3.1: Human Body Organization

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Learning Objectives

Identify the components of a cell.
Describe the cell membrane's structure and functions.
Describe the organization of the human body.

Cells

What distinguishes a living organism from an inanimate object? A living organism conducts self-sustaining biological processes. A cell is the smallest and most basic form of life. Robert Hooke, one of the first scientists to use a light microscope, discovered the cell in 1665. In all life forms, including bacteria, plants, animals, and humans, the cell was defined as the most basic structural and functional unit. Based on scientific observations over the next 150 years, scientists formulated the cell theory, which is used for all living organisms no matter how simple or complex. The cell theory incorporates three principles:

Cells are the most basic building units of life.
All living things are composed of cells.
New cells are made from preexisting cells, which divide into two.

Who you are has been determined because of two cells that came together inside your mother’s womb. The two cells containing all of your genetic information (DNA) united to begin making new life. As seen in Figure \(\PageIndex{1}\), cells divided and differentiated into other cells with specific roles that led to the formation of the body’s numerous body organs, systems, blood, blood vessels, bone, tissue, and skin. As an adult, you are comprised of trillions of cells. Each of your individual cells is a compact and efficient form of life—self-sufficient, yet interdependent upon the other cells within your body to supply its needs.

Image of one cell dividing into two cells. — Figure \(\PageIndex{1}\): One cell divides into two, which begins the creation of millions of more cells that ultimately become you. (Public Domain; National Institutes of Health).

An independent single-celled organism must conduct all the basic processes of life: it must take in nutrients (energy capture), excrete waste, detect and respond to its environment, move, breathe, grow, and reproduce. Even a one-celled organism must be organized to perform these essential processes. All cells are organized from the atomic level to all its larger forms. Oxygen and hydrogen atoms combine to make the molecule water (H₂O). Molecules bond together to make bigger macromolecules. The carbon atom is often referred to as the backbone of life because it can readily bond with four other elements to form long chains and more complex macromolecules. Four macromolecules—carbohydrates, lipids, proteins, and nucleic acids—make up all of the structural and functional units of cells.

Cell structure and function

Although we defined the cell as the “most basic” unit of life, it is structurally and functionally complex. A cell can be thought of as a mini-organism consisting of tiny organs called organelles. The organelles are structural and functional units constructed from several macromolecules bonded together. A typical animal cell contains the following organelles:

the nucleus (which houses DNA used to provide instructions for cells to make proteins)
mitochondria (which produces adenosine triphosphate (ATP), an energy molecule, from basic food components)
ribosomes (which produce proteins)
endoplasmic reticulum (which is important for modifying proteins and lipid synthesis)
golgi apparatus (which sorts, packages, and distributes proteins and lipids)
lysosomes and peroxisomes (little digestive pouches) which break down macromolecules and destroy foreign invaders

Drawing of a cell with the following internal organelles: nucleus, mitochondrion, ribosomes, endoplasmic reticulum, golgi apparatus, and lysosome. — Figure \(\PageIndex{2}\): The components of a cell.

As seen in (Figure \(\PageIndex{2}\)), all of the organelles are anchored in the cell’s cytoplasm. The cell’s organelles are isolated from the surrounding environment by a plasma (cell) membrane. The cell membrane defines the cell's boundaries and regulates what can enter and exit the cell. The cell membrane is comprised of two layers of phospholipids with cholesterol and various proteins scattered throughout. Watch the video below for a simple explanation of the cell membrane structure.

Human Body Organization

Single-celled organisms can function independently, but the cells of multicellular organisms are dependent upon each other and are organized into different levels in order to coordinate their specific functions and carry out all of life’s biological processes.

