Cell Biology Structure and Function of Cells PDF

Summary

This document provides an overview of cell biology, covering the structure and function of cells, different cell types (prokaryotic and eukaryotic), organelles and non-organelles, and their roles in maintaining homeostasis. It also touches upon the interrelation between cell organelles and homeostasis.

Full Transcript

CELL BIOLOGY
STBP1023
DR.NURUL YUZIANA MOHD YUSOF
Structure & Functions of Cells
- Organelles, non-organelles
& others subcellular components
 Structure & Functions of Cells
- Organelles, non-organelles
& others subcellular components

PART I : Type of Cells – a recap
PART II : Cell Structure – The Organelles PART III : Cell Structure – The Non Organelles
Nucleus Cell Wall
Mitochondrion Cytoskeleton
Endoplasmic Reticulum Ribosome
Golgi Apparatus Others: cell coats, cell junctions
Lysosome & Peroxisome
Vacuole
Chloroplast
 3 different kingdoms – Eukarya, Bacteria and Archaea
Type of CELLS
Karp 2010; Cell Biology
 Prokaryotic Cells
pro- “before” karyon- “nucleus”
 Bacterial Cell Archaeal Cell (General)

http://0.tqn.com/d/biology/1/0/Z/V/prokaryoticcell.jpg http://dbscience3.wikispaces.com/file/view/prokaryote.jpg/
59566886/prokaryote.jpg
Archaeal Cell
Structurally similar to
prokaryotic cell
Several genes and biochemical
and metabolism pathways are
similar to eukaryotes
Examples:
Most of them, line in extreme
environment - “extremophiles” such
as:
- methanogens (produce methane)
- halophiles (salty)
- acidophiles (very low pH)
- thermophiles (extreme hot/cold)
 Eukaryotic Cells
eu- “true” karyon- “nucleus”

Animal Cell Plant Cell
Eukaryotic Cells
Animal Cell
Eukaryotic Cells
Plant Cell
Sub-cellular Components
 Organelles and Non-Organelles
Components
Organelle:
– membrane-bound structure
– within an eukaryotic cell; have a specific function
– contains a specific enzyme complement and chemical
composition related to its function
– nucleus, mithochondrion, endoplasmic reticulum, chloroplast,
Golgi complex, vacuoles, peroxisome, lysosome

Non-Organelle
- mostly related to structure
- non membrane-bound
– plasma membrane, cell wall, cytoskeleton, cytosol, ribosome
 Sub-cellular Components
Organelles Non-Organelles

nucleus vacuole plasma membrane cell wall

mitochondrion
Golgi complex

cytoskeleton
endoplasmic
reticulum lysosome

cytosol

chloroplast peroxisome
ribosome
 C A R D – key points
NOTE

Structure Function Role in Homeostasis

What is it? A state of balance among all the body systems needed
for the body to survive and function correctly
Homeostasis is the maintenance of a stable internal environment within cells and organisms
through dynamic regulation and feedback mechanisms, despite external changes or disturbances.
It involves coordinated actions of cellular organelles and systems to maintain optimal conditions for
life processes, such as pH, temperature, ion concentrations, and metabolic balance.
The relationship between homeostasis and cell organelles is crucial because:
1.Organelles are specialized units that maintain specific aspects of cellular balance
2.Each organelle contributes unique functions to overall cell stability
3.The integrated network of organelles allows coordinated responses
4.Understanding these relationships helps in:
- Disease treatment
- Cell engineering
- Biotechnology applications
- Medical research
THE ORGANELLES
 The Nucleus:
Control Centre of the Cell
Structure Function Role in Homeostasis
1. Nuclear envelope 1. Storage of genetic information (DNA) 1. Coordination of cellular responses
- Double membrane structure - Chromosomal organization - Integration of cellular signals
- Nuclear pores for controlled transport - DNA replication during cell division - Regulation of gene expression
- Connection to endoplasmic reticulum - Protection of genetic material patterns
- Adaptation to environmental
2. Nucleoplasm and nucleolus 2. Regulation of gene expression and changes
- Gel-like matrix containing genetic material cellular activity
- Nucleolus as the site of ribosome - Transcription of genetic information 2. Maintenance of genetic integrity
assembly - Processing of RNA molecules - DNA repair mechanisms
- Organization of chromatin structure - Control of protein synthesis - Chromosome stability
- Quality control of genetic
information
 Nucleus
Outer membrane
Inner membrane
Nucleoplasm
Nucleolus
Chromatin

