Cell Structure and Function PDF

Summary

This document provides an outline of cell structure and function. It details various cell components such as the cell membrane, nucleus, endoplasmic reticulum, Golgi apparatus, lysosomes, peroxisomes, and mitochondria, discussing their structure and functions. The document also covers topics such as energy production, protein and lipid biosynthesis, the cytoskeleton and intracellular transport mechanisms.

Full Transcript

Cell Structure and Function
MED 1103:Histology 1
Lecturer: Dr Christopher Heywood
Quotable quote

“The whole is greater than the sum of its parts”
- Aristotle
 Outline
1. Introduction 1. Energy production and storage
2. Cell components: 2. Ribosomes
- Cell membrane 3. Protein Biosynthesis and degradation
- Nucleus 4. Lipid Biosynthesis
- Endoplasmic Reticulum 5. Cytoskeleton
- Golgi apparatus 6. Intra and intercellular transport
- Lysosomes 7. References
- Peroxisomes
- Mitochondria
Introduction: The Cell
Functional unit of living organisms
Comprises Cytoplasm and Nucleus
Cytoplasm: Cytosol + Organelles –
Nucleus
Membrane-bound organelles provide
ideal microenvironments
Membranes participate in reactions
based on associated enzymes
Cell Components- Cell Membrane
Aka Plasma Membrane or
Plasmalemma
Structure:
- Amphiphilic phospholipid bilayer with
cholesterol
- Unsaturated and Saturated tails usually
present
- Intrinsic membrane proteins/
carbohydrates/ lipids
- Glycolipids and glycoproteins form
glycocalyx
- Fluid mosaic model
 Cell components- Cell Membrane
Functions:
- Separation of Internal contents from
exterior (cells, extracellular matrix)
- Nutrient transfer e.g. aquaporins
- Glycocalyx:
i. Cell adhesion
ii. Intercellular signaling
iii. Mechanical and chemical protection
Cell components- Nucleus
Structure:
- Largest organelle
- Nucleoplasm bound by nuclear
membrane/ envelope
- Found in all cells except erythrocytes
Cell components- Nucleus
- Contains DNA, RNA, nucleoproteins
- Nucleoproteins:
o synthesized in cytoplasm: histone
(structural), non-histone (enzymes)
o Nucleosome= chromosome + histone
- Nucleosomes seen as euchromatin
(electro-lucent, active) and
heterochromatin (electrodense, inactive)
Cell components- Nucleus
- RNA:
o transfer, messