Cell Transport and Homeostasis PDF

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This document is a lecture from Gulf Medical University on cell transport and homeostasis, describing the structure and function of cell organelles like the cell membrane and nucleus, as well as different transport mechanisms within the cell.

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Cell and transport mechanism,
Homeostasis

Dr.Rasha Eldeeb
Associate Professor of Physiology

www.gmu.ac.ae COLLEGE OF HEALTH SCIENCES
 Cell and transport mechanism,
Homeostasis
Learning Objectives:
Describe the general characteristics of
cells
Describe the structure of the plasma
membrane (Fluid Mosaic Model)
Describe the structure and function of
the different cell organelles.
Enlist the different types of transport
mechanisms existing across the cell
membrane and explain the
mechanism of each
Define Homeostasis and explain its
mechanism
 What Is Physiology?
It is the branch of biology that studies the functions and vital processes of living
organisms.

It explains the physical and chemical factors responsible for life's origin,
development, and progression.
 Why Do We Study Physiology?
To understand the physiologic principle that underlies normal function to cure
impairments
Distinguish between Process & Function

Physiology Integrate both to complete the picture!
 What You Should Know is…
The Human body is organized from
cells to organs
The organ systems operate as
integrated units
The human body needs a constant
internal environment to perform its
function properly
Physiology deals with the
mechanisms that maintain a stable
internal environment despite the
changes in the external
environment (Homeostasis)
What is the structural and Functional Unit
of life?
The Cell
The Cell
 The Cell Membrane
The cell membrane (plasma membrane) is a thin,
elastic, and semipermeable barrier between the cell
and its surroundings.
Its Lipid bilayer consists of phospholipids and
cholesterol, only 2 molecules thick, and continuous
over the entire cell surface. Each molecule has :
– Head: is the phosphate portion of phospholipids
that are charged ( polarized) and soluble in water
(hydrophilic).
– Tail: is the lipid portion of phospholipids, that is
uncharged (non-polarized) and relatively insoluble
in water (hydrophobic)
The hydrophilic ends are exposed to H2O present
outside [extracellular fluid (ECF)] and inside
[intracellular fluid (ICF)] the cell, while the hydrophobic
ends meet in the water-poor interior of the membrane.
 The Cell Membrane
Proteins: 55% They do not form a continuous layer as lipids but, they
exist as globular units that may be either :
– Integral proteins: that extend through the whole thickness of the
membrane.
– Peripheral proteins: They are attached to the surface of the cell
membrane either from inside or from outside i.e. they do not
penetrate the whole thickness of the membrane.

The functions of cell membrane proteins
▪ Structural proteins (lipoproteins and glycoproteins)
▪ Pumps (Na+/K+ pump)
▪ Receptors (for hormones, chemical transmitters,….)
▪ Carriers (glucose transporters)
▪ Enzymes (adenyl cyclase enzyme)
▪ Ion channels (Na +, K+, and Ca2+ channels)
▪ Tissue typing, and antibody processing (immunity)

Carbohydrates: 3%: They are either combined with proteins
(glycoproteins) or with lipids (glycolipids). When they cover the whole
membrane, they are called glycocalyx.
 The Cell Membrane

The functions of the Cell Membrane

Regulate the passage of substance into and out of cells

Detect chemical messengers arriving at the cell surface

Link adjacent cells together by membrane junctions

Anchor a variety of proteins, including intracellular and
extracellular protein filaments involved in the generation
and transmission of force, to the cell surface
 The Nucleus

Usually, it is the largest organelles
It is bounded by a nuclear membrane (envelope) with pores
It controls the normal cell function
Contains the DNA in chromosomes
Each cell has a fixed number of chromosomes that carry genes
The genes control cell characteristics
What is inside the nucleus?

It is the largest structure present inside the boundaries
of the nucleus

It is the dark staining zone in the center of the nucleus

It is the place where intensive synthesis of ribosomal
RNA takes place

Its main components are ribonucleic acid (RNA),
deoxyribonucleic acid (DNA) and proteins
What is inside the nucleus?

The genetic material (DNA) is found which is the
hereditary material of the cell
DNA is spread out and appears as Chromatin in
non-dividing cells
DNA is condensed and wrapped around proteins
forming as Chromosomes in dividing cells
 Cell Organelles

Mitochondria Endoplasmic reticulum Ribosomes
It contains its DNA; It is Two types: It contains two sub-units
mDNA, RNA, and
ribosomes. 1. Smooth- ribosome free It is the site of protein
synthesis; therefore, it is
It produces high- - detoxify drugs and pesticides. considered ad the Protein
energy compound -absorb, synthesize, and transport fat factory of the cell
ATP
-break down glycogen to form glucose. It is either free-floating or
It is the Powerhouse attached to the
of the cell. 2. Rough - contains ribosomes: it manufactures proteins. Endoplasmic Reticulum.
 Cell Organelles

