Post Laboratory Notes: The Cell PDF

Summary

This document is a set of post-laboratory notes on cell biology, providing detailed descriptions and functions of various cell parts, such as the plasma membrane, nucleus, and ribosomes. It features diagrams and illustrations to aid comprehension.

Full Transcript

POST LABORATORY NOTES

THE CELL

Cell Parts Descrip
on Func
on
Plasma Membrane Lipid bilayer composed of Func
ons as the outer
phospholipids and cholesterol; boundary of the cell; controls
proteins extend across or are the entry and exit of
embedded in either surface of the substances; receptor proteins
lipid bilayer func
on in intercellular
communica
on; marker
molecules enable cells to
recognize one another
Nucleus Enclosed by nuclear envelope, a Is the control center of the cell;
double membrane with nuclear DNA within the nucleus
pores; contains chroma
n regulates protein (e.g.,
(dispersed, thin strands of DNA enzyme) synthesis and
and associated proteins), which therefore the chemical
condenses to become visible reac
ons of the cell
mito
c chromosomes during cell
division; also contains one or
more nucleoli, dense bodies
consis
ng of ribosomal RNA and
proteins
Cytoplasmic Organelles
Ribosome Ribosomal RNA and proteins form Serves as site of protein
large and small subunits; some are synthesis
atached to endoplasmic
re
culum, whereas others (free

By: Deannise Ann Boco, RMT
POST LABORATORY NOTES

ribosomes) are distributed
throughout the cytoplasm
Rough Endoplasmic Membranous tubules and Synthesizes proteins and
Re
culum flatened sacs with transports them to Golgi
atached ribosomes apparatus
Smooth Endoplasmic Membranous tubules and Manufactures lipids and
Re
culum flatened sacs with no atached carbohydrates; detoxifies
ribosomes harmful chemicals; stores
calcium
Golgi Apparatus Flatened membrane sacs stacked Modifies, packages, and
on each other distributes proteins and lipids
for secre
on or internal use
Lysosome Membrane-bound vesicle pinched Contains diges
ve enzymes
off Golgi apparatus
Peroxisome Membrane-bound vesicle Serves as one site of lipid and
amino acid degrada
on; breaks
down hydrogen peroxide
Proteasomes Tubelike protein complexes in the Break down proteins in the
cytoplasm cytoplasm
Mitochondria Spherical, rod-shaped, or Are major sites of ATP
threadlike structures; synthesis when oxygen is
enclosed by double membrane; available
inner membrane forms
projec
ons called cristae
Centrioles Pair of cylindrical organelles Serve as centers for
consis
ng of triplets of parallel microtubule forma
on;
microtubules; located in the determine cell polarity during
centrosome, a specialized area of cell division; form the basal
the cytoplasm where microtubule bodies of cilia and flagella
forma
on occurs
Cilia Extensions of the plasma Move materials over the
membrane containing doublets of surface of cells
parallel microtubules; 10 μm in
length
Flagellum Extension of the plasma In humans, propels
membrane containing doublets of spermatozoa
parallel microtubules; 55 μm in
length
Microvili Extensions of the plasma Increase surface area of the
membrane containing plasma membrane for
microfilaments absorp
on and secre
on;
modified to form sensory
receptors

Fluid Mosaic Model

By: Deannise Ann Boco, RMT
POST LABORATORY NOTES

Fluid Mosaic Model: describes the plasma membrane as being neither rigid nor sta
c in structure.

By: Deannise Ann Boco, RMT
POST LABORATORY NOTES

MEMBRANE PHYSIOLOGY: FACTORS AFFECTING DIFFUSION:

DIFFUSION: a passive process in which the random mixing of par
cles in a solu
on occurs because of
the par
cles’ kine
c energy. Both the solutes, the dissolved substances and the solvent, the liquid that
does the dissolving, undergo diffusion.
 If a par
cular solute is present in high concentra
on in one area of a solu
on, and in low
concentra
on in another area, solute molecules will diffuse toward the area of lower
concentra
on—they move down their concentra
on gradient.

