Cell Membrane and Cytoplasm Functions PDF

Summary

This document describes the structure and function of cell membranes and cytoplasm, discussing transport mechanisms like diffusion, osmosis, and active transport. It also explains intercellular junctions and specific examples of these processes.

Full Transcript

- Structure and function of
Cytoplasm and Cell membrane.
- Study mechanisms of cell
transport through membrane.
- Types of intercellular
Junctions

Lecture 3
Dr. Zainab Almansour
 Cytoplasm
Cytoplasm is a thick solution that fills each cell and
is enclosed by the cell membrane.

- It is mainly composed of water, salts, and
proteins.

- a majority of cell organelles (ribosome, Golgi
apparatus, Endoplasmic Reticulum, etc) are
located in the cytoplasm.
 Function of Cytoplasm
Functions of the Cytoplasm:

Functions of the cytoplasm can be attributed to its
components. Some of these functions include:
1- Transport
2- Maintain the shape and structure of a cell
3- Protection
4- Storage
5- Site of metabolic activities
6- Cell movement
7- Cell Division
8- Cell growth
 Cytosol
Cytosol The cytosol is the intracellular fluid of the cytoplasm. It is largely composed of
water (over 70 percent) and surrounds all organelles located/suspended in the cytoplasm.

Cytosol Functions

- It involved in signal transduction originating from the cell membrane.

- It contributes to the transduction signaling from the plasma membrane to the nucleus

- The cytosol is also involved in the transportation of metabolites (e.g. amino acids in
eukaryotic cells) in addition to being the site of metabolic chemical reactions in
prokaryotes.

The difference between cytoplasm and cytosol lies in the fact that cytosol is the fluid
(intracellular fluid) of the cell while cytoplasm consists of all cell components within the cell
membrane (excluding the nucleus).
 Protoplasm
Protoplasm: The term protoplasm is used to refer to the cytoplasm and the
internal components of a cell in general. It consists of proteins, lipids,
sugars, and starches (carbohydrates), phosphates, potassium, and sodium
(inorganic salts) and water.

The difference between cytoplasm and protoplasm:

Whereas cytoplasm includes cell components within the cell (excluding the
nucleus) the term protoplasm is sometimes used to refer to all components
within the cell including the nucleus.
The difference between cytoplasm and
protoplasm
 Cell Membrane
The cell membrane, also known as the plasma membrane, is a double layer
of lipids and proteins that surrounds a cell.

- It separates the cytoplasm (the contents of
the cell) from the external environment.

- It is a feature of all cells, both prokaryotic
and eukaryotic.
 Function of Cell Membrane
Function of the Cell Membrane

- The cell membrane gives the cell its structure and regulates the materials
that enter and leave the cell.

- It is a selectively permeable barrier, meaning it allows some substances to
cross, but not others.

- The cell membrane also plays an
important role in cell signalling and
communication.
 Structure of Cell Membrane
- The cell membrane is made up of a phospholipid bilayer.
- Phospholipids are lipid molecules made up of a phosphate group head and
two fatty acid tails.

- The phosphate group head of a
phospholipid is hydrophilic, whereas the
phospholipid tail is hydrophobic. This means
that the phosphate group is attracted to
water, whereas the tail is repelled by water.
 Structure of Cell Membrane
- The cell membrane also contains many different proteins.

- Proteins make up about half of
the cell membrane.
- Many of these proteins are
transmembrane proteins, which
are embedded in the membrane.
- Membrane proteins perform a
variety of functions vital to the
survival of organisms.
 Mechanisms of cell transport through membrane

-All cells are enclosed by a cell membrane, which is selectively permeable.
-Molecules can move into or out of cells by diffusion and active transport.
-Cells can gain or lose water by osmosis.

There are two major ways that molecules can be
moved across a membrane:

Passive mechanisms like diffusion use no energy,
while active transport requires energy to get
done.
 Diffusion
Diffusion is the movement of a substance from an area of high concentration to an area of low
concentration.
Factors Affecting Diffusion
1- Temperature 2- Area of Interaction 3- Size of the Particle.
4- The steepness of the concentration gradient.
Significance of Diffusion
During the process of respiration, this process helps in diffusing the carbon dioxide gas out
through the cell membrane into the blood.
Diffusion also occurs in plant cells. In all green plants, water present in the soil diffuses into
plants through their root hair cells.
The movement of ions across the neurons that generates electrical charge is due to diffusion.
 Diffusion
- Diffusion is one form of passive transport that doesn’t
require the expenditure of cellular energy.
- A molecule can diffuse passively through the cell
membrane if it’s lipid-soluble, uncharged, and very small.
- The unassisted diffusion of very small or lipid-soluble
particles is called simple diffusion. The assisted process is
known as facilitated diffusion.
- Embedded in the membrane are transmembrane protein
molecules called channel proteins that create diffusion-
friendly openings for molecules to move through during the
facilitated diffusion
 Osmosis
Osmosis is a form of passive transport that’s similar to
diffusion and involves a solvent moving through a selectively
permeable or semipermeable membrane from an area of
higher concentration to an area of lower concentration.
- Solutions are composed of two parts: a solvent and a
solute.
The solvent is the liquid in which a substance is dissolved.
A solute is the substance dissolved in the solvent.
 Osmosis
Osmolarity is the term used to describe the concentration of solute particles per
litre.

An isotonic solution has the same concentration of
solute and solvent as found inside a cell.
A hypotonic solution has less solute and higher water
potential than inside the cell.
A hypertonic solution has more solute and lower water
potential than inside the cell.
Diffusion Vs Osmosis
Diffusion
 Active Transport
Active Transport is a process that involves the movement
of molecules from a region of lower concentration to a
region of higher concentration against a gradient or an
obstacle with the use of external energy.

There are two types of active transport :
1- Primary active transport that uses adenosine triphosphate (ATP).
2- Secondary active transport that uses an electrochemical gradient.
An example of active transport in human physiology is the uptake of
glucose in the intestines.
Active Transport
Passive Vs Active Transport
 Endocytosis
Endocytosis is the process of actively transporting molecules into the cell by
engulfing it with its membrane.

The material to be internalized is
surrounded by an area of cell membrane,
which then buds off inside the cell to
form a vesicle containing the ingested
material.
Endocytosis includes 1- pinocytosis (cell drinking) 2- phagocytosis (cell eating)
3- receptor- mediated endocytosis
 Exocytosis
Exocytosis is a form of active transport in which a cell transports molecules from
within a cell to the exterior of the cell by secreting them through an energy-
dependent process.
During exocytosis vesicles form in the cytoplasm and move to the surface of the cell
membrane.Then they merge with the membrane
and release their contents to the outside of the cell.
Exocytosis removes the cell’s waste products,
which are the parts of molecules that are not used
by the cell.
 Intercellular Junctions
Cell junctions (or intercellular bridges) are specialized regions of contact between the
plasma membranes of adjacent cells, consisting of multiprotein complexes that provide
contact between neighbouring cells or between a cell and the extracellular matrix.

Three different types of intercellular junctions can be distinguished according to their
function:

1- Tight or occluding junctions.

2- Adherent or anchoring junctions, including desmosomes and hemidesmosomes.

3- Gap junctions.