Golgi Apparatus Lysosomes Cytoskeleton
It is a membrane-bound organelle It is the framework of the cell
It is a series of flattened sacs containing a variety of enzymes. It contains small microfilaments and
that modifies, packages, It contains digestive enzymes larger microtubules.
stores, and transports They support the cell, giving it its
materials out of the cell. It helps digest food particles inside or
outside the cell. shape and helping with the
Works with the ribosomes movement of its organelles.
and Endoplasmic Reticulum. They are called suicide bags
 The Cytoskeleton

MICROTUBULES
It is a hollow tube present in all cell types except RBCs
It is responsible for the intracellular movement of cytoplasmic
Organelles
It forms Cilia and Flagella

MICROFILAMENTS
It is attached to the cytoplasmic side of the Plasma Membrane
It strengthens the cell surface

INTERMEDIATE FILAMENTS
It is tough, insoluble protein fiber with strength
It resists pulling forces on the cell
 The Cellular Extensions

Microvilli: Tubular extensions of the plasma membrane
which contain actin filaments
Stereocilia: Modified Microvilli seen on the cells in the
Epididymis
Cilia are shorter and more numerous in cells; they move in
a single direction across the cell pair
Flagella are longer and fewer (usually 1-3) on cells
What is the difference between Cytosol
and Cytoplasm?
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 TRANSPORT MECHANISMS
Solutes (e.g. ions, glucose, gases
…… etc) can cross the cell
membrane by:
▪ Diffusion: either simple or facilitated
▪ Active transport: either primary or
secondary
▪ Endocytosis and exocytosis

Solvents (e.g. H2O) can pass across
the cell membrane by:
▪ Filtration
▪ Osmosis
 Transport of Solutes
Diffusion
It is a passive process substance in a solution (or in a gas) that expands to occupy all the available volume.
It is produced by the kinetic motion of the molecules, and it occurs in the direction of their concentration gradient.
This occurs through either the lipid bilayer or the proteins embedded in it (transport proteins), depending on the:
molecular size, lipid solubility, and charge of the substance.
Generally, diffusion across cell membranes can be divided into 2 main types:

Simple diffusion
It occurs through the lipid bilayer. The following substances can diffuse through the lipid bilayer of cell membranes:
Lipid-soluble substances (e.g. O2, N2, and alcohols), Water, Small uncharged water-soluble molecules (which cross the
lipid bilayer along with water molecules) e.g. CO2 (which is also lipid soluble).
Diffusion is directly related to Lipid solubility, Concentration gradient, Surface area, Temperature.
Diffusion is inversely related to the thickness of the membrane and the Molecular weight.
Facilitated diffusion
This mechanism moves substances passively in the direction of their chemical (concentration) gradient, but it requires a
type of transport protein
The molecules of substances that diffuse by this mechanism (e.g. glucose and most amino acids)
The facilitated diffusion is regulated by hormones
 Different types of Carriers

If the carrier transports only If the carrier transports two If the carrier transports two
one molecule, it is called molecules (Cotransport) in the molecules (Cotransport) in
uniport [e. g. glucose same direction it is called opposite directions, it is called
transporters (GLUT1, symport e.g. Na-dependent antiport (Counter transport)
GLUT2,….) glucose transport e.g. Cl-/HCO3- exchange.
Transport of Solutes

Active Transport

Primary active transport
It is the transport of substances against their electrical or concentration gradients (i.e.
from a lower to a higher concentration.
It requires: Specific carrier proteins and Energy (provided only by hydrolysis of ATP)
Examples: Na+ - K+ pump (Na+/K+ ATPase),Ca2+ pump ,H+ pump (proton pump).

Secondary active transport
It is the cotransport of Na+ down its electrochemical gradient (created by the primary active
transport) and another substance (e.g. glucose or amino acids) by a carrier protein
(symport).
Example: Sodium-dependent glucose transport (glucose absorption in the intestine and
glucose reabsorption in the kidney).
 Remember -Na+ - K+ pump
In the cell membrane, there are carrier proteins that
have:
– Three receptor sites for Na+ from inside
– Two receptor sites K+ from outside.
– The inside part (near mitochondria) has ATPase
activity.
So, three Na+ ions will bind to the carrier from inside,
while two K+ ions will bind from outside. This will
activate the ATPase carrier leading to hydrolysis of ATP
liberating the energy. This energy causes configuration
change in the carriers pushing Na+ to outside and K+ to
inside the cell [i.e. it has a coupling ratio of 3/2].
Function of Na+ - K+ pump:
– Electrogenic pump; creates more positivity
outside the cell (and more negativity inside).
– Controls the cell volume.
 Endocytosis and Exocytosis
Both pinocytosis and phagocytosis are called
Endocytosis.
Pinocytosis (Cell Drinking): This is a transport
mechanism by which large particles. The particle at
first contacts the cell membrane, then, the latter is
depressed, and, on each side, it rises and folds over
the particle (which will thus become a vacuole inside
the cytoplasm, the wall of which is made of a part of
the cell membrane).
Phagocytosis (Cell Eating) It is a process by which
bacteria and dead tissue are engulfed by cells, and
ingested.
Exocytosis (Cell Vomiting): This is the reverse of
endocytosis. The membrane of the granule or vesicle
fuses with the cell membrane, then the area of fusion
breaks down and its contents are expelled outside the
cell while the cell membrane remains intact.
 Filtration
Filtration is the passive movement of water
through a porous membrane due to a difference
in hydrostatic pressure on the two sides of the
membrane [e.g. formation of interstitial (tissue)
fluid through the capillary membrane and
glomerular filtrate in nephrons].