FACTORS THAT AFFECT RATE OF DIFFUSION:
 Steepness of the concentra
on gradient – the greater the difference in concentra
on between
the two sides of the membrane, the higher is the rate of diffusion.
 Temperature – the higher the temperature, the faster the rate of diffusion. (All of the body’s
diffusion processes occur more rapidly in a person with a fever)
 Surface Area – the larger the membrane surface area available for diffusion, the faster is the
diffusion rate.

By: Deannise Ann Boco, RMT
POST LABORATORY NOTES

 Diffusion Distance – the greater the distance over which diffusion must occur, the longer it
takes.
SIMPLE DIFFUSION:
 a passive process in which substances move freely through the lipid bilayer of the plasma
membrane of cells without
 the help of membrane transport proteins.
 Non-polar, hydrophobic molecules move across the lipid bilayer through the process of simple
diffusion.
 Example: O2, CO2, Nitrogen gases; faty acids; steroids; and fat-soluble vitamins (A, D, E, and K).
 Small, uncharged polar molecules such as water, urea, and small alcohols pass through the lipid
bilayer by simple diffusion.

FACILITATED DIFFUSION:
 In this process an integral membrane protein
assists a specific substance across the membrane.
 Integral membrane protein could either be a
membrane channel or a carrier.
 Solutes that are too polar or highly charged to
move through the lipid bilayer by simple diffusion
can cross the plasma membrane through
facilitated diffusion.

A. CHANNEL-MEDIATED FACILITATED DIFFUSION
 A solute moves down its concentra
on gradient
across the lipid bilayer through a membrane channel.
 Most membrane channels are ion channels.
 Ion channels are integral membrane proteins that allow passage of small
inorganic ions that are too hydrophilic to penetrate the nonpolar interior of the lipid bilayer.
Each ion can diffuse across the membrane only at certain sites.
 Most ions are selec
ve for potassium or chloride ions; fewer channels are available for sodium
and calcium ions.
 Diffusion of ions through channels is generally slower than free diffusion through the lipid
bilayer, due to channels occupying a smaller frac
on of the membrane’s total surface area than
lipids.
 “Gated” channel – when part of the channel protein
acts as a “plug” or “gate”, changing its shape in one
way to open the port and in another way to close it.
Some alternate between open and closed posi
ons,
while others are regulated by chemical or electrical
changes inside and outside of the cell.
 When the gates of a channel are open – ions diffuse
into or out of the cells down their electrochemical
gradients.

By: Deannise Ann Boco, RMT
POST LABORATORY NOTES

B. CARRIER-MEDIATED FACILITATED DIFFUSION
 A carrier moves a solute down its concentra
on gradient across the plasma membrane.
 The solute binds to a specific carrier on one side of the
membrane and is released on the other side a
er the
carrier undergoes a change in shape.
 The solute binds more o
en to the carrier on the side of
the membrane with a higher concentra
on of solute.
 Once the concentra
on is the same on both sides, the
solute molecules bind to the carrier on the cystolic side
and move out to the extracellular fluid as rapidly as they
bind to the carrier on the extracellular side and move
into the cytosol.
 The rate of carrier-mediated facilitated diffusion is
determined by the steepness of the concentra
on
gradient across the membrane.
 The number of carriers available in a plasma membrane
places an upper limit, called Transport Maximum.
 Once all the carriers are occupied, the transport maximum is reached, the process of carrier-
mediated facilitated diffusion exhibits satura
on.
 Substances: glucose, fructose, galactose, and some vitamins.

ACTIVE TRANSPORT:
- Considered an ac
ve process because energy is required for carrier proteins to move solutes across the
membrane against a concentra
on gradient.

