Week 2, The cellular level of organization and cellular membrane new.pdf

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Chapter 03

Cell Biology
Seeley’s
ANATOMY & PHYSIOLOGY
Thirteenth Edition
Cinnamon VanPutte, Jennifer
Regan, Andrew Russo

© 2023 McGraw Hill, LLC. All rights reserved. Authorized only for instructor use in the classroom.
No reproduction or further distribution permitted without the prior written consent of McGraw Hill, LLC.
 Learning Outcomes

The cellular level of organization and cellular membrane
Cell components: a nucleus and cytoplasmic organelles.
Plasma membrane, transport mechanisms.

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 Lecture Outline

- Cell is the structural and functional
unit of all living organisms.
It is the basic unit of life and is
composed of :
-a plasma membrane
- cytoplasm, which includes a nucleus
and cytoplasmic organelles.

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 3.1

General parts of a cell:

Plasma (cell) membrane – outer boundary that allows
cell interaction with its external environment.

Nucleus – directs cell activities (control center of the cell)

Cytoplasm – located between plasma membrane and
nucleus; contains organelles that perform specific
functions.

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 3.3 Plasma Membrane

Functions:

A boundary separating the cytoplasmic (intracellular)
substances from the extracellular environment of the
cells.

Encloses and supports the cell contents.

Attaches to the extracellular environment or to other cells.

The ability to recognize and communicate with other cells.

Determines what moves into and out of cells.

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 Composition of the Plasma Membrane

The plasma membrane is primarily made of lipids and proteins
with a very small amount of carbohydrates.
Glycocalyx: combinations of carbohydrates and lipids
(glycolipids) and proteins (glycoproteins) on outer surface.

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 3.4 Membrane Lipids

Phospholipids and cholesterol predominate.
Phospholipids: bilayer. (a hydrophilic head and hydrophobic tails).
- Polar heads facing water in the interior and exterior of the cell
(hydrophilic); nonpolar tails facing each other on the interior of the
membrane (hydrophobic).

Cholesterol: interspersed among phospholipids. Amount determines
fluid nature of the membrane, providing stability to the membrane.

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 3.5 Membrane Proteins

Integral membrane proteins.
Extend deeply into membrane, often extending from one
surface to the other.
Can form channels through the membrane.
Peripheral membrane proteins.
Attached to integral proteins at either the inner or outer
surfaces of the lipid bilayer or to polar heads of
phospholipids.

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 Transport Proteins

Includes:

-channel proteins,

- carrier proteins

-ATP-powered pumps.

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 Channel Proteins

Channel proteins – integral membrane proteins that form
tiny channels through membrane.

Channel proteins- membrane proteins form a passageway
through the plasma membrane.

The channel determines the size, shape and charge of
what can move through.

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 Leak and Gated Ion Channels

Leak ion channels (nongated ion channels): always open.
Responsible for the permeability of the plasma membrane
to ions when the plasma membrane is at rest.
Gated ion channels: opened or closed by certain stimuli.
Ligand-gated ion channel: open in response to small
molecules that bind to proteins or glycoproteins.
Voltage-gated ion channel: open when there is a change
in charge across the plasma membrane.

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 Leak and Gated Membrane Channels

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 Carrier Proteins 1

Also called transporters.
Integral proteins move ions from
one side of membrane to the other.

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 Carrier Proteins 2

Carrier proteins come in several forms.

Uniporters – moves one ion/molecule.

Symporters –two different ions/molecules move in the
same direction at the same time (cotransport).

Antiporters – move two ions/molecules in opposite
directions at the same time (countertransport).

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 Membrane Transport Mechanisms

1. Passive membrane transport – the cell does not
expend ATP; movement from higher concentration to lower
concentration.
Diffusion.
Osmosis.
Facilitated diffusion.
2. Active membrane transport – AT P is used to move
from lower concentration to higher concentration.
Active transport.
Secondary active transport.
3. Vesicular transport – uses a membrane-bound sac.
Endocytosis.
Exocytosis.
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 Diffusion

Net movement of solutes from an area of higher
concentration to lower concentration in solution.
Concentration gradient: concentration difference
between two points.
Solutes move down their concentration gradient until an
equilibrium is established.

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 Osmosis

Diffusion of water (solvent) across a selectively permeable
membrane.

- Water moves from an area of low concentration of solute
(high amount of water) to an area of high concentration of
solute (low amount of water).

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 Osmosis and Cells

Important because large volume changes caused by water
movement disrupt normal cell function.
Isotonic: cell neither shrinks nor swells when placed in a
solution.
Hypertonic: cell shrinks (crenation) when placed in a
solution; water moves out of the cell.
Hypotonic: cell swells and may rupture (lysis) when place
in a solution; water moves into the cell.

