NUR 101 HB1 Lecture 2- Cells & Tissues 020924 PDF

Summary

This is a lecture covering the basics of cell and tissue structure and function for human biology students, providing an overview of the anatomy and cellular processes. It includes information from Shier, 2015.

Full Transcript

AY2425 NUR101 Human Biological Science I

Cells & Tissues
Ms. Cissy Soong (Reg. MLT I, RN)
Senior Lecturer
Saint Francis University
Learning Objectives
Understand the anatomy of the cell and its
01 structural features that enable it to perform
those functions

Describe and explain different cellular
02 metabolisms- cellular aspiration, protein
synthesis, packaging and processing and its
relationship with the structure
Describe the stages of the cell life cycle,
03 including interphase, mitosis, cytokinesis and
explain their significance

04 Identify different types of tissues, describe
their roles and discuss their functions
Cells
Cells
The basic structural and functional units of all living organisms
Primary formed by carbon, oxygen, hydrogen, and nitrogen
All cells are created by cell division. After division, they differentiate into
different cell types for their purpose
Classification by size, shape and function
Each cell maintains homeostasis at the cellular level
2 main types of cells in human body:
Sex Cells (Germ Cells)
Reproductive cells, reproduce by meiosis, e.g. Male sperm,
Female oocyte
Somatic Cells
All body cells except sex cells, reproduce by mitosis

(Shier, 2015)
 Cell Structure
A General View of the Cell
A cell consists of 3 main parts:

Plasma Membrane
A sturdy yet flexible outer surface
A selective barrier
Very important in cell communication

Cytoplasm
Cytosol
Organelles

Nucleus
Cell control center
Contain heredity information

(Shier, 2015)
 A semipermeable lipid bilayer found outside the cytoplasm of a cell and
surround the inner contents. The membrane consists of
Phospholipids (~75-98%): The polar heads of the phospholipid are
hydrophilic and are attracted to water; The non-polar tails of the
phospholipid are hydrophobic which avoid water and line up in the center of
the membrane

Plasma Glycolipids (~5%): Protect plasma membrane from injury; Enable the
immune system to recognize the host cell; Forms the basics of transfusion
and transplant compatibility; Allow cells to stick to other tissues; Enable

Membrane sperm to recognize and bind to the egg; Guides embryonic cells to their
destination
Cholesterol (~20%): Holds the phospholipid together; Stiffen the
membrane
Proteins (2%): Act as receptors; Involved in second messenger systems,
Act as enzymes, carriers, channel proteins, cell marker, and cell adhesion
molecules

(Shier, 2015)
 Function of Plasma Membrane
Isolation and Protection
A physical barrier that separate the inside of the cell from
Selectively Permeability the surrounding extracellular fluid
Allow some substances to move into or out of the Protect the cellular organelles
cell but restricts the passage of other substances
E.g. Permeable to water, most lipid soluble Sensitivity to the environment and
molecules communication
Not permeable to ions and charged/ polar
molecules Consists of receptors to allow the cell to
recognize and respond to the environment
Receive chemical signals from other cells to
activate or deactivate cellular activities
Channels and Transporters
Pores to allow substances move in and out
Control materials entry and exit the cell
Transporters (Carriers) change shape as they
move a substance one side of the membrane Entry of ions and nutrients
to the other Elimination of waste
Release of secretions
Structural Support
 Membrane Transport
Active Transport
The movement of ions or molecules from a region of low
concentration to a region of high concentration
Occurs against the concentration gradient
Require energy- ATP for transportation
Active transport
Vesicular transport
01 Passive Transport Action Potential

Passive Transport Active Transport 02
A simple process that no energy is required for
molecules movement
Substances move across the membrane down
their concentration or electrical gradient, E.g.
Simple diffusion
Facilitated diffusion
Osmosis

(Shier, 2015)
Passive
Transport-
Simple
Diffusion

(Martini, 2015)

