fossils
  • The wide distribution
  • and short stratigraphic range of individual
    conodont species
  • make them excellent fossils
  • for biostratigraphic zonation and correlation

Mass Extinctions
  • The end of the Ordovician
  • was a time of mass extinctions in the marine
  • More than 100 families of marine invertebrates
    became extinct,
  • and in North America alone,
  • approximately one-half of the brachiopods and
    bryozoans died out
  • What caused such an event?
  • Many geologists think these extinctions
  • were the result of the extensive glaciation
  • that occurred in Gondwana
  • at the end of the Ordovician Period

Mass Extinctions
  • Mass extinctions,
  • those geologically rapid events
  • in which an unusually high percentage
  • of the fauna and/or flora becomes extinct,
  • have occurred throughout geologic time
  • for instance, at or near the end of the
  • Ordovician,
  • Devonian,
  • Permian,
  • and Cretaceous periods
  • and are the focus of much research and debate

Silurian and Devonian Marine Communities
  • The mass extinction at the end of the Ordovician
  • was followed by rediversification
  • and recovery of many of the decimated groups
  • Brachiopods, bryozoans, gastropods, bivalves,
    corals, crinoids, and graptolites
  • were just some of the groups that rediversified
  • beginning during the Silurian

Massive Reef Builders
  • Recall that the Silurian and Devonian
  • were times of major reef building
  • While most of the Silurian radiations of
  • represented repopulating of niches,
  • organic reef builders diversified in new ways,
  • building massive reefs
  • larger than any produced
  • during the Cambrian or Ordovician

  • This repopulation
  • was probably caused in part to renewed
  • transgressions over the craton,
  • and although a major drop in sea level
  • occurred at the end of the Silurian,
  • the Middle Paleozoic sea level
  • was generally high

Silurian and Devonian Reefs
  • The Silurian and Devonian reefs
  • were dominated by
  • tabulate and colonial rugose corals and
  • While the fauna of these Silurian and Devonian
  • was somewhat different
  • from that of earlier reefs and reeflike
  • the general composition and structure
  • are the same as in present-day reefs

Middle Devonian Reef
  • Reconstruction of a Middle Devonian reef from the
    Great Lakes area
  • with corals, cephalopods, trilobites, crinoids,
    and brachiopods

Eurypterids and Ammonoids
  • The Silurian and Devonian periods
  • were also the time when eurypterids
  • arthropods with scorpion-like bodies and
    impressive pincers
  • were abundant, especially in brackish and
    freshwater habitats
  • Ammonoids,
  • a subclass of the cephalopods,
  • evolved from nautiloids
  • during the Early Devonian and rapidly diversified

Silurian Brackish-Marine Scene
  • Restoration of a Silurian brackish-marine bottom
  • near Buffalo New York
  • with algae, eurypterids, gastropods, worms, and

  • Ammonoids are excellent guide fossils
  • for the Devonian through Cretaceous periods
  • with their distinctive suture patterns,
  • short stratigraphic ranges,
  • and widespread distribution

Ammonoid Cephalopod
  • A late Devonian ammonoid cephalopod
  • from Erfoud, Morocco
  • The distinctive suture pattern, short
    stratigraphic range, and wide geographic
    distribution make ammonoids excellent guide

Another Mass Extinction
  • Another mass extinction
  • occurred near the end of the Devonian
  • and resulted in a worldwide near-total collapse
  • of the massive reef communities
  • On land, however, the seedless vascular plants
  • were seemingly unaffected,
  • Thus, extinctions at this time
  • were most extensive in the marine realm,
  • particularly in the reef and pelagic communities

Global Cooling
  • The demise of the Middle Paleozoic reef
  • serves to highlight the geographic aspects
  • of the Late Devonian mass extinction
  • The tropical groups were most severely affected
  • in contrast, the higher latitude communities were
    seemingly little affected
  • Apparently, an episode of global cooling
  • was largely responsible for the extinctions
  • near the end of the Devonian

