Chapter 20 Unifying Concepts of Animal Structure and Function

Download Report

Transcript Chapter 20 Unifying Concepts of Animal Structure and Function

Chapter 20
Unifying Concepts of Animal
Structure and Function
Overview:
Hierarchy of Structural Organization
Exchanges with the environment
Climbing the Walls
• The function of any part of an
animal results from its unique
structure
• Consider the gecko, a small
lizard commonly
found in the tropics
– A gecko can walk up a wall
and across ceilings
– How does it do that?
• The explanation relates to
hairs, called setae, on the
gecko’s toes
– They are arranged in
rows
– Each seta ends in
many split ends
called spatulae,
which have rounded
tips
– The ability to “stick” to surfaces results from
attractions between molecules on the spatulae and
molecules on the surface
– The structure of the gecko’s feet leads to a unique
function
THE HIERARCHY OF STRUCTURAL
ORGANIZATION IN AN ANIMAL
Structure fits function in the animal body
• The correlation between structure and function is
one of biology’s most fundamental concepts
Animal structure has a hierarchy
• Structure and
function are
correlated at
each level in
the structural
hierarchy of an
animal’s body
• Life is characterized by hierarchical levels of
organization
• In animals
–
–
–
–
Individual cells are grouped into tissues
Tissues combine to form organs
Organs are organized into organ systems
Organ systems make up the entire organism
• Biologists distinguish anatomy from physiology
– Anatomy is the study of the structure of an organism
– Physiology is the study of the function of an
organism’s structural equipment
Tissues
• In most multicellular animals, cells are grouped
into tissues
– A tissue is a collection of many structurally similar
cells that act cooperatively to perform a specific
function
Tissues are groups of cells with a common structure and
function
• A tissue is a cooperative of many similar cells
that perform a specific function
• Animals have four major categories of tissue
–
–
–
–
Epithelial tissue
Connective tissue
Muscle tissue
Nervous tissue
Epithelial tissue covers and lines the body and its parts
• Epithelial tissue occurs as sheets of closely
packed cells
– It covers surfaces and lines internal organs and
cavities
– Examples: epidermis, stomach lining
• The structure of each type of epithelium fits its
function
Connective tissue binds and supports other tissues
• Connective tissue is characterized by sparse cells
– The cells manufacture and secrete an extracellular
matrix
– The matrix is composed of fibers embedded in a
liquid, solid, or gel
• Connective tissues have a sparse population of
cells scattered through an extracellular matrix
– The matrix consists of a web of protein fibers
embedded in a uniform foundation
• The structure of connective tissue correlates with
its function
– It binds and supports other tissues
• Loose connective tissue is the most widespread
connective tissue
– It binds epithelia to underlying tissues
– It holds organs in place
• Adipose tissue stores fat
– It stockpiles energy
– It pads and insulates the body
• Blood is a connective tissue with a matrix of
liquid
– Red and white blood cells are suspended in plasma
• Fibrous connective tissue has a dense matrix of
collagen
– It forms tendons and ligaments
• The matrix of cartilage is strong but rubbery
– It functions as a flexible, boneless skeleton
– It forms the shock absorbing pads that cushion the
vertebrae of the spinal column
• Bone is a rigid connective tissue with a matrix of
rubbery fibers hardened with deposits of calcium
Muscle Tissue
• Muscle tissue consists of bundles of long, thin,
cylindrical cells called muscle fibers
• Each cell has specialized proteins that contract
when the cell is stimulated by a nerve
• Skeletal muscle is responsible for voluntary body
movements
• Cardiac muscle pumps blood
• Smooth muscle moves the walls of internal
organs such as the stomach
• Skeletal muscle is attached to bones by tendons
– It is responsible for voluntary movements
– The contractile apparatus forms a banded pattern in
each cell or fiber
– It is said to be striated, or striped
• Cardiac muscle is found only in heart tissue
– Its contraction accounts for the heartbeat
– Cardiac muscle cells are branched and joined to one
another
• Smooth muscle is named for its lack of obvious
striations
– It is found in the walls of various organs
– It is involuntary
Nervous Tissue
• Nervous tissues makes communication of
sensory information possible
– Sensory input is received and processed
– Motor output is then relayed to make body parts
respond
• Nervous tissue is found in the brain and spinal
cord
• The basic unit of nervous tissue is the neuron, or
nerve cell
– Neurons can transmit electrical signals rapidly over
long distances
Nervous tissue forms a communication network
• The branching neurons of nervous tissue transmit
nerve signals that help control body activities
Organs and Organ Systems
• The next level in the structural hierarchy after
tissue is the organ
– An organ consists of two or more tissues packaged
into one working unit that performs a specific
function
– Examples: heart, liver, stomach, brain, and lungs
The body is a cooperative of organ systems
• The level of organization higher than an organ is
an organ system
• Each organ system has one or more functions
• The organs of humans and most other animals
are organized into organ systems
– Organ systems are teams of organs that work together
to perform a vital bodily function
• The digestive system
gathers food
• The respiratory system
gathers oxygen
• The circulatory system,
aided by the lymphatic
system, transports the
food and oxygen
• The immune system
protects the body from
infection and cancer
• The excretory system disposes of certain wastes
• The endocrine and nervous systems control and
coordinate body functions
• The integumentary
system covers and
protects the body
• The skeletal system
supports and protects
the body
• The muscular system enables movement
• The reproductive system perpetuates the species
Connection: New imaging technology
reveals the inner body
• New technologies enable us to see body organs
without surgery
– Computed tomography (CT)
– Magnetic resonance
imaging (MRI)
– Positron-emission
tomography (PET)
EXCHANGES WITH THE EXTERNAL
ENVIRONMENT
• Every organism is an open system
– This means that organisms exchange chemicals and
energy with their surroundings
– Organisms must do this to survive
• Animals are not closed systems
– An animal must exchange materials and heat with its
environment
– This exchange must extend to the cellular level
Body Size and Shape
• An animal’s size and shape affect how it
exchanges energy and materials with its
surroundings
– All living cells must be bathed in water so that
exchange of materials may occur (e.g. hydra)
• Small animals with simple body construction
have enough surface to meet their cells’ needs
– Hydras can exchange materials with the environment
though direct diffusion
• Exchange with the environment is easy for
single-celled organisms
– The entire surface area of an amoeba is in contact
with the environment
• Animals with complex body forms face the same
basic problem
– Every living cell must be bathed in fluid
– Every cell must have access to essential nutrients
from the outside environment
• Complex animals have extensively folded or
branched internal surfaces
– These maximize surface area for exchange with the
environment
• Larger, complex
animals have
specialized
internal
structures that
increase surface
area
• Lungs exchange oxygen and carbon dioxide with
the air
– The epithelium of the lungs has a very large total
surface area for this purpose
Animals regulate their internal environment
• In response to changes in external conditions,
animals regulate their internal environment
– They must do this to achieve homeostasis, an internal
steady state
Homeostasis
• Homeostasis is the body’s tendency to
maintain relatively constant conditions in
the internal environment even when the
external environment changes
Negative and Positive Feedback
• Most mechanisms of homeostasis depend on a
common principle called negative feedback
– The results of some process inhibit that very process
• Negative feedback
mechanisms keep
fluctuations in
internal conditions
within the narrow
range compatible
with life
• Less common is positive feedback
– The results of a process intensify that same process
– Example: uterine contractions during childbirth