Molecules movement from a region of high
concentration to low concentration region, down the
concentration gradient
Membrane may not be needed
Factors like increased temperature, light, and small
particles, increase in membrane surface area, and
steeper the concentration gradient speed up the diffusion
rate
(Martini, 2015)
Diffusion Across the Plasma Membrane
In the body, diffusion occurs across the
lipid bilayer, e.g.
Exchange of O2 and CO2 between
blood and cells, between blood and
air within lungs
Absorption of lipid-soluble molecules
Release waste from body cells
Diffusion occurs through pores of
channels, e.g.
Ion channels
“Gated” channels- moving in one
direction to open, and in another
direction to close
(Martini, 2015)
 Passive
Transport-
Osmosis

Diffusion of Water
Net movement of water through a selectively
permeable membrane, from an area of higher
water concentration to an area of lower water
concentration
Occurs when a membrane is permeable to water,
but is permeable to certain solutes

(Martini, 2015)
 Osmolarity and Tonicity
Osmolarity of body fluids is ~300mOsm/L
Tonicity- the ability of a solution to affect the fluid volume or pressure in a cell
Water moves in and out of a cell depending on whether the cell’s environment is isotonic, hypotonic or hypertonic

Hypertonic Isotonic Hypotonic
In a hypertonic solution, the concentration of When two environments are isotonic, the In a hypotonic solution, the concentration of
solute particles is greater than the concentration of solutes is same in both of them solute is less than that of a cell
concentration in a cell Water comes in and out during cell Water comes into the cell
Water comes out from the cell to the solution No net gain or net loss of water from cell
 You can simply impress your audience and
add a unique zing and appeal to your
Presentations. Easy to change colors,
photos and Text. Get a modern
PowerPoint Presentation that is beautifully
designed. You can simply impress your
audience and add a unique zing and
appeal to your Presentations. Easy to
change colors, photos and Text. Get a
modern PowerPoint Presentation that is
beautifully designed.

(Martini, 2015)

Substances that cannot diffuse through the lipid bilayer
or ion channels
Transport assisted by carrier protein- Specific
Passive Transport- transporter for the specific substance
Substance binds to a specific transporter on one
Facilitated Diffusion side of the membrane, then released on the other
side after the transporter changes shape
Not require energy
E.g Transport of glucose into the cells
 Primary Active Transport
Movement of molecules from a low concentration
Active area to a high concentration area with the help of an
Ionic Pump which uses ATP to provide energy to move
the ions against the concentration gradient
Transport Energy is required
E.g. Na+, K+, Ca2+, amino acids, monosaccharides

(Martini, 2015)
 Secondary
Active Transport
Require energy indirectly
Carrier protein can move another
substance at the same time as with
facilitated diffusion, without regard to its
concentration gradient
Another substance gets a “free ride”
(Martini, 2015) E.g Sodium-glucose transporters
The transporter does not need energy
Need the energy to pump out the
sodium in the Na+-K+ pump
Endocytosis
Materials move into a cell in You can simply impress your audience and
add a unique zing and appeal to your
a vesicle formed from the Presentations. Easy to change colors,
plasma membrane photos and Text. Get a modern
PowerPoint Presentation that is beautifully
Require ATP designed. You can simply impress your
Three types of endocytosis- audience and add a unique zing and
appeal to your Presentations. Easy to
Pinocytosis change colors, photos and Text. Get a
Phagocytosis modern PowerPoint Presentation that is
beautifully designed.
Receptor-mediated
Exocytosis
endocytosis
Materials move out of a cell by the
fusion with the plasma membrane of
vesicular inside the cell
All cells carry out exocytosis,
especially important in-
Vesicular Secretory cells that secrete
digestive enzymes, hormones,
mucus or other secretions
Transport Nerve cells that release
neurotransmitters
 Pinocytosis (Cell drinking)
Tiny droplets of extracellular fluid are
taken up

Vesicle
Transport-
Endocytosis

Receptor- mediated Endocytosis
A more selective form of phagocytosis
or pinocytosis
Minimum unnecessary matter is taken