The amount of fluid filtered per time unit is
directly proportional to the:
▪ Pressure gradient
▪ Surface area of the membrane
▪ Membrane permeability
▪ Dissolved molecules (solutes) with smaller
diameters than the pores pass with the
filtered fluid.
 Osmosis
Osmosis is the passive movement of water through a semipermeable
membrane from an area containing pure water or a diluted solution of
a solute (NaCl or glucose) to an area in which there is a higher
concentration of solute (the membrane is impermeable to the solute
and permeable to the solvent).
The pressure required to apply the concentrated solution to prevent
water movement from the diluted solution is called the osmotic
pressure.
The amount of osmotic pressure is directly proportional to the
number of particles per unit volume of solution. So, ionizing
solutes (e.g. NaCl) are more osmotically active (because each
ion is active by itself) than non-ionizable solutes (e.g. glucose).
The osmotic pressure is expressed in osmoles or milliosmoles
which can be converted to mmHg, since one milliosmole =
about 19.3 mmHg.
 The osmolarity of a certain solution is the number of osmoles per liter of this
solution, while its osmolality is the number of osmoles per kilogram of solvent.
In the body, the osmotically-active substances are dissolved in water (= solvent),
and are usually measured and are expressed in milliosmoles per liter of water
(since water density is 1).
All body fluids have the same osmolality =290 milliosmoles/liter.
Solutions that have an osmolality equal to that of the plasma are called isotonic
solutions, while those having a higher osmolality are hypertonic, and those having a
lower osmolality are hypotonic.
A 0.9% NaCl solution is isotonic with the plasma and is known as the isotonic (or
physiological) saline solution.
Remember
Transport aims to
maintain
homeostasis
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 What is Homeostasis?
Is to maintain the physical and chemical composition of the internal environment (Extracellular Fluid)
constant despite the changes in the external environment

It is a vital concept in human physiology

Normal Physiological ranges in fasting blood :
▪ Arterial pH 7.35-7.45
▪ O2 content 17.2-22.0 ml/100 ml
▪ Glucose75-110 mg/100 ml
 Regulation of the Body Functions
Regulation- the ability of an organism to maintain a stable internal
condition in a constantly changing environment, done by:

▪ Chemical (hormonal) Regulation: a regulatory process
performed by hormone or active chemical substance in blood or
tissue. It responds slowly, acts extensively, and lasts for a long
time

▪ Nervous Regulation process in which body functions are
controlled by the nervous system. It responds fast; acts exactly
or locally, lasts for a short time

▪ Auto-regulation: a tissue or an organ can directly respond to
environmental changes that are independent of nervous and
hormonal control. The Amplitude of the regulation and the
Extension of the effects are smaller than the other two types.
 When the internal environment is disturbed by a stimulus either a successful
compensation occurs, and homeostasis is reestablished, or homeostasis Fail to
compensate, and the pathology appears (illness, death)
 Feedback
Homeostasis is maintained through the
regulatory process called “feedback”
A feedback loop is a cycle of events in which
a body condition (such as temperature) is
continually monitored and adjusted to be
within specific limits
The basic components of the feedback loop
are:
o Receptor : detects changes (stimuli) in
the body
o Control center : determines a set point
for a normal range, receives input from
the receptor, and sends output when
changes are needed
o Effectors': causes the response
determined by the control center
 There are two types of feedback loops:

Positive loops where the response enhances
the condition as it increases the action of the
control system; examples: blood clotting,
contraction of the uterus during childbirth
(parturition)

Negative loops where the response counteracts
or antagonizes the condition

Most feedback loops in the body are negative
feedback loops
Negative Feedback
Positive Feedback
Learning Resources:

1. Marieb EN. Human Anatomy and Physiology, 9th Edition, Pearson International Edition; 2014. ISBN-13: 978-1-2920-2649-7
2. Guyton, Arthur C. Textbook of medical physiology / Arthur C. Guyton, John E. Hall.—11th ed.
3. Ganong's Review of Medical Physiology/Kim E. Barrett, Susan M. Barman, Scott Boitano and Heddwen L.Brooks,23rd ed.
4. Instructional Web site
5. Lectures PDF on Moodle
6. https://www.clinicalkey.com/#!/content/book/3-s2.0-B9780702031144000026
 DISCLAMER

The contents of this presentation, can be used only for the purpose of a Lecture,
Scientific meeting or Research presentation at Gulf Medical University, Ajman.

www.gmu.ac.ae