Actors in Extinctions
  • During such a cooling,
  • the disappearance of tropical conditions
  • would have had a severe effect on reef
  • and other warm-water organisms
  • Cool-water species, on the other hand,
  • could have simply migrated toward the equator
  • The closing of the Iapetus Ocean
  • and the orogenic events of the Late Devonian
  • undoubtedly also played a role in these
  • by reducing the area of shallow shelf
  • where many marine invertebrates lived

Carboniferous and Permian Marine Communities
  • The Carboniferous invertebrate marine community
  • responded to the Late Devonian extinctions
  • in much the same way as
  • the Silurian invertebrate marine community
  • responded to the Late Ordovician extinctions
  • that is, by renewed adaptive radiation and

Rapid Recovery
  • The brachiopods and ammonoids
  • quickly recovered
  • and again assumed important ecological roles,
  • while other groups, such as the lacy bryozoans
    and crinoids,
  • reached their greatest diversity during the
  • With the decline
  • of stromatoporoids and tabulate and rugose
  • large organic reefs virtually disappeared
  • and were replaced by small patch reefs

Mississippian Patch Reefs
  • These patch reefs were dominated
  • by crinoids, blastoids, lacy bryozoans,
    brachiopods, and calcareous algae
  • and flourished during the Late Paleozoic
  • In addition, bryozoans and crinoids
  • contributed large amounts of skeletal debris
  • to the formation of the vast bedded limestones
  • that constitute the majority of Mississippian
    sedimentary rocks

Mississippian Marine Life
  • Based on a fossil site in the Upper Mississippian
    at Crawfordville, Indiana
  • Invertebrate animals shown include
  • blastoids
  • lacy bryozoans
  • crinoids
  • brachiopods
  • small corals

Restricted Permian Marine Faunas
  • The Permian invertebrate marine faunas
  • resembled Carboniferous faunas,
  • but were not as widely distributed
  • because of the restricted size of the shallow
  • on the cratons and the reduced shelf space
  • along the continental margins

Permian Period
  • Paleogeography of North America during the
    Permian Period

  • The spiny and odd-shaped productids
  • dominated the brachiopod assemblage
  • and constituted an important part
  • of the reef complexes
  • that formed in the Texas region during the Permian

Permian Patch-Reef Community
  • From Glass Mountains of West Texas
  • including algae, productid brachiopods,
    cephalopods, sponges, and corals

  • The fusulinids
  • spindle-shaped foraminifera
  • which first evolved during the Late Mississippian
  • and greatly diversified during the Pennsylvanian,
  • experienced a further diversification
  • during the Permian

  • Fusulinids are spindle-shaped, benthonic
    foraminifera that are excellent guide fossils for
    the Pennsylvanian and Permian periods

Fusulinids Are Important Guide Fossils
  • Because of their
  • abundance, diversity, and worldwide occurrence,
  • fusulinids are important guide fossils
  • for Pennsylvanian and Permian strata
  • Bryozoans, sponges, and some types of calcareous
  • also were common elements of the Permian
    invertebrate fauna

The Permian Marine Invertebrate Extinction Event
  • The greatest recorded mass extinction event
  • to affect Earth
  • occurred at the end of the Permian Period
  • Before the Permian ended,
  • roughly 50 of all marine invertebrate families
  • and about 90 of all marine invertebrate species
    became extinct

Phanerozoic Diversity
  • Diversity for marine invertebrate and vertebrate
  • 3 episodes of Paleozoic mass extinctions are
  • with the greatest occurring at the end of the
    Permian Period

  • Fusulinids, rugose and tabulate corals, several
    bryozoan and brachiopod orders,
  • as well as trilobites and blastoids
  • did not survive the end of the Permian
  • All of these groups
  • had been very successful during the Paleozoic Era
  • In addition, more than 65 of all amphibians and
  • as well as nearly 33 of insects on land also
    became extinct