Phagocytosis (Cell eating)
The cell engulf large solid molecules
like bacteria, dust
Vesicle is call phagosome
(Martini, 2015)
Cytoplasm
Consists of all cellular contents between
the plasma membrane and the nucleus
2 components included-
Cytosol (Intracellular fluid)
Site of many chemical reactions
Organelles (Tiny structures that
perform different functions in the cell)
Organelles
Organelles with Membrane

Endoplasmic reticulum
Golgi apparatus
Mitochondria
Lysosomes
Peroxisomes

Non-membranous Organelles

Centrosome & Centrioles
Cytoskeleton
Cilia & Flagella
Microvilli
Ribosome

(Martini, 2015)
 Endoplasmic Reticulum (ER)
System of interconnected channels
Extends from the nuclear membrane throughout the cytoplasm, more than half of membrane surface within
the cytoplasm of the cell
2 forms of endoplasmic reticulum (ER):

Rough ER Smooth ER
Covered with ribosomes No ribosomes
Functions: Functions:
Involved in protein synthesis- Involved in the
attach sugar groups to synthesis of fatty
proteins acid and steroid
Proteins are bound in Detoxification of
vesicles for transport to drugs/ toxic
Golgi apparatus Calcium storage
External face synthesize
phospholipids

(Shier, 2015)
Mitochondria
Rod-like organelle surrounded by a double
membrane
The powerhouse of a cell
Generate ATP to provide energy through
aerobic respiration
A cell may have thousands of mitochondria,
depending on its activity

(Shier, 2015)
Golgi Apparatus/ Complex
Small flattened membrane and associated vesicles
close to the nucleus
Cupcake shape
Functions:
Synthesis carbohydrates
Package, modifies, and segregates
proteins for secretion from the cell, inclusion
of lysosomes, and incorporation into the
plasma membrane

(Shier, 2015)
 Lysosome & Peroxisomes
Lysosome
Membrane-enclosed
vesicles
Form from the Golgi
apparatus
Contain digestive and
hydrolytic enzymes
Break down a wide variety Peroxisomes/ Microbodies
of molecules
Help recycle worn-out cell Structurally similar to lysosomes
structures but smaller
Removal of pathogens Contain oxidases- enzyme that
can break down fats and other
organic compounds
Neutralize toxic compound
Abundant in liver and kidney
In mitochondria, peroxisomes
decompose fatty acids to
generate energy for ATP
synthesis

(Martini, 2015)
Centrosome
Consists of 2 hollow cylinders called centrioles
Located near the Golgi apparatus and nucleus
Contain a pair of centrioles at the right angle
Form mitotic spindle- essential for the movement of
chromosomes during the cell division
Form the basal bodies found at the base of cilia and flagella

Centrosome &
Centrioles
(Shier, 2015)
 Microvilli, Cilia & Flagella
Flagella
Similar structure with cilia but much longer
Generate forward motion of the entire cell
(e.g. sperm)

(Martini, 2015)
(Shier, 2015)
(Martini, 2015)
Cytoskeleton
A network of protein filaments that extends
throughout the cytosol
Support the cell shape
Organize the contents in cell
Direct movements within the cell
Contribute movement of cell
Consist of 3 structures:

Microtubules
Microfilaments Determine
cell shapes
Assist movement Intermediate
Help the
Provide support filaments
organelles
Assist in
movement
stabilize
organelles
position
Help attach
cells to others

(Shier, 2015)
 Ribosomes
Free or attached to rough ER
High content of ribosomal RNA (rRNA)
Some are free in the cytosol, some located
within the mitochondria
Contain of 2 tRNA binding sites
Function:
Site of protein synthesis

