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Lesson OverviewLesson Overview Homeostasis and CellsHomeostasis and Cells
Lesson OverviewLesson Overview7.4 Homeostasis and Cells7.4 Homeostasis and Cells
Lesson OverviewLesson Overview Homeostasis and CellsHomeostasis and Cells
THINK ABOUT IT
The diversity of life is so great that you might have to remind yourself that all living things are composed of cells, use the same basic chemistry, and even contain the same kinds of organelles.
This does not mean that all living things are the same. Differences arise from:•the ways in which cells are specialized •the ways in which cells associate with one another to form multicellular organisms.
Lesson OverviewLesson Overview Homeostasis and CellsHomeostasis and Cells
The Cell as an Organism
A single-celled, or unicellular, organism does everything you would expect a living thing to do.
Just like other living things, unicellular organisms must achieve homeostasis, relatively constant internal physical and chemical conditions.
To maintain homeostasis, unicellular organisms grow, respond to the environment, transform energy, and reproduce.
Lesson OverviewLesson Overview Homeostasis and CellsHomeostasis and Cells
The Cell as an Organism
In terms of their numbers, unicellular organisms dominate life on Earth.
Unicellular organisms include both prokaryotes and eukaryotes.
•Prokaryotes, especially bacteria, are remarkably adaptable and live almost everywhere—in the soil, on leaves, in the ocean, in the air, and even within the human body.•Eukaryotic algae are found in oceans, lakes, and streams around the world.•Yeasts, or unicellular fungi, are also widespread. Yeasts play an important role in breaking down complex nutrients, which makes them available for other organisms.
Lesson OverviewLesson Overview Homeostasis and CellsHomeostasis and Cells
The Cell as an Organism
Whether a prokaryote or a eukaryote, homeostasis is an issue for each unicellular organism.
Every unicellular organism needs to find sources of energy or food, to keep concentrations of water and minerals within certain levels, and to respond quickly to changes in its environment.
Lesson OverviewLesson Overview Homeostasis and CellsHomeostasis and Cells
Multicellular Life
The cells of multicellular organisms are interdependent, meaning, they work together.
Like in baseball, for example, players take on a particular role, such as pitcher, catcher, infielder, or outfielder. Messages and signals are sent and understood by teammates and coaches to play the game effectively.
Cells in a multicellular organism work the same way. The cells of multicellular organisms become specialized for particular tasks and then communicate with one another in order to maintain homeostasis.
Lesson OverviewLesson Overview Homeostasis and CellsHomeostasis and Cells
Cell Specialization
Cells throughout an organism can develop in different ways to perform different tasks. This development is called cell specialization.
Some cells are specialized to move, others to react to the environment, and still others to produce substances that the organism needs.
No matter what the role, each specialized cell contributes to the overall homeostasis of the organism.
Lesson OverviewLesson Overview Homeostasis and CellsHomeostasis and Cells
Examples of Specialized Animal Cells
Particles of dust, smoke, and bacteria are part of even the cleanest air.
Specialized cells in the lungs act like street sweepers to keep particles out.
These cells are full of mitochondria, which provide a steady supply of the ATP that powers the cilia on their upper surfaces.
Lesson OverviewLesson Overview Homeostasis and CellsHomeostasis and Cells
Copyright Pearson Prentice Hall
Red blood cells are
specialized to transport oxygen. They contain a
protein called
hemoglobin that binds oxygen for
transport through the
body.
Lesson OverviewLesson Overview Homeostasis and CellsHomeostasis and Cells
Specialized Plant Cells
Pollen grains are highly specialized cells that are tiny and light, with thick cell walls to protect the cell’s contents.
Pine pollen grains have two tiny wings that enable the slightest breeze to carry them great distances.
Lesson OverviewLesson Overview Homeostasis and CellsHomeostasis and Cells
Levels of Organization
The specialized cells of multicellular organisms are organized into tissues, then into organs, and finally into organ systems.
For example, consider the specialized muscle cell.Muscle cells use cytoskeletal proteins to contract and relax, allowing movement of body parts.
Lesson OverviewLesson Overview Homeostasis and CellsHomeostasis and Cells
Levels of Organization
There are 3 different kinds of muscle cells so there are 3 different types of muscle tissue. A tissue is a group of similar cells that performs a particular function.
Lesson OverviewLesson Overview Homeostasis and CellsHomeostasis and Cells
Levels of Organization
To perform complicated tasks, many groups of tissues work together as an organ.
Each type of tissue performs an essential task to help the organ function.
In most cases, an organ completes a series of specialized tasks.
stomach
Lesson OverviewLesson Overview Homeostasis and CellsHomeostasis and Cells
A group of organs that work together to perform a specific function is called an organ system.
For example, the stomach, pancreas, and intestines work together as the digestive system.
Levels of Organization
Lesson OverviewLesson Overview Homeostasis and CellsHomeostasis and Cells
Levels of Organization
The organization of the body’s cells into tissues, organs, and organ systems creates a division of labor among those cells that allows the organism to maintain homeostasis.
Lesson OverviewLesson Overview Homeostasis and CellsHomeostasis and Cells
Cellular Communication
Cells in a large organism communicate by means of chemical signals that are passed from one cell to another.
These cellular signals can speed up or slow down the activities of the cells that receive them, and can cause a cell to change what it is doing.
Lesson OverviewLesson Overview Homeostasis and CellsHomeostasis and Cells
Cellular Communication
Some cells form connections, or cellular junctions, to neighboring cells. Some junctions hold cells firmly together. Other junctions allow small molecules carrying chemical messages to pass directly from one cell to the next.
To respond to one of these chemical signals, a cell must have a receptor to which the signaling molecule can bind. Sometimes these receptors are on the cell membrane; sometimes the are inside the cytoplasm.
The chemical signals sent by various types of cells can cause important changes in cellular activity. For example, such junctions enable the cells of the heart muscle to contract in a coordinated fashion.