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 Effects of Hypotonic, Isotonic, and Hypertonic Solutions
on Red Blood Cells

gains Loses
water. water

neither gains nor
loses water.
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 Facilitated diffusion

Transport process requires a carrier molecule but does not use cellular energy

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 Active Membrane Transport: Active Transport

Requires ATP.
Substances can be moved against their concentration
gradients (that is, from low to high), allowing the
substance to accumulate on one side of the plasma
membrane.
Example: sodium-potassium (Na + K + ) pump that creates
electrical potentials across membranes.

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 Vesicular Transport
Movement of larger substances by
formation or release of a vesicle.
Requires ATP. Phagocytosis
Types:
Endocytosis: movement into cell.
Phagocytosis: solid particle is ingested, and
large vesicle is formed. E.g Cells ingest
Bacteria.
Pinocytosis: dissolved molecules ingested,
and small vesicles are formed.
Exocytosis: movement out of cell.

Transcytosis: movement through a cell by a combination of
endocytosis on one surface and exocytosis on the opposite surface.

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 3.7 Cytoplasm

Cytoplasm: cellular material outside nucleus but inside
plasma membrane.

Composed of cytosol, organelles, cytoskeleton, cytoplasmic
inclusions.

Cytosol is the fluid portion.

Dissolved molecules, ions, and suspended molecules of
proteins, especially enzymes.

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 Cytoskeleton

- Cytoskeleton Supports the
cell but allows for
movements like changes in
cell shape and movements
of cilia.
- Cytoskeleton is consist
of microtubules, actin
filaments, and
intermediate filaments.

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 3.8 The Nucleus and Cytoplasmic Organelles

Organelles: small specialized structures with particular
functions. Vary in number and type depending on cell
function.

Most have membranes that separate interior of organelles
from cytoplasm.

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 The Nucleus

Large membrane-bound structure containing DNA.
Consists of nucleoplasm surrounded by nuclear
envelope which is a double membrane with many fused
areas called nuclear pores that regulate movement
into/out of nucleus.
DNA contained in nucleus specifies the structure of
proteins.
Nucleolus: dense region(s) within the nucleus where
ribosomes are manufactured.

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 Nucleus

(b) Don W. Fawcett/Science Source; (c) Bernard Gilula/Science Source

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 Chromosome Structure

DNA is found in nucleus,
associated with proteins called
histones to form chromosomes.
Nucleosomes are structural units
of chromosomes.
During much of cell cycle,
chromosomes are dispersed as
chromatin.
During cell division, chromatin
condenses into compact
chromosomes.

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 Ribosomes

responsible for protein synthesis.
Composed of a large and a small subunit.
Composed of ribosomal RNA (rRNA) + proteins.
Types:
Free – synthesize proteins used inside the cell.
Attached (to endoplasmic reticulum) – produce integral
proteins and proteins secreted from the cell.

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 Endoplasmic Reticulum (ER)

Organelle consisting of a network of
membranes that is continuous with
outer membrane of nuclear envelope;
internal spaces are cisternae.

Rough ER: has attached ribosomes;
where proteins are produced and
modified.

Smooth ER: no attached ribosomes;
manufactures lipids, participates in
detoxification, and calcium ion
storage.

(b) J. David Robertson, from Charles Flickinger, Medical Cell Biology, Philadelphia

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 Golgi Apparatus

Flattened membrane sacs,
containing cisternae, stacked on
each other.

Modifies, packages, and
distributes proteins and lipids for
secretion or internal use.

Substances packaged into
transport vesicles.

(b) Biophoto Associates/Science Source

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 Lysosomes and Peroxisomes

Lysosomes.
Form at the Golgi Apparatus.
Contain hydrolytic enzymes that function in digesting cellular material.
Digest material ingested by cell – nutrients and phagocytized bacteria.
Destruction nonfunctional organelles no longer functional (autophagy).

Peroxisomes.
Smaller than lysosomes.
Contain enzymes to break down fatty acids and amino acids.
Hydrogen peroxide H2O2 (toxic) is a by-product of breakdown.
Also contain the enzyme catalase which breaks down hydrogen
peroxide into water and oxygen

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 Mitochondria

Major site of ATP synthesis.
Membranes:
Cristae: Infoldings of inner membrane; contain enzymes of the electron transport
chain.
Matrix: Substance located in space formed by inner membrane; contains the
enzymes for the citric acid or Krebs cycle.

(b) EM Research Services/ Newcastle University

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 Cilia and Flagella

Appendages projecting from cell surfaces, capable of
movement.

Cilia move materials over the surface of cells.
For example, mucus in respiratory tract.

Flagella used for movement by sperm cells (flagellum)

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 Microvilli

Extension of plasma membrane that increases surface area; some
modified as sensory receptors.

(b) Don W. Fawcett/Science Source

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© 2023 McGraw Hill, LLC. All rights reserved. Authorized only for instructor use in the classroom.
No reproduction or further distribution permitted without the prior written consent of McGraw Hill, LLC.