(Shier, 2015)
 Nucleus
Large organelle and most prominent feature
of a cell
Most cells have a single nucleus except
mature red blood cells (no cell nuclei) and
skeletal muscle cells (with multiple nuclei)
Contain fluid nucleoplasm, nucleoli, and
chromatin
Functions:
Control center of a cell
Storage and processing of genetic
information, provide instructions for
protein synthesis
Nuclear envelope: separate the
nucleoplasm from the cytoplasm and
(Shier, 2015)
regulates the passage of substances to
and from the nucleus
Chromatin: DNA constitutes the genes
 DNA, Chromatin,
Chromosome &
Chromatid
Chromatin is a complex of
macromolecules composed of DNA,
RNA, and protein, which is found
inside the nucleus of eukaryotic cells
The primary protein components of
chromatin are histones that help to
organize DNA into “bead-like”
structures called nucleosomes by
providing a base on which the DNA
can be wrapped around
The nucleosome can be further folded
to produce the chromatin fiber
Chromatin fibers are coiled and
condensed to form chromosomes
when cell is preparing for division
Chromatin makes it possible for a
number of cell processes to occur
including DNA replication,
transcription, and cell division
Chromatid is one half of a duplicated
chromosome
(Shier, 2015)
Section Break
TOILET TIME
 Cellular Metabolism

Protein
Cellular Synthesis; Cell Cycle &
Respiration Package, Cell Division
Processing
& Secretion
 Cellular respiration is a series of
chemical reaction processes that take
place within a cell for the generation of
energy, usually in the form of ATP, from
dietary proteins, fats, and carbohydrates
3 main processes are-
i. Glycolysis
ii. The Citric Acid Cycle (Krebs
Cycle)
iii. Oxidative phosphorylation/
Electron transport chain
Glycolysis starts in the cytosol and the
others occur in the mitochondria

Cellular Respiration
Cellular
Respiration
1. Glycolysis (Anaerobic pathway)
Glycolysis breaks down 6-carbon
glucose molecule producing two 3-carbon
pyruvic acid molecules and a net gain of 2
ATP molecules that the body uses as
cellular energy
Each 3-carbon pyruvic acid molecules
enters the mitochondria to start the Citric
Acid Cycle
2. The Citric Acid Cycle (Aerobic pathway)
2 more ATP are created and carbon
dioxide is released as a waste product
3. The Oxidative Phosphorylation
Involves the electron transport chain and
chemiosmosis in the inner mitochondrial
membrane.
Most ATP molecules are created
3 steps of cellular respiration can produce (Shier, 2015)
up to 38 ATP molecules
Nucleic Acid, DNA & RNA
Nucleic acid- huge molecule contain carbon,
hydrogen, oxygen, nitrogen, and phosphorus
Monomers is nucleotides made with pentose
sugar-deoxyribose & ribose, phosphate group
and nitrogen bases (Adenine, Guanine,
Thymine, Cytosine, Uracil)
2 types of nucleic acid-
DNA- Deoxyribose Nucleic Acid
Long double helix chain of
nucleotides
Consists of deoxyribose and bases
(A,T,G,C)
Complementary base pairing- A
with T, G with C
Forms the inherited genetic material
inside each human cell
Gene- a segment of a DNA molecule
RNA- Ribose Nucleic Acid
Single strain of nucleotides
Consists of ribose and bases
(A,U,G,C)
Relays instructions from the genes to
(Martini, 2015)
transcript amino acids
 Types of RNA
Amino acid

Anticodon

02 Ribosomal RNA (rRNA) 03 Transfer RNA (tRNA)
01 Messenger RNA (mRNA)
Found in the cytoplasm
Formed in nucleus Involved in the synthesis of 06 Carries anticodon
Rewrite the sequences of peptides in the ribosomes Transfer specific amino acids to
bases in a section of DNA ribosomes
during transcription Ensure the alignment of these
Serve as template for the amino acids in the proper
05
protein synthesis sequence prior to the peptide
bond formation
 Protein Transcription

Synthesis
The DNA of the nucleus controls cell
structure and function through
synthesis of specific proteins
Protein synthesis is the assembling of
functional polypeptides in the
cytoplasm
The major events of protein synthesis
are Transcription and Translation

