BackEvolution, Speciation, and Ecology: Study Guide Notes
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Evolutionary Biology and Ecology
Key Concepts in Evolution
This section covers foundational terms and processes in evolutionary biology, including mechanisms of evolution, species concepts, and the history of life on Earth.
Homology and Homologous Structures: Homology refers to similarities between organisms due to shared ancestry. Homologous structures are anatomical features in different species that originated from a common ancestor, even if they serve different functions (e.g., the forelimbs of humans, whales, and bats).
Evolutionary Trees: Also known as phylogenetic trees, these diagrams depict evolutionary relationships among species, showing patterns of descent from common ancestors.
Mutation: A change in the DNA sequence. Mutations are the ultimate source of all new alleles and genetic variation in populations.
Microevolution: Small-scale evolutionary changes within populations, typically involving changes in allele frequencies over generations.
Natural Selection: The process by which individuals with advantageous traits survive and reproduce more successfully, increasing the frequency of those traits in the population. Fitness refers to an organism's ability to survive and reproduce in its environment.
Artificial Selection: The intentional breeding of organisms by humans for desired traits (e.g., dog breeds, crop varieties).
Sexual Selection: A form of natural selection where certain traits increase an individual's chances of mating (e.g., peacock feathers).
Antibiotic Resistance: The evolution of bacteria that survive exposure to antibiotics, often due to mutations and selection pressure.
Speciation and Species Concepts
Speciation is the process by which new species arise. Several concepts are used to define what constitutes a species.
Gene Pool: The total collection of genes and alleles in a population.
Speciation: The formation of new species, often through reproductive isolation mechanisms.
Biological Species Concept: Defines species as groups of actually or potentially interbreeding populations that are reproductively isolated from other such groups.
Ecological Species Concept: Defines species based on their ecological niche, focusing on unique adaptations to particular roles in a biological community.
Phylogenetic Species Concept: Defines species as the smallest group of individuals sharing a common ancestor, forming one branch on the tree of life.
Morphological Species Concept: Defines species based on observable physical traits and structural features.
Reproductive Isolation Mechanisms
Prezygotic Barriers: Prevent mating or fertilization between species. Types include:
Temporal Isolation: Species breed at different times.
Habitat Isolation: Species live in different habitats and do not meet.
Behavioral Isolation: Differences in mating behaviors prevent interbreeding.
Mechanical Isolation: Structural differences prevent mating.
Gametic Isolation: Gametes (egg and sperm) are incompatible.
Postzygotic Barriers: Occur after fertilization, reducing hybrid viability or fertility.
Reduced Hybrid Viability: Hybrids fail to develop or are frail.
Reduced Hybrid Fertility: Hybrids are sterile (e.g., mule).
Major Events in the History of Life
The history of life on Earth is divided into eons and eras, each marked by significant evolutionary events.
Archaean Eon: Origin of life, first prokaryotes.
Proterozoic Eon: First eukaryotes, multicellular life.
Paleozoic Era: Appearance of plants, fungi, arthropods, and reptiles on land.
Mesozoic Era: Age of reptiles (dinosaurs), first mammals and flowering plants.
Cenozoic Era: Age of mammals, diversification of flowering plants.
Order of Major Life Forms in the Geologic Record:
Plants and fungi
Arthropods
Reptiles
Flowering plants
First Mammals and Flowering Plants: Appeared during the Mesozoic Era.
First Plants and Fungi on Land: Established during the Paleozoic Era.
Taxonomy and Classification
Taxonomy is the science of naming and classifying organisms. The binomial classification system uses two names (genus and species) for each organism.
Taxonomic Categories (from most specific to most general):
Rank | Example |
|---|---|
Species | Homo sapiens |
Genus | Homo |
Family | Hominidae |
Order | Primates |
Class | Mammalia |
Phylum | Chordata |
Kingdom | Animalia |
Domain | Eukarya |
Ecology and Ecosystems
Levels of Ecological Organization
Habitat: The natural environment where an organism lives.
Population: A group of individuals of the same species living in a particular area.
Community: All the populations of different species living and interacting in an area.
Ecosystem: The community plus the nonliving (abiotic) environment.
Species Diversity
Species Diversity: The variety of species in a community.
Species Richness: The number of different species present.
Species Composition: The identity of the species present in a community.
Biomes
Biomes are large ecological areas with distinct climate, flora, and fauna. Key characteristics differentiate each biome, such as temperature, precipitation, and dominant vegetation.
Permafrost: Permanently frozen ground, characteristic of tundra biomes.
Note: Be able to list and differentiate the major biomes based on their climate, vegetation, and animal life.
Ecological Interactions
Competition: Occurs when organisms vie for the same resource in an ecosystem.
Mutualism: Both species benefit from the interaction (e.g., bees and flowers).
Interspecific Interactions: Interactions between different species, including competition, predation, and symbiosis.
Predation: One organism (predator) kills and eats another (prey).
Parasitism: One organism (parasite) benefits at the expense of another (host).
Niche: The role and position a species has in its environment, including all its interactions with biotic and abiotic factors.
Predator Avoidance Mechanisms: Adaptations such as camouflage, mimicry, and defensive behaviors that help prey avoid predators.
Trophic Structure and Energy Flow
Trophic Structure: The feeding relationships among organisms in a community.
Food Chain: A linear sequence of organisms through which nutrients and energy pass.
Food Web: A complex network of interconnected food chains in an ecosystem.
Producers: Organisms (usually plants) that produce their own food via photosynthesis.
Consumers: Organisms that obtain energy by eating other organisms. Levels include:
Primary Consumers: Herbivores that eat producers.
Secondary Consumers: Carnivores that eat herbivores.
Tertiary Consumers: Carnivores that eat other carnivores.
Quaternary Consumers: Top predators at the highest trophic level.
Detritivores: Organisms that feed on dead organic matter (e.g., earthworms).
Decomposers: Microorganisms that break down dead material, recycling nutrients (e.g., bacteria, fungi).
Ecological Succession
Ecological Succession: The process of change in the species structure of an ecological community over time.
Primary Succession: Occurs in lifeless areas where soil has not yet formed (e.g., after a volcanic eruption).
Secondary Succession: Occurs in areas where a disturbance has destroyed a community but left the soil intact (e.g., after a fire).
Invasive Species: Non-native species that spread rapidly and disrupt native communities.
Summary Table: Types of Reproductive Isolation
Type | Definition | Example |
|---|---|---|
Temporal Isolation | Species breed at different times | One species breeds in spring, another in fall |
Habitat Isolation | Species live in different habitats | One species in water, another on land |
Behavioral Isolation | Differences in mating rituals | Different bird songs |
Mechanical Isolation | Structural differences prevent mating | Incompatible reproductive organs |
Gametic Isolation | Gametes cannot fuse | Sperm cannot fertilize egg |
Reduced Hybrid Viability | Hybrids fail to develop or are frail | Hybrid embryos die early |
Reduced Hybrid Fertility | Hybrids are sterile | Mule (horse-donkey hybrid) |
Additional info:
Understanding the mechanisms of evolution and speciation is essential for explaining the diversity of life.
Ecological principles help explain how organisms interact with each other and their environment.
Be prepared to apply these concepts to real-world examples and exam questions.