THE CELL MEMBRANE_ Pharmaceutical Biochemistry (lab)-KEROVILLOS.pdf

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THE CELL MEMBRANE

 THE CELL MEMBRANE

The plasma membrane not only defines the borders of the cell, but also allows the cell
to interact with its environment in a controlled way. Cells must be able to exclude, take
in, and excrete various substances, all in specific amounts. In addition, they must able
to communicate with other cells, identifying themselves and sharing information.

To perform these roles, the plasma membrane needs lipids, which make a semi-
permeable barrier between the cell and its environment. It also needs proteins, which
are involved in cross-membrane transport and cell communication, and carbohydrates
(sugars and sugar chains), which decorate both the proteins and lipids and help cells
recognize each other.

 FLUID MOSAIC MODEL

The currently accepted model for the structure of the plasma membrane, called the fluid
mosaic model, was first proposed in 1972. This model has evolved over time, but it still
provides a good basic description of the structure and behavior of membranes in many
cells.

According to the fluid mosaic model, the plasma membrane is a mosaic of components
—primarily, phospholipids, cholesterol, and proteins—that move freely and fluidly in the
plane of the membrane. In other words, a diagram of the membrane (like the one
below) is just a snapshot of a dynamic process in which phospholipids and proteins are
continually sliding past one another.

Interestingly enough, this fluidity means that if you insert a very fine needle into a cell,
the membrane will simply part to flow around the needle; once the needle is removed,
the membrane will flow back together seamlessly.
 Figure 1.3. The structure of the plasma membrane.

The principal components of the plasma membrane are lipids (phospholipids and
cholesterol), proteins, and carbohydrate groups that are attached to some of the lipids
and proteins.

A phospholipid is a lipid made of glycerol, two fatty acid tails, and a phosphate-
linked head group. Biological membranes usually involve two layers of phospholipids
with their tails pointing inward, an arrangement called a phospholipid bilayer.
Cholesterol, another lipid composed of four fused carbon rings, is found alongside
phospholipids in the core of the membrane.
Membrane proteins may extend partway into the plasma membrane, cross the
membrane entirely, or be loosely attached to its inside or outside face.
Carbohydrate groups are present only on the outer surface of the plasma
membrane and are attached to proteins, forming glycoproteins, or lipids, forming
glycolipids.

The proportions of proteins, lipids, and carbohydrates in the plasma membrane vary
between different types of cells. For a typical human cell, however, proteins account for
about 50 percent of the composition by mass, lipids (of all types) account for about 40
percent, and the remaining 10 percent comes from carbohydrates.
  STRUCTURE OF THE CELL MEMBRANE

Phospholipids

Phospholipids, arranged in a bilayer, make up the basic fabric of the plasma membrane.
They are well-suited for this role because they are amphipathic, meaning that they have
both hydrophilic and hydrophobic regions.

Figure 1.4. Chemical structure of a phospholipid, showing the hydrophilic head and hydrophobic tails.

The hydrophilic, or “water-loving,” portion of a phospholipid is its head, which contains
a negatively charged phosphate group as well as an additional small group (of varying
identity, “R” in the diagram at left), which may also or be charged or polar. The
hydrophilic heads of phospholipids in a membrane bilayer face outward, contacting the
aqueous fluid both inside and outside the cell. Since water is a polar molecule, it readily
forms electrostatic interactions with the phospholipid heads.

The hydrophobic, or “water-fearing,” part of a phospholipid consists of its long,
nonpolar fatty acid tails. The fatty acid tails can easily interact with other nonpolar
molecules, but they interact poorly with water. Because of this, it’s more energetically
favorable for the phospholipids to tuck their fatty acid tails away in the interior of the
membrane, where they are shielded from the surrounding water. The phospholipid
bilayer formed by these interactions makes a good barrier between the interior and
exterior of the cell, because water and other polar or charged substances cannot easily
cross the hydrophobic core of the membrane.

Proteins

Proteins are the second major component of plasma membranes. There are two main
categories of membrane proteins: integral and peripheral.

Integral membrane proteins are, as their name suggests, integrated into the
membrane: they have at least one hydrophobic region that anchors them to the
hydrophobic core of the phospholipid bilayer. Some stick only partway into the
membrane, while others stretch from one side of the membrane to the other and are
exposed on either side. Proteins that extend all the way across the membrane are
called transmembrane proteins.

The portions of an integral membrane protein found inside the membrane are
hydrophobic, while those that are exposed to the cytoplasm or extracellular fluid tend to
be hydrophilic. Transmembrane proteins may cross the membrane just once, or may
have as many as twelve different membrane-spanning sections. A typical membrane-
spanning segment consists of 20-25 hydrophobic amino acids arranged in an alpha
helix, although not all transmembrane proteins fit this model. Some integral membrane
proteins form a channel that allows ions or other small molecules to pass, as shown
below.

Figure 1.5. The proteins found on the cell membrane.
Peripheral membrane proteins are found on the outside and inside surfaces of
membranes, attached either to integral proteins or to phospholipids. Unlike integral
membrane proteins, peripheral membrane proteins do not stick into the hydrophobic
core of the membrane, and they tend to be more loosely attached.

Carbohydrates

Carbohydrates are the third major component of plasma membranes. In general, they
are found on the outside surface of cells and are bound either to proteins (forming
glycoproteins) or to lipids (forming glycolipids). These carbohydrate chains may consist
of 2-60 monosaccharide units and can be either straight or branched.

Along with membrane proteins, these carbohydrates form distinctive cellular markers,
sort of like molecular ID badges, that allow cells to recognize each other. These markers
are very important in the immune system, allowing immune cells to differentiate
between body cells, which they shouldn’t attack, and foreign cells or tissues, which they
should.

Membrane fluidity

The structure of the fatty acid tails of the phospholipids is important in determining the
properties of the membrane, and in particular, how fluid it is.

Saturated fatty acids have no double bonds (are saturated with hydrogens), so they
are relatively straight. Unsaturated fatty acids, on the other hand, contain one or more
double bonds, often resulting in a bend or kink. The saturated and unsaturated fatty acid
tails of phospholipids behave differently as temperature drops:

At cooler temperatures, the straight tails of saturated fatty acids can pack tightly
together, making a dense and fairly rigid membrane.
Phospholipids with unsaturated fatty acid tails cannot pack together as tightly
because of the bent structure of the tails. Because of this, a membrane containing
unsaturated phospholipids will stay fluid at lower temperatures than a membrane
made of saturated ones.

Most cell membranes contain a mixture of phospholipids, some with two saturated
(straight) tails and others with one saturated and one unsaturated (bent) tail. Many
organisms—fish are one example—can adjust physiologically to cold environments by
changing the proportion of unsaturated fatty acids in their membranes. For more
information about saturated and unsaturated fatty acids, see the article on lipids.
In addition to phospholipids, animals have an additional membrane component that
helps to maintain fluidity. Cholesterol, another type of lipid that is embedded among the
phospholipids of the membrane, helps to minimize the effects of temperature on fluidity.

At low temperatures, cholesterol increases fluidity by keeping phospholipids from
packing tightly together, while at high temperatures, it actually reduces fluidity. In this
way, cholesterol expands the range of temperatures at which a membrane maintains a
functional, healthy fluidity.