Transcription Translation
Translation

DNA ➔ RNA ➔ Protein
(Marieb, 2019)
Transcription
Nucleus
Transcription is the synthesis of
messenger RNA (mRNA) from a
DNA template catalyzed by RNA
polymerase
Occurs in the cell nucleus
Start at a DNA nucleotide sequence
called promoter
The mRNA then leaves the
nucleus to the cytoplasm through
the nuclear pore after synthesis
Translation
Translation is the synthesis of a linear chain of
Cytoplasm amino acids using the transcribed information provided
by the mRNA
Occurs in the cytoplasm
Each amino acid in a protein is specified by three
nitrogen bases in the DNA sequences called codon
tRNAs with matched anti-codon bring the specific
amino acid to the ribosome and start the translation
process
Base pair complementation between mRNA codon and
tRNA anticodon
tRNA Peptide bond formation happens between the amino
acids that the tRNAs bought within the ribosome
Ribosome translocate to another codon along the
mRNA and continue the amino acid chain synthesis
The completed amino acid chain released after
synthesis
Process of Translation

tRNA

(Martini, 2015)
Codons for Protein Synthesis

tRNA

(Shier, 2015)
 Gene Mutation
A gene mutation involves a change in the order of the nitrogen bases (A, C, G, T)
that makes up the genes
The change in the DNA sequence can lead to a subsequent change in the mRNA
sequence
The altered mRNA sequence would lead to a change in the amino acid sequence
(the primary protein structure) and may alter bonding in the protein molecule
leading to the protein being inactive or problem-causing

Types of mutation
Deletion- base missing
01 E.g. AGTCTGC ➔ AGCTGC
Addition- extra base added
E.g. AGTCTGC ➔ AGTCGTGC
Substitution- one base is replaced by another base
E.g. AGTCTGC ➔ AGGCTGC

Effects of gene mutation
Proteins produced may be beneficial or harmful, or may
02 have no effect at all
The effect can be positive, negative or neutral
Protein Package, Processing & Secretion

tRNA

(Martini, 2015)
 Cell Cycle

A cell life from it forms until it
divides consists of a series of
phases called cell cycle
The major phases are
Interphase
Mitosis
Cytokinesis
(Cytoplasmic division)
(Shier, 2015)
Types of Cell Division Reproductive Cell
Division
Somatic Cell Division
Any cell of the body except sex cells Reproductive Cell Division
Undergo nuclear division (Mitosis) and Undergo 2-step division called
cytoplasmic division (Cytokinesis) Meiosis
Produce 2 genetically identically cells- same The number of chromosomes in
number and kind of chromosomes as the original the nucleus is reduced by half
cell, i.e. 23 pairs of chromosomes cell (n=46) (n=23) to become Haploid cells
called Diploid cells

Somatic Cell Division

(Shier, 2015)
Cell Cycle- Interphase
Interphase consists of 4 phases:
G0 Phase- Resting phase
G1 Phase- Organelle duplication
and protein synthesis occur
S Phase- Cell duplicate centrioles
and conduct DNA replication
G2 Phase- Cell continues growing
to:
Makes more organelles
Finishes replicating centrioles
tRNA
Synthesis enzymes for cell
division
Checks DNA and repairs any
errors

(Shier, 2015)
 DNA Replication
Occur in S phase:

DNA helix unwinded by helicases
into single template strand and
expose the nitrogenous bases, ATP
required
DNA polymerase read the
exposed short segments of
nitrogenous bases and assemble
the sequence of the new strand
with complementary nitrogenous tRNA

bases with the RNA primers
DNA ligase joins the short
segments together

(Martini, 2013)
 Happens in the nucleus
Functions- Growth, repair,
replace, wore out cells
The replicated chromatin
becomes tightly coiled and
easier to see under the
microscope
Consists of 4 sub-phases:
Prophase
Metaphase
Anaphase
Telophase

Mitosis (M Phase)
(Shier, 2015)
 Process of Mitosis

(Marieb, 2019)