Nuclear envelope
Pore in nucleus envelope

also refer red
as g e n o m
that deter mine ic DNA (g
s the specific DNA)
trait/characte
r of an organis
m

Contains the genetic material of an eukaryotic cell
Enclosed by two membranes
Numerous small openings, nucleopores; allows movement of molecules
 Nucleus

Contains chromosome
– structural unit of genetic material
– Consist of DNA molecule and histone
– Readily visualised during mitosis
– During interphase, dispersed as chromatin

this is when the cell actually ‘active’
Nucleus
Nucleus
Nucleus
 Mitochondrion:
Powerhouse of the Cell
Structure Function Role in Homeostasis
1. Double membrane and inner 1. ATP production through cellular 1. Energy supply for cellular processes
membrane folds (cristae) respiration - ATP availability regulation
- Outer membrane permeability - Oxidative phosphorylation - Metabolic rate adjustment
- Cristae increase surface area - Electron transport chain - Energy distribution
- Compartmentalization of respiratory - Proton gradient generation
processes
2. Role in metabolic pathways 2. Regulation of apoptosis and metabolic
2. Matrix composition - Citric acid cycle balance
- Enzymes for metabolic processes - Fatty acid oxidation - Cell death signalling
- Multiple copies of mitochondrial DNA - Amino acid metabolism - Calcium homeostasis
- Protein synthesis machinery - Reactive oxygen species management
Mitochondrion
 Mitochondrion
Similar size to a prokaryotic cell
Two membranes
Contain their own DNA and
ribosomes
‘powerhouse’ of the eukaryotic cell
– Generates high-energy
compound adenosine
triphosphate (ATP)
– Localises most of the enzymes
and intermediates involved in
energy-producing pathways
 Mitochondrion

Number and location within the cell are often related directly to
their role in that cell, e.g. muscle cell and sperm cell
 Mitochondrion
Occurrence of other
Localises intermediates chemical reactions, such as
involved in the electron Krebs cycle & fat
transport chain oxidation
 Endoplasmic Reticulum:
Protein & Lipid Synthesis
Structure Function Role in Homeostasis
1. Smooth ER vs. Rough ER 1. Protein synthesis and folding 1. Quality control of proteins
- Structural differences (Rough ER) - Unfolded protein response
- Distribution within the cell - Ribosome attachment - Protein trafficking
- Membrane composition - Protein translocation - ER stress management
- Quality control mechanisms
2. Connection to the nuclear envelope 2. Modulation of lipid levels in the cell
- Continuous membrane system 2. Lipid synthesis and detoxification - Membrane composition regulation
- Transport mechanisms (Smooth ER) - Lipid distribution
- Spatial organization - Membrane lipid production - Cellular stress response
- Steroid hormone synthesis
- Drug metabolism
 Endo = within, plasmic = the plasm, reticulum = network
ER is continuous with the outer membrane of the nuclear envelope
Rough ER & Smooth ER
 Rough ER
– Due to the ribosomes
– Ribosomes synthesise
secretory proteins and
membrane proteins
– Proteins are transported
into or across the ER
membrane via RER, Golgi
complex or secretory
vesicles
 Smooth ER
– No ribosomes
– Responsible for:
Packaging of secretory
proteins
Synthesis of lipids and
steroids
Metabolism of
carbohydrates
Inactivation and
detoxification of toxic
drugs and other
compounds
 Golgi Apparatus:
Modification and Transport Hub

Structure Function Role in Homeostasis
1. Stacked cisternae 1. Modification of proteins and lipids 1. Regulation of cellular transport
- Structural organization - Glycosylation - Membrane traffic control
- Membrane composition - Protein processing - Protein distribution
- Vesicle formation - Sorting signals - Vesicle targeting