Two sources of cellular energy:
A. Energy obtained from hydrolysis of ATP. (Primary Ac
ve Transport)
B. Energy stored in an ionic concentra
on gradient. (Secondary Ac
ve Transport)

A. PRIMARY ACTIVE TRANSPORT
 Energy derived from hydrolysis of ATP changes the shape of a carrier protein, which “pumps” a
substance across a plasma membrane against its concentra
on gradient.
 Pumps – carrier proteins that mediate
primary ac
ve transport.
 Sodium-Potassium Pump – most prevalent
primary ac
ve transport mechanism that
expels sodium ions from cells and brings
potassium ions in.
 Other name is Sodium-Potassium ATPase.
 Maintain a low concentra
on of sodium ions in the cytosol by pumping these ions oon to the
extracellular fluid against the sodium concentra
on gradient. At the same
me, the pumps
move potassium into the cells against the potassium concentra
on gradient.

By: Deannise Ann Boco, RMT
POST LABORATORY NOTES

 The different concentra
ons of sodium and potassium in the cytosol and extracellular fluid are
crucial for maintaining normal cell volume and for the ability of some cells to generate electrical
signals such as ac
on poten
als.

B. SECONDARY ACTIVE TRANSPORT
 Mechanisms uses the energy stored in an ionic concentra
on gradient. Because primary ac
ve
transport pumps that hydrolyze ATP maintain the gradient, secondary ac
ve transport
mechanisms consume ATP indirectly.
 A carrier protein simultaneously binds to sodium and another substance and then changes its
shape so that both substances cross the membrane at the same
me.
 Symporters – transporters that move two substances in the same direc
on.
 An
porters – moves two substances in opposite direc
on across the membrane.

ENDOCYTOSIS
Three types of endocytosis:
a. Receptor-Mediated Endocytosis- highly selec
ve type of endocytosis by which cells take up
specific ligands (molecules that bind to specific receptors).
PROCESS:
 Binding
 Vesicle forma
on
 Uncoa
ng
 Fusion with endosome
 Recycling of receptors to plasma membrane
 Degrada
on in lysosomes

b. Phagocytosis – form of endocytosis in which the cell engulfs large solid par
cles, such as worn-
out cells, bacteria, or viruses.
 Phagocytes – cells that are able to carry out
phagocytosis.
Two types of Phagocytes:
 Macrophages – located in many body
ssues.
 Neutrophils – a type of WBC. PROCESS:
 Par
cle binds to a plasma membrane receptor on
the phagocyte causing it to extend pseudopods
(projec
ons of plasma membrane and cytoplasm)
 Pseudopods surround the par
cle outside the cell,
and the membranes fuse to form a vesicle called
phagosome.
 The phagosome fuses with one or more
lysosomes, and lysosomal enzymes break down
the ingested material.
 Any undigested material in the phagosome remain indefinitely in a vesicle called a
residual body.
 The residual bodies are then either secreted by the cell via exocytosis or they remain

By: Deannise Ann Boco, RMT
POST LABORATORY NOTES

stored in the cell as lipofuscin granules.

c. Bulk-phase endocytosis/Pinocytosis – a form of endocytosis in
which
ny droplets of extracellular fluid are taken up.
 During pinocytosis, the plasma membrane folds inward and
forms a vesicle containing a droplet of extracellular fluid.
The vesicle detaches or “pinches off” from the plasma
membrane and enters the cytosol.
 Within the cell, the vesicle fuses with a
lysosome, where enzymes degrade the
engulfed solutes.
 The resul
ng smaller molecules, such as amino acids, and FA,
leave the lysosome to be used elsewhere in the cell.
 Pinocytosis occurs in most cells, especially absorp
ve cells in
the intes
nes and kidneys.

Exocytosis
 Releases materials from a cell.
 All cells carry out exocytosis.
Two types of cells:
1. Secretory cells – liberate diges
ve enzymes, hormone, mucus, or other secre
ons.
2. Nerve cells – release substances called neurotransmiters.
 In some cases, wastes are also released by exocytosis.
 During exocytosis, membrane-enclosed vesicles called secretory vesicles form inside the cell,
fuse with the plasma membrane and release their contents into the extracellular fluid.

TRANSCYTOSIS
 Vesicles undergo endocytosis on one side of a cell, move across the cell, and then undergo
exocytosis on the opposite side. As the vesicles fuse with the plasma membrane, the vesicular
contents are released into the extracellular fluid.
 Transcytosis occurs most often across the endothelial cells that line blood vessels and is
a means for materials to move between blood plasma and interstitial fluid.

By: Deannise Ann Boco, RMT
POST LABORATORY NOTES

OSMOSIS
 There is a net movement of a solvent through a selec
vely permeable membrane from an area
of higher water concentra
on to an area of lower water concentra
on un
l equilibrium is
reached.
 In living systems, the solvent is water, which moves osmosis across the plasma membranes
from an area of higher water concentra
on to an area of lower water concentra
on.
 During osmosis, water molecules pass through a plasma membrane in two ways:
a. By moving between neighboring phospholipid molecules in the lipid bilayer via
simple diffusion.
b. By moving through aquaporins, integral membrane proteins that func
on as water
channels.
 Osmosis occurs only when a membrane is permeable to water but is not permeable to
certain solutes

PRINCIPLE OF OSMOSIS

 Water molecules move through the selec
vely permeable membrane; solute molecules
cannot.
a) Water molecules move from the le
arm into the
right arm down the water concentra
on gradient.
b) The volume of water in the le
arm has decreased
and the volume of solu
on in the right arm has
increased.
c) Pressure applied to the solu
on in the right arm
restores the star
ng condi
ons.
 ISOSMOTIC – solutions having the same or equal osmotic pressure.

 Osmotic pressure – the pressure that must be applied to the solution side to stop fluid
movement when a semipermeable membrane separates a solution from water.

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POST LABORATORY NOTES

TONICITY – a solution’s tonicity is a measure of the solution’s ability to change the volume of
cells by altering their water content.

A. ISOTONIC SOLUTION – concentra
ons of solutes that cannot cross the plasma membrane are
the same on both sides of the membrane.
 Our RBC maintains its normal shape and volume in an isotonic solu
on.
 Normal saline solu
on or 0.9% NaCl solu
ons is an isotonic solu
on which contains
0.9% grams of NaCl in 100 ml of solu
on.
 When RBCs are bathed in 0.9% NaCl, water molecules enter and exit at the same
rate, allowing RBCs to keep their normal shape and volume.
B. HYPOTONIC SOLUTION – a
solu
on that has a lower
concentra
on of solutes than the
cytosol inside the RBCs.
 In this case, water molecules enter
the cells faster than they leave,
causing the RBCs to swell and
eventually burst.
 Hemolysis – rupture of RBCs in
the manner.
 Pure water is very hypotonic and
causes rapid hemolysis.

C. HYPERTONIC SOLUTION – a
solu
on with higher concentra
on
of solutes than does the cytosol
inside the RBCs.
 In such solu
on, water molecules
move out of the cells faster than
they enter, causing the cells to
shrink.
 Crenation – shrinkage of cells.

By: Deannise Ann Boco, RMT
POST LABORATORY NOTES

DIALYSIS:
 a process in which a solu
on containing par
cles of different sizes is placed a bag made of a
semipermeable membrane. The bag is placed into a solvent or solu
on containing only small
molecules. The solu
on in the bag reaches equilibrium with the solvent outside, allowing the
small molecules to diffuse across the membrane but retaining the large molecules.
 An osmo
c semipermeable membrane allows only solvent and not solute molecules to pass. If,
however, the openings in the membrane are somewhat larger, then small solute molecules can
also get through, but large solute molecules, such as macromolecular and colloidal par
cles,
cannot.

Colloids: are stable mixtures despite the rela
vely large size of the colloidal par
cles. The stability
results from the solva
on layer that cushions the colloid’s par
cles from direct collisions and from the
electric charge on the surface of colloidal par
cles.

Crystalloid: have small, highly soluble molecules, such as glucose, that are easily dialyzed. They can be
charged or neutral and go into solu
on because of their microscopic size.

Dialysate: the part of a mixture which passes through the membrane in dialysis.

By: Deannise Ann Boco, RMT