Early Prophase Late Prophase Metaphase Anaphase Telophase
Chromatin fibers Centrioles get pushed The chromatids Centromeres split by Chromosomes are in opposite ends,
condense and apart to each pole of align on the enzyme uncoil and revert to chromatin form
shorten into the cell by spindle center of the Sister chromatids Nuclear envelope reform, nucleoli
chromosomes fibers spindle fibers, separated and reappear in the identical nuclei
Spindle fibers attached Mitotic spindle breaks up
Each attached by their move toward
to the centromere on Following telophase, cytokinesis
chromosome centromeres opposite poles of the
chromosomes
consists of a pair cell occurs- the cytosol, intracellular
Nucleoli disappear and
of identical the nuclear envelope Chromatids become organelles and plasma membrane
strands called breaks down chromosomes after split to form 2 identical daughter
chromatids separated cells
 Sex cells are produced through Meiosis
Involves 2 cell division instead of one, and
produces four genetically unique cells rather
than two identical cells
Sex cells are haploid cells that contain only half
of the full set of 46 chromosomes
Because of haploid and genetically unique, it
can combine with another sex cell during
fertilization to create offspring with genetic
variation
Detail process discussed in the reproductive
system

Meiosis
Cell Differentiation

All cells in human body
comes from stem cells,
through the processes of
mitosis and
differentiation- process
enables cells to
specialize and become
mature cells

(Shier, 2015)
Section Break
TOILET TIME
Tissues
 Groups of similar cells
working together to
perform a particular
function
8 types of tissues- blood,
bone, epithelial tissue,
cartilage tissue, adipose
tissue, connective
tissue, muscle tissue,
and nervous tissue

Types of Body Tissues
Epithelial
Tissue
Cover body surface
Line hollow organs, body
cavities and ducts
Form glands and membranes
Classification of Epithelial Tissue

tRNA
Simple Epithelial Tissue
Location Function
Found in heart, blood and Reduce friction
lymphatic vessels linings Control vessels permeability
Epithelial layer of peritoneum, Perform diffusion
pleura and pericardium Perform secretion

Located at glands, ducts, kidney Secretion and absorption
tubules
Makes up secreting portion of
thyroid gland and ducts of pancreas

Lining of stomach, guts, gall bladder, Secretion
uterine tubes, collecting ducts of Absorption
kidney Protection
tRNA

Ciliated: Lining of nasal cavity, Secrete mucus to trap foreign particles
trachea and bronchi Cilia sweep away mucus for
Non-ciliated: Lining of large ducts, elimination from the body
epididymis, and part of male urethra Absorption and protection
Stratified & Transitional Epithelial Tissue
Location Function
Found in skin surface Protect against abrasion, water loss,
Linings of mouth, throat, ultraviolet radiation, and foreign
oesophagus, rectum and vagina invasion
Covers tongue Form the first line of defense against
microbes

Ducts of sweat glands and Protection
oesophageal glands Limited secretion and absorption
Part of male urethra

Part of urethra, large excretory Protection and secretion
ducts
tRNA

Lines several parts of the urinary Variable appearance, subject to
tract, including bladder expansion
Glandular
Epithelium
Found in cells or organs that secrets substances
for use in other body parts
Include Endocrine and Exocrine glands
Endocrine
No ducts
Secrete directly into blood
(Martini, 2015)
Secretions are known as hormones
Exocrine
Contact with the surface by means of duct-
an epithelial tube that brings secretion to
the surface, e.g. Sweat and tears
Secretion released to the body surface or
into the cavity or lumen of another organic,
e.g. Saliva and digestive enzymes

(Shier, 2015)
Membranes in
the Body
Line body cavities and cover the
viscera (internal organs)
Cutaneous Membrane (Skin)
Largest membrane in the body
Dry
Mucous Membrane (Mucosa)
Line all body cavities that open
to the outside of the body, e.g.
Digestive tract, Respiratory tract,
Urogenital tract
Serous Membrane (Serosa)
Internal membrane that covers
organs and lines walls of body
cavities, e.g. Pleura,
Pericardium, Peritoneum