Atoms. Tiny units of matter.
Molecules. Groups of atoms. Food that we eat is composed of molecules. Digestion breaks food down into molecules that can be absorbed.
Cells. Cells are the basic structural and functional unit of all life. Examples include red blood cells and nerve cells.
Tissues. Tissues are groups of cells that share a common structure and function and work together. There are four types of human tissues:
- connective, which connects tissues;
- epithelial, which lines and protects organs;
- muscle, which contracts for movement and support; and
- nerve, which responds and reacts to signals in the environment.
Organs. Organs are a group of tissues arranged in a specific manner to support a common physiological function. Examples include the brain, liver, and heart.
Organ systems. Organ systems are two or more organs that support a specific physiological function. Examples include the digestive system and central nervous system. There are eleven organ systems in the human body (Table \(\PageIndex{1}\)).
Organism. An organism is the complete living system capable of conducting all of life’s biological processes.

Table \(\PageIndex{1}\): The Eleven Organ Systems in the Human Body and Their Major Functions
Organ System	Organ Components	Major Function
Circulatory	heart, blood/lymph vessels, blood, lymph	transport nutrients and waste products
Digestive	mouth, esophagus, stomach, intestines	digestion and absorption
Endocrine	all glands (thyroid, ovaries, pancreas)	produce and release hormones
Immune	white blood cells, lymphatic tissue, marrow	defend against foreign invaders
Integumentary	skin, nails, hair, sweat glands	protective, body temperature regulation
Muscular	skeletal, smooth, and cardiac muscle	body movement
Nervous	brain, spinal cord, nerves	interprets and responds to stimuli
Reproductive	gonads, genitals	reproduction and sexual characteristics
Respiratory	lungs, nose, mouth, throat, trachea	gas exchange
Skeletal	bones, tendons, ligaments, joints	structure and support
Urinary	kidneys, bladder, ureters	waste excretion, water balance

Drawing of the human body with approximate location of each organ system. — Figure \(\PageIndex{3}\): Organ systems in the human body, (© Networkgraphics)

An Organism Requires Energy and Nutrient Input

Energy is required in order to build molecules into larger macromolecules, and to turn macromolecules into organelles and cells, and then turn those into tissues, organs, and organ systems, and finally into an organism. Proper nutrition provides the necessary nutrients to make the energy that supports life’s processes. Your body builds new macromolecules from the nutrients in food.

Nutrient and Energy Flow

Energy is stored in a nutrient’s chemical bonds. As seen in Figure \(\PageIndex{4}\), energy comes from sunlight, which plants capture and (via photosynthesis) use this energy to transform carbon dioxide (CO₂) in the air into sugar (glucose). When the bonds in the glucose molecules are broken, energy is released. Bacteria, plants, and animals (including humans) harvest the energy in glucose via a biological process called cellular respiration. In this process the chemical energy of glucose is transformed into cellular energy in the form of adenosine triphosphate (ATP). Cellular respiration requires oxygen which is provided as a waste product of photosynthesis. The waste products of cellular respiration are carbon dioxide (CO₂) and water, which plants use to conduct photosynthesis again. Thus, energy is constantly cycling between plants and animals.

diagram of photosynthesis showing how plants capture energy from sunlight and use it to transform carbon dioxide in the air into glucose — Figure \(\PageIndex{4}\): Overview of photosynthesis. (CC BY-SA 4.0; Daniel Mayer via Wikimedia Commons)

In this section, we have learned that all life is composed of cells capable of transforming small organic molecules into energy. How do complex organisms such as humans convert the large macromolecules in the foods that we eat into molecules that can be used by cells to make cellular energy? In the next section, we will discuss the physiological process of digestion to answer this question.

Key Takeaways

The cell is the basic structural and functional unit of life. Cells are independent, single-celled organisms that take in nutrients, excrete waste, detect and respond to their environment, move, breathe, grow, and reproduce. The macromolecules (carbohydrates, proteins, lipids, and nucleic acids) make up all of the structural and functional units of cells.
In complex organisms, cells are organized into five levels so that an organism can conduct all basic processes associated with life.
There are eleven organ systems in the human body that work together to support life, all of which require nutrient input.
Energy is constantly cycling between plants and animals.

References

Chapter cover photo "Cute Digestive System" by Bentlie is licensed under CC BY-NC-ND 3.0.