Mass Extinction
  • What caused such a crisis
  • for both marine and land-dwelling organisms?
  • Various hypotheses have been proposed,
  • but no completely satisfactory answer
  • has yet been found
  • Some scenarios put forth to explain the
    extinctions include
  • (1) a meteorite impact such as occurred at the
    end of the Cretaceous Period
  • (2) a widespread marine regression resulting from
    glacial conditions,

Permian Mass Extinction
  • (3) a reduction in shelf space due to the
    formation of Pangaea,
  • (4) oceanographic changes such as anoxia,
    salinity changes, and turnover of deep-ocean
  • It appears that the Permian mass extinction
  • took place over millions of years
  • at the end of the Permian Period,
  • which would seemingly rule out a meteorite impact

Permian Mass Extinction
  • The second and third hypotheses
  • can probably be eliminated
  • because most of the collisions of the continents
  • had already taken place by the end of the Permian
  • and the large-scale formation of glaciers took
  • during the Carboniferous Period

Anoxic Waters
  • Currently, many scientists think
  • that an episode of deep-sea anoxia
  • resulted in a highly stratified ocean
  • during the Late Permian.
  • There was little circulation
  • of oxygen-rich surface waters
  • into the deep ocean.
  • Stagnant waters also covered the shelf region.
  • There is also evidence
  • of increased global warming
  • during the Late Permian,
  • which would contribute to a stratified global

Carbon Dioxide
  • During this time, widespread volcanic eruptions
  • 1nd continental fissure eruptions
  • also took place,
  • further releasing additional carbon dioxide
  • into the atmosphere
  • and contributing to increased climatic
    instability and ecological collapse
  • By the end of the Permian,
  • a near collapse of both the marine and
    terrestrial ecosystem had occurred.

  • Multicelled organisms presumably
  • had a long Precambrian history during which they
    lacked hard parts
  • Invertebrates with hard parts
  • suddenly appeared during the Early Cambrian
  • in what is called the Cambrian explosion
  • Skeletons provided such advantages
  • as protection against predators
  • and support for muscles,
  • enabling organisms to grow large
  • and increase locomotor efficiency

  • Hard parts probably evolved
  • as a result of various geologic factors
  • rather than a single cause
  • Marine organisms are classified
  • as plankton
  • if they are floaters,
  • nekton
  • if they swim,
  • and benthos
  • if they live on or in the seafloor

  • Marine organisms can be divided
  • into four basic feeding groups
  • suspension feeders,
  • which consume microscopic plants and animals as
    well as dissolved nutrients from water
  • herbivores, which are plant eaters
  • carnivores, which are meat eaters
  • and sediment-deposit feeders,
  • which ingest sediment and extract nutrients from

  • The marine ecosystem consists of various trophic
  • of food production and consumption
  • At the base are primary producers,
  • upon which all other organisms are dependent
  • the primary consumers
  • feed on the primary producers
  • higher level consumers
  • can feed upon primary producers
  • The decomposers are bacteria
  • that break down the complex organic compounds
  • of dead organisms
  • and recycle them within the ecosystem

  • The Cambrian invertebrate community
  • was dominated by three major groups,
  • the trilobites,
  • inarticulate brachiopods,
  • and archaeocyathids
  • Little specialization existed among the
  • and the most phyla were represented
  • by only a few species

  • The Middle Cambrian Burgess Shale
  • contains one of the finest examples
  • of a well-preserved soft-bodied biota in the
  • The Ordovician marine invertebrate community
  • marked the beginning of the dominance
  • by the shelly fauna
  • and the start of large-scale reef building
  • The end of the Ordovician Period
  • was a time of major extinctions
  • for many invertebrate phyla

  • The Silurian and Devonian periods
  • were times of diverse faunas
  • dominated by reef-building animals,
  • while the Carboniferous and Permian periods
  • saw a great decline in invertebrate diversity
  • A major extinction occurred at the end of the
    Paleozoic Era,
  • affecting the invertebrates as well as the
  • Its cause is still being debated
Write a Comment
User Comments (0)