(Martini, 2015)
Connective
Tissue
The most abundant tissue and
widely distributed
Materials found between cells
Functions:
Support and binds
structures together, e.g.
Bone, Cartilage, Ligament,
and Tendon
Store energy, e.g. Adipose
tissue
Provides immunity to
disease, e.g. White blood
cells
Loose Connective Tissues
Fill up space between organs
Act as cushion and stabilize cells
Surround and support blood vessels and nerves
Store Lipids
Provide a route for diffusion of materials
E.g. Matrix as in areolar, adipose tissue, finely woven
reticular fibers

tRNA

(Martini, 2015)
Dense Connective Tissues
Collagenous tissues
Contain elastic fibers
Can tolerate cycles of extension and recoil, e.g. Lung, Vessels
Connect, provide strength and support, e.g. Tendon

tRNA

(Martini, 2015)
 Fluid Connective Tissue
Transports oxygen from lungs to body cells
Bring waste, carbon dioxide from cells to lungs
Transports nutrients and hormones, regulate body temperature,
body defense and prevent excessive blood loss from injury
Consists of Red blood cells, White blood cells and Platelet

Diffuse lymphatic tissue
Found in connective tissue of almost all organs
Found in lymphatic ducts and nodules

Lymph
Supporting Connective Tissues- Cartilage

Strong, flexible and avascular
Covers the ends of long bones
Connects bones
Resists compressions and absorbs shock
3 types:
Hyaline cartilage
Elastic cartilage
Fibrocartilage

tRNA

(Martini, 2015)
 Supporting Connective Tissue- Bone
Bone/ Osseous Tissue

Hardest form of connective tissue
Functions:
Protection to visceral organs
Support
Blood cell formation (Hemopoiesis)
Red bone marrow produces red
blood cells, white blood cells and
platelets
Storage of minerals & lipid
Calcium, phosphate
Yellow bone marrow consists
adipose cells which store
triglycerides and act as energy
reserve
Leverage for muscles
Provide balance for the body
Assistance in movement

(Marieb, 2019)
Muscle Tissue
Able to contract and relax
Functions:
Provide movement within
the body and of the body
itself
Muscle contraction requires
a rich blood supply providing
sufficient oxygen, calcium
and nutrients and removing
waste products
3 types of contractile cells:
Skeletal muscle cell
Smooth muscle cell
Cardiac muscle cell
(Martini, 2015)
 Types of Muscle Tissue

Skeletal Muscle

Cardiac Muscle

tRNA

Smooth Muscle
(Martini, 2015)
Nervous Tissue
Located in the brain, spinal cord
and nerves
Function:
Transmit the information
from one part of the body to
another, by means of nerve
impulse
Nervous cells called Neurons
consists of 3 parts-
Cell body: Contain nucleus
and other organelles
Dendrites: Short
projections to receive inputs
Axon: Single, thin and long
projection to conduct output
impulse
Cells support them called
neuroglia
(Shier, 2015)
Q & A
 REFERENCE
Marieb, E. N., & Keller, S. M. (2019). Essentials of Human
Anatomy & Physiology, Global Edition. Pearson.

Martini, F. H., Nath, J. L., Bartholomew, E. F., & Ober,
W. (2015). Fundamentals of Anatomy and
Physiology. 2001. Pentice Hall: New Jersey,
657-687.

McKinley M, O’Loughlin VD. Human Anatomy: McGraw-Hill
International Edition. 2006. McGraw-Hill: New
York.

Shier, D., Butler, J., & Lewis, R. (2015). Hole’s human
anatomy and physiology. McGraw- Hill Education.

Tomkins, Z. (2020). Applied Anatomy & Physiology:
an interdisciplinary approach. Elsevier Health
Sciences, 195-225.

Vander, A. J., Sherman, J. H., & Luciano, D. S. (1998).
Human physiology: the mechanism of body
function. Burr Ridge, IL: WCB McGraw-Hill.
Reference Videos
Passive Transport https://youtu.be/-ZwXUrZolD0

Cell Biology: Active Transport https://youtu.be/5asMngTQqxQ

DNA & RNA- Overview of DNA & RNA
https://youtu.be/GhABWQC3YDs

DNA & RNA- Transcription https://youtu.be/YlOqI3PQwjo

From DNA to Protein https://youtu.be/gG7uCskUOrA

DNA & RNA- DNA Replication https://youtu.be/Mu2bJgEZtwE

M phase of the cell cycle https://youtu.be/5bq1To_RKEo

Overview of cell division https://youtu.be/XKZhcYetvsc
THANK YOU