LESSON 3: THE CHARACTERISTICS OF BIOLOGICAL MEMBRANES

The development of a cell membrane around 3.8 billion years ago had profound ramifications for the development of life. The complex mosaic of macromolecule that make up cell and organelle membranes provides protection for the cell’s interior while regulating the cell’s interaction with its surroundings. In this module we will explore the structure of cell membranes using the fluid-mosaic model. We will also see how materials are transported across cell membranes by both passive and active transport mechanisms.

Learning Objectives

• Understand the importance of compartmentalization

• Know the structure of a typical phospholipid bilayer membrane

• Understand the various transport mechanisms and how the structure of the membrane helps make them possible

• Think about how membranes work in your own bodyUnderstand the importance of compartmentalization

Topics covered in this Lesson

• Biological Membranes

• Diffusion/Passive Transport

• Active Transport

• Direct Cell-Cell Connections

Biological Membranes

Biological membranes are essential to life, whether they surround individual cells, or the organelles inside of eukaryotic cells. Membranes are active structures, composed of lipids, proteins and carbohydrates, that help maintain an internal environment distinct from the external environment of the cell or organelle.

Learning Objectives

• Understand the fluid-mosaic model of membrane structure.

• Understand that membranes encompass eukaryotic and prokaryotic cells, and many organelles of eukaryotic cells.

• Know that membranes are primarily composed of phospholipids, but proteins and carbohydrates also play essential roles in membranes.

• Understand the basic structure of a phospholipid, and how its two regions affect the structure of biological membranes.

• Understand the difference between integral and peripheral membrane proteins.

• Know some of the basic roles that carbohydrates and proteins play as a part of membranes.

Diffusion/Passive Transport

One of the most essential roles of membranes is controlling what substances are able to cross it. Some substance, such as ions, are able to diffuse across membranes through protein channels when the channels are open. Other, larger substances, require slightly different membrane proteins to move across a membrane.

When substances move across a membrane toward either chemical or electrical equilibrium, the movement typically requires no net input of energy. Both diffusion and passive transport are instances of such movement.

Learning Objectives

• Understand that substances tend to diffuse toward equilibrium.

• Be able to describe how membranes are selectively permeable.

• Know why small, non-polar molecules may move directly across membranes without any aid.

• Know why larger or polar molecules only move across membranes with the aid of integral membrane proteins.

• Understand the process of osmosis as the diffusion of water from areas of high concentration (low solute concentration) to areas of low concentration (high solute concentration)

• Understand the difference between hypotonic, isotonic, and hypertonic solutions.

• Understand the characteristics of ion channels and how they work to allow the diffusion of ions across a membrane.

• Understand how carrier proteins work to transport molecules across membranes, and how they differ from ion channels.
   

Active Transport

Cells cannot rely solely on passive movement of substances across their membranes. In many instances, it is necessary to move substances against their electrical or chemical gradient to maintain the appropriate concentrations inside of the cell or organelle. Moving substances against their gradient requires energy, because they are being moved away from equilibrium. Cells use two different types of active transport, which directly or indirectly require ATP, to move substances in this way. Both types of active transport require integral membrane proteins.

Cells must occasionally move very large particles, such as food particles or volumes of water, across their membranes. Cells do this by processes called endocytosis and exocytosis, where the substance to be transported is surrounded by an infolding of the cell membrane.

Learning Objectives

• Understand the fundamental differences between active and passive transport processes.

• Know the differences and similarities between uniports, symports, and antiports.

• Understand the role of ATP in active transport processes.

• Describe the sodium-potassium pump as an example of primary active transport.

• Be able to explain why secondary active transport depends on primary active transport, using transport of glucose as an example.

• Describe the basic processes of endocytosis, including phagocytosis, pinocytosis and receptor-mediated endocytosis, and exocytosis.
  

Direct Cell-Cell Connections

In multicellular organisms, directly adjacent cells are often physically connected to each other. Some of these connections are channels from cell to cell, through which small substances, such as ATP or signal molecules, may pass. Plants (and protists), fungi and animals all have specific types of channels connecting the cytoplasm of neighboring cells.

Learning Objectives

• Understand the benefits of having cytoplasmic connections between the cells of a multicellular organism.

• Know the basic characteristics of gap junctions, plasmodesmata and pores, and in which types of organisms each is found.

   

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