2. Polarized structure (cis & trans faces) 2. Packaging for secretion or delivery 2. Maintenance of cellular communication
ic
Asym
metr
ha e
p - Directional processing - Vesicle formation - Secretory pathway regulation
cell s
- Sorting mechanisms - Protein targeting - Signal molecule processing
- Transport regulation - Quality control - Membrane composition control
 A stack of flattened
vesicles
Role in:
– Processing and
packaging secretory
proteins (mostly
glycoproteins)
– Synthesis of complex
polysaccharides

https://www.pnas.org/content/105/24/8256
Sub-Organelle: Secretory Vesicles

Contains secretory proteins
and substances processed
by Golgi complex
To export the packaged
contents from the cell
Vesicles move from GC
Øto the plasma membrane
Øfused with it,
Ødischarge their contents
to the extracellular space
(exocytosis)
 Production of Secretory Vesicles by GC

1. Vesicles budding off the ER
2. Accepted by Golgi complex (GC)
3. Contents of the vesicles further
5
modified and processed in the
GC
4
4. Vesicles budding off the GC
5. The contents are passed to
3 other compartments of the cell
(or being expelled from the cell to
2
1 release secreted proteins)
 Lysosomes and Peroxisomes:
Waste Management and Metabolism
Structure Function Role in Homeostasis
1. Membrane-bound vesicles Function of Lysosomes 1. Cellular cleanup and recycling
- Single membrane structure 1. Breakdown of macromolecules - Waste management
- Specific protein composition - Protein degradation - Material recycling
- Size and distribution - Lipid breakdown - Quality control
- Carbohydrate processing
2. Enzymatic content and functions 2. Regulation of metabolic byproducts
- Hydrolytic enzymes 2. Role in autophagy - Toxin elimination
- Oxidative enzymes - Cellular recycling - ROS management
- Substrate specificity - Organelle turnover - Metabolic balance
- Stress response
Function of Peroxisomes
1. Breakdown of fatty acids
- β-oxidation
- Hydrogen peroxide production
- Metabolic coordination

2. Detoxification processes
- ROS neutralization
- Specialized metabolism
- Cellular protection
 0.5-1.0 µm in diameter
Single membrane
Discovered by Christian de
Duve and his colleagues
– Discovered a class of
particles that contained
acid phosphatase and
hydrolytic enzymes
Means of storing hydrolases,
digestive enzyme
– To digest food molecules
that the cell acquire from
the environment
– To break down unwanted
cellular constituents
– To contain the enzyme
and use it when required
 Synthesised in the RER and
transported to GC
– inactive form
Develop by budding off the
ends of the Golgi cristernae
– Primary lysosome: contain
hydrolytic enzymes but
not yet engaged in
digestive activity
Secondary lysosome: fused
with food vacuole
containing or vacuole with
damaged organelles
– The digestion products
pass through the
membrane and out into
the cytoplasm and
recycled
 Resemble lysosome in size, mode of origin and structure
Found in both animal and plant cells
Carry several distinctive function according to cell type
– Common property of both generating and degrading hydrogen peroxide
(H2O2)
– H2O2 highly toxic; eukaryotic cell protect themselves by decomposing H2O2
into H2O and O2 by catalase in peroxisomes
An example of lysosome-based application

Nano Lipid Particle for mRNA Vaccine Delivery
 Vacuoles:
The Multifunctional Compartments
Structure Function Role in Homeostasis
1. Membrane (Tonoplast) 1. Storage 1. Turgor Pressure Regulation
- Single membrane system - Water retention - Cell growth control
- Selective transport proteins * Turgor pressure maintenance - Structural support
- Aquaporins * Cell volume regulation - Guard cell function
- Ion channels and pumps * Drought resistance - Movement responses
- Nutrient storage
2. Internal Organization * Ions (Ca2+, K+, NO3-) 2. pH and Ion Balance
- Aqueous matrix * Sugars - Cytoplasmic pH regulation
- Stored compounds * Proteins - Ion concentration control
- Protein aggregates * Secondary metabolites - Metal ion sequestration
- Crystal structures - Toxic compound sequestration - Salt stress management
* Heavy metals
* Xenobiotics
* Waste products
2. Cell Maintenance
- pH regulation
- Ion homeostasis
- Protein turnover
- Waste management
3. Defense Functions
- Storage of defense compounds
Alkaloids | Tannins | Protease inhibitors
- Pathogen resistance
- Herbivore deterrence
 A membrane-bound organelle
In eukaryotic cells and some bacterial cells
In animal cells, temporary storage or transport
E.g.: Food vacuoles; take up food particles by phagocytosis
– phago: eating , cyte: vessel, osis; process
– The cellular process of engulfing foreign particles (e.g. food,
bacteria etc.) by the cell membrane, followed by a pinching-off
process that form vacuoles
 In plant cell:
– Central Vacuole
– Major role in maintenance
of the turgor pressure of
the cell
– ‘pumped up’ with liquid
– Pressing the cellular
constituents out against
the cell wall
– \maintaining the turgor
pressure of the
characteristic of non-
lignified plant tissue
 Chloroplasts:
The Photosynthetic Centers
Structure Function Role in Homeostasis

