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Animal Diversity, Biodiversity, and Conservation Biology

Study Guide - Smart Notes

Tailored notes based on your materials, expanded with key definitions, examples, and context.

Animal Diversity and General Characteristics

Defining Features of Animals

  • Animals are multicellular organisms that originated from a common ancestor.

  • They exhibit cellular coordination, specialization, and communication among different cell types, which arise due to gene expression.

  • Animals are monophyletic, meaning they form a single clade derived from a common ancestor.

  • Movement under their own power and ingestion of food are key features; animals are true consumers (ingest and digest food internally).

  • Most animals are motile, but some can be sessile during certain life stages.

  • Some characteristics are present only in certain lineages (e.g., tissues, symmetry, cephalization).

Major Animal Traits

  • Tissues: Most animals (except sponges) have specialized tissues, including muscle and nerve tissue.

  • Symmetry: Bilaterally symmetrical animals exhibit cephalization (development of a head region with sensory organs and a brain).

  • Support Structures: Some animals have a spine or vertebral column for central support.

General Patterns and Exceptions

  • Biology is full of general patterns that are usually true, but also exceptions.

  • Understanding both patterns and exceptions is important for studying animal diversity.

Biodiversity: Concepts and Measurement

Defining Biodiversity

  • Biodiversity refers to the variety and variability of life on Earth.

  • It can be characterized in many ways, including species richness, evenness, and functional or phylogenetic diversity.

Measures of Biodiversity

Measure

Description

Benefits

Limitations

Species Richness (Alpha Diversity)

Number of species in a given area

Simple, quick to assess

No info on abundance; sensitive to sample size

Species Evenness

Relative abundance of different species in an area

Quantitative; gives sense of dominance

Population varies; more work to measure

Gamma Diversity

Total number of species across multiple habitats

Broad overview

No info on abundance; ignores habitat differences

Beta Diversity

Difference in species composition between habitats

Shows diversity among habitats

No info on abundance; sensitive to scoring method

Phylogenetic Diversity

Amount of evolutionary history represented in a community (sum of branch lengths on a phylogenetic tree)

Captures evolutionary relationships

Requires phylogenetic data

Functional Diversity

Variety of ecological roles, traits, and functions of organisms in a community

Links biodiversity to ecosystem function

Requires trait data

Additional info:

  • Alpha diversity is sometimes used interchangeably with species richness.

  • Beta diversity quantifies how different communities are in terms of species composition.

Major Evolutionary Events and Patterns

Timeline of Key Biological Events

  • Life on Earth: ~3.5 billion years ago (bya)

  • First eukaryotes: ~2 billion years ago

  • First multicellular organisms: 1.6–1 billion years ago

  • Land plants: 450–500 million years ago (mya)

  • First land vertebrates: 375 mya

  • Dinosaurs: 350–65 mya

  • Mammals: 260 mya

  • Flowering plants: 50 mya

Ecological Opportunity and Adaptive Radiation

  • Ecological opportunity arises when a new or available ecological niche allows species to diversify and adapt.

  • Examples: Appearance of new resources, invasion of new habitats, evolution of key innovations, or loss of competitors/predators.

  • Adaptive radiation is the rapid diversification of a single lineage into many species, often following ecological opportunity.

  • Example: Flowering plants provided new resources for animals, leading to coevolution and diversification.

Extinction and Conservation

Mass Extinctions

  • Mass extinction: Loss of a large number of species in a short time (1–2 million years), often due to rapid environmental changes.

  • Mass extinctions reset ecosystems and open ecological niches for surviving species to diversify and adapt.

  • Current extinction rates are 1,000–10,000 times higher than normal background rates; many species are at risk.

Human Impacts on Biodiversity

  • Humans cause biodiversity decline through habitat loss, introduction of invasive species, climate change, overexploitation, and habitat fragmentation.

  • Habitat fragmentation breaks large habitats into smaller, isolated patches, reducing movement and genetic exchange.

  • Small populations are more vulnerable to extinction due to random events, genetic drift, and inbreeding depression (increased homozygosity).

  • The "extinction vortex" describes the downward spiral of small populations toward extinction.

Ecological Niches

  • Fundamental niche: The full set of conditions and resources a species could theoretically use.

  • Realized niche: The actual conditions and resources a species uses in the presence of competitors and other biotic factors.

Conservation Strategies

  • Conservation efforts include captive breeding, strategic release, habitat restoration, and maintaining genetic diversity.

  • Protecting large areas, restoring connectivity, and managing resources sustainably are key to conservation success.

  • Genetic variation is crucial for population resilience; increasing population size minimizes genetic drift and inbreeding.

Conservation Works

  • Examples of successful conservation: protected areas, sustainable resource management, captive breeding, and species reintroduction.

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