1. Membrane Systems 1. Photosynthetic Processes 1. Energy Balance
- Outer membrane - Light-dependent reactions - Glucose production
* Permeable to small molecules * Photosystem I and II operation - ATP generation
* Protection and structural support * Electron transport chain - NADPH supply
* Transport protein channels * ATP synthesis - Energy storage as starch
- Inner membrane * NADPH production
* Selective permeability 2. Redox State Maintenance
* Specialized transport systems - Carbon fixation (Calvin cycle) - ROS management
* Protein import machinery * CO2 incorporation - Antioxidant production
- Thylakoid membrane system * Sugar synthesis - Electron transport regulation
* Grana stacks (appressed regions) * Starch production - Photoprotection mechanisms
* Stromal lamellae (non-appressed regions) * Photorespiration
* Light-harvesting complexes
* Electron transport components 2. Additional Metabolic Roles
- Fatty acid synthesis
2. Internal Compartments - Amino acid production
- Stroma - Secondary metabolite synthesis
* Site of carbon fixation - Nitrogen and sulphur assimilation
* Contains DNA, ribosomes
* Metabolic enzymes
* Starch granules
- Thylakoid lumen
* Proton accumulation space
* Water-splitting components
* Plastocyanin transport
 Larger than any other organelles except for the nucleus
The site of photosynthesis
Found in leaves and other photosynthetic tissue

http://upload.wikimedia.org/wikipedia/commons/thumb/4/49/Plagiomnium_affine_laminazellen.jpeg/250px-
Plagiomnium_affine_laminazellen.jpeg
 Third membrane
Surrounded by two Outer system
membranes membrane
Inner membrane

Stroma
lamellae
Thylakoid
Situate reactions that
Stroma depend directly on solar
Situate reactions involved energy
in ‘fixing’ CO2 into organic Intermembrane space
form, its subsequent
reduction and
Granum
rearrangement into sugar (stack of thylakoids)
molecules
http://micro.magnet.fsu.edu/cells/chloroplasts/images/chloroplastsfigure1.jpg
 Other functions: The process of reducing oxidised form of N (nitrate,
NO3-) to ammonia (NH3)
An e.g. of a class of plant organelles, plastids
Other member
– Chromoplasts: pigment-containing plastid, responsible for colour
– Amyloplasts: starch storage
THE NON-ORGANELLES
 Plasma Membrane:
The Dynamic Barrier
Structure Function Role in Homeostasis

1. Lipid Bilayer Organization 1. Barrier Function A. Ion Balance Regulation B. Osmotic Balance
- Phospholipid composition - Selective permeability 1. Ion Channel Control 1. Volume Regulation
* Phosphatidylcholine - Ion gradients maintenance - Na+/K+ ATPase regulation - Osmolyte transport
* Phosphatidylethanolamine - Cellular integrity * Membrane potential * Compatible solute
* Phosphatidylserine - Protection from environment maintenance adjustment
* Sphingomyelin * Cell volume control * Volume regulatory ↓ (VRD)
2. Transport Systems * Energy metabolism coupling * Volume regulatory ↑ (VRI)
- Cholesterol distribution - Passive Transport - Calcium signalling - Water flux control
* Membrane fluidity regulation * Simple diffusion * Ca2+ channel regulation * Aquaporin regulation
* Microdomain formation * Facilitated diffusion * Second messenger systems * Osmotic stress response
* Structural stability * Ion channels * Signal transduction * Cell volume maintenance
- Active Transport
2. Membrane Proteins * Primary active transport 2. pH Regulation 2. Mechanical Stability
- Integral Proteins (ATP-driven) - Proton pumps - Membrane tension control
* Transmembrane proteins * Secondary active transport * Intracellular pH maintenance * Cytoskeleton interaction
* Single-pass proteins * Bulk transport * Acid-base balance * Membrane reservoir
* Multi-pass proteins (endo/exocytosis) * Metabolic regulation management
* Lipid-anchored proteins - Bicarbonate transporters * Surface area regulation
3. Cell Signalling * pH buffering
- Peripheral Proteins - Receptor functions * CO2 transport
* Cytoskeletal attachments - Signal transduction * Acid-base homeostasis
* Signal transduction components - Cell-cell communication
* Regulatory proteins - Environmental sensing
 Surrounds every cell, define the boundaries and ensure its
contents retained
Consists lipids, proteins and carbohydrates
Fluid-mosaic model
Functions, fluid – dynamic movement within membrane
plane, mosaic: protein embedded
 Consist of:

Lipids Proteins
– Phospholipids, – Glycoproteins
– Glycolipids, – Transport proteins
sphingolipids – Enzymes
– Cholesterol – Receptors
– ‘anchors’
Carbohydrates
– Glycoproteins
protein/lipid ratio vary;
– Glycolipids amphiphatic (polar/non-polar)
 Plasma membrane – The Lipids
Phospholipids - a phosphate group attached to fatty acids
- Phosphate group - hydrophilic and ‘head’ structure
- Fatty acids - hydrophobic and ‘tails’ structure
 Plasma membrane – The Lipids

Glycolipids
– Lipids with a
carbohydrate
attached
– Function as cell-
markers and also as a
source of energy
Cholesterol
– Strengthen the cell
membrane
 Plasma membrane – The Proteins

Glycoproteins:
– Polypeptide with one or more carbohydrate side chains attached
Types:
– Transmembrane protein, peripheral protein and surface protein
Roles:
– Transport proteins, enzymes, hormone-receptors and ‘anchors’
for structural elements
 Cell wall:
The Protective Framework
(Plant/Fungal/Bacterial)
Structure Function Role in Homeostasis

1. Plant Cell Walls 1. Structural Support A. Pressure Regulation B. Environmental Protection
- Primary Wall - Mechanical strength 1. Turgor Pressure Control Stress Response
* Cellulose microfibrils - Shape maintenance - Wall extensibility - Temperature adaptation
* Hemicellulose - Growth regulation * Growth regulation * Wall flexibility adjustment
* Pectin - Pressure resistance * Pressure adaptation * Thermal protection
* Structural proteins * Mechanical feedback * Stress signaling
2. Protection - Stress response - Chemical protection
- Secondary Wall - Physical barrier * Osmotic challenge management * Barrier function
* Additional cellulose layers - Pathogen defense * Mechanical stress adaptation * Selective permeability
* Lignin deposition - Stress resistance * Growth adjustment * Toxin exclusion
* Specialized modifications - Environmental protection
2. Structural Integrity
2. Bacterial Cell Walls 3. Cell-Cell Interaction - Wall composition modification
- Peptidoglycan layer - Communication * Enzyme regulation
- Teichoic acids (Gram-positive) - Adhesion * Polymer cross-linking
- Outer membrane (Gram- - Recognition * Wall strengthening
negative) - Transport regulation - Repair mechanisms
- Surface proteins * Damage response
* Remodeling processes
3. Fungal Cell Walls * Integrity maintenance
- Chitin framework
- β-glucans
- Mannoproteins
- Specialized polymers
 Cell wall; rigid,
cellulose-containing,
that encases the plant
cell (non-motile)
 Confine and restrain
the cell
Chemical composition
varies;
– Always consists of
microfibrils of cellulose
embedded in a matrix of
polysaccharides and small
amount of proteins
Neighbouring cells are
connected by
numerous
plasmodesmata
– cytoplasmic bridges
– Channel is membrane-
lined
Source: Loix et al. 2017. Frontiers in plant Science 8
 Cytoskeletons:
The Cellular Framework
Structure
1. Microfilaments (Actin Filaments) 2. Microtubules 3. Intermediate Filaments
- Structure - Structure - Structure
* G-actin monomers * α/β-tubulin dimers * Various protein families
* F-actin polymers * Protofilaments * Non-polar assembly
* Polarity * Dynamic instability * Stable structures
* Dynamic assembly * Polarity * Tissue-specific expression
- Associated Proteins - Associated Proteins - Associated Proteins
* Motor proteins (myosin) * Motor proteins (kinesin, dynein) * Crosslinking proteins
* Crosslinking proteins * MAPs (Microtubule Associated * Anchoring proteins
* Capping proteins Proteins) * Regulatory factors
* Regulatory factors * +TIP proteins
* Regulatory factors
 Cytoskeletons:
The Cellular Framework

Function Role in Homeostasis
1. Cellular Organization A. Structural Homeostasis B. Transport Homeostasis
- Organelle positioning 1. Cell Shape Maintenance 1. Vesicular Traffic
- Spatial organization - Dynamic remodelling - Organelle positioning
- Cell shape maintenance * Tension regulation * Spatial organization
- Structural support * Shape adaptation * Transport regulation
* Mechanical response * Distribution control
2. Cell Movement - Stability control - Material transport
- Cell migration * Scaffold maintenance * Cargo delivery
- Muscle contraction * Organelle positioning * Pathway organization
- Ciliary/flagellar movement * Structural integrity * Traffic regulation
- Cytoplasmic streaming
2. Mechanical Response 2. Molecular Motor Function
3. Transport - Force distribution - Transport regulation
- Vesicle trafficking * Stress fibre formation * Speed control
- Organelle movement * Tension management * Directional movement
- Chromosome segregation * Mechanical adaptation * Energy efficiency
- Cytoplasmic organization - Shape recovery - Cargo selection
* Deformation response * Specific targeting
* Elasticity maintenance * Load distribution
* Structure restoration * Transport priority
 Portion of cell interior not occupied by the nucleus or other
membrane-bound organelles
Many cellular activities involved
Consist of intricate three-dimensional array of interconnected
filaments and tubules called the cytoskeleton : the cytoskeletal
network
Establish and maintain cellular shape
 Important roles in cell movement and cell division
– E.g. contraction of muscles cells, beating of cilia and
flagella, movements of chromosomes and
locomotion of the cell
Positioning and actively moving organelles within
the cytoplasm
– Same for ribosomes and enzymes
Water also influence the cytoskeleton dynamics
3 major structural elements
– Microtubules
– Microfilaments (actin filaments)
– Intermediate filaments
 Cytoskeleton: Microtubules
Role in motiliy
– E.g.: axoneme of cilia and flagella
Role in chromosome movement
– Form spindle fibers needed to separate
chromosomes prior to cell division
Role in organisation of the cytoplasm
– the polarity and overall shape of the cell
– Spatial disposition of its organelles
– Distribution of microfilaments and
intermediate filaments
Examples of diverse role:
– asymmetric shapes of animal cells,
– the plane of cell division in plant cells,
– the ordering of filaments during muscle
development and
– the positioning of mitochondria around
the axoneme of motile appendages
 Straight, hollow cylinders
Wall consists of longitudinal
arrays of protofilaments, usually
13 arranged side by side around
the hollow centre, or lumen
Each protofilament is a linear
polymer of tubulin molecules
– Dimeric protein; α-tubulin and b-
tubulin
– Oriented in the same direction,
i.e. all subunits face the same end
in microtubule, hence uniform
orientation
– polarity
 Role in the contractile fibrils of muscle cells
Form connections with the plasma membrane
– Influence locomotion,
– amoeboid movement,
– cytoplasmic streaming (a cyclic flow of
cytoplasm seen in variety of algal, animal and
plant cells)
Produce cleavage furrows that divide the
cytoplasm of animal cells after chromosomes
have been separated by the spindle fibers
Contribute importantly to the development and
maintenance of cell shape
 Cytoskeleton: Microfilaments

Polymers of actin
– Synthesised as monomer called G-actin (G = globular)
– G-actin monomers polymerise reversibly into long, double-
helical strands of F-actin (F for fibrous)
Consists of two strands of F-actin wrapped around each other
to form a double helix
Polar structures, similar to microtubules
– Influence the direction of elongation and disassembly
 Cytoskeleton: Intermediate Filaments

Most stable and the least
soluble constituents
– Scaffold that supports
the entire cytoskeletal
network
– A tension-bearing role
Composition differ from
tissue to tissue
– Grouped into 5 classes
– IFs serves as a diagnostic
tool for medicine
https://www.ncbi.nlm.nih.gov/pmc/articles/P
MC6562751/
 Have a central rodlike
segment, similar to all 5
classes
– The N-terminal and C-
terminal segments differ
greatly in size and
sequence
Basic structural unit is a
dimer of two intertwined
IF polypeptides tetramer

Two dimers align laterally
to form a tetrameric
protofilament
Protofilament interact
with each other to form
an IF
– Up to 8 protofilaments
– Joined end to end in
overlapping manner
 Ribosomes:
The Protein Factories
Structure Function Role in Homeostasis
1. Prokaryotic Ribosomes (70S) 1. Protein Synthesis A. Protein Homeostasis B. Metabolic Homeostasis
- Small subunit (30S) - Translation initiation 1. Translation Control 1. Energy Balance
* 16S rRNA - Elongation - Protein synthesis regulation - Translation efficiency
* 21 proteins - Termination * Rate adjustment * ATP utilization
* Decoding center - Quality control * Quality control * Energy conservation
* Energy efficiency * Resource allocation
- Large subunit (50S) 2. Regulatory Roles - Stress response - Metabolic coupling
* 23S and 5S rRNA - Translation regulation * Heat shock response * Energy sensing
* 31 proteins - Protein folding * Unfolded protein response * Pathway coordination
* Peptidyl transferase center - Cellular stress response * Metabolic adaptation * Resource management
- Gene expression control
2. Eukaryotic Ribosomes (80S) 2. Protein Quality Control 2. Stress Adaptation
- Small subunit (40S) - Error detection - Response coordination
* 18S rRNA * Proofreading * Stress protein synthesis
* 33 proteins * Mistake prevention * Repair mechanism
* mRNA binding site * Quality assurance activation
- Response mechanisms * Protective measures
- Large subunit (60S) * Protein folding
* 28S, 5.8S, and 5S rRNA * Degradation signaling
* 47 proteins * Repair processes
* Exit tunnel
 Involved in protein synthesis from
amino acids
Not a true organelle
Found in both eukaryotic and
prokaryotic cells
– Difference in sizes
25nm-30nm in eukaryotic cells, 20 nm
is prokaryotic cells
– 350,000 ribosomes in a bacterial cell
Sedimentation coefficient
– Express sizes of small particles
– How rapidly the particle sediments in
an ultracentrifuge
– Svedberg units (S)
– Eukaryotic cell; 80S and prokaryotic cell;
70S
 2 subunits with differing sizes
– In Eukaryotic cell, large and small
ribosomal subunits are 60S and 40S,
respectively
– In Prokaryotic cell; 50S and 30S
respectively
– Both are synthesised and assembled
separately in the cell
Eukaryotic cells have more
ribosomes than Prokaryotic
cells
Can also be found in
mitochondria and chloroplast
– Differ in size and composition from
ribosomes in the cytoplasm
– Very similar to those found in bacteria
and blue-green algae
By RIT RAJARSHI - Own work, CC BY-SA 4.0
THE OTHERS
Structural components: Cell Coats
Structural components: Cell-to-cell junction
Strengthen the cell surface and
hold cells together
Important in cell-cell
recognition, due to the unique
molecular structure of
carbohydrates
Intercellular connections:
– Gap junctions; transfer of material
between the cytoplasms of
adjacent cells
– Tight junctions; hold cells together
and block any transport of
substances
– Desmosomes; Disc-shaped type of
specialised adhesive junction to
give structural integrity and
function as a unit
Example of Cell-to-cell junction
 THANK YOU!
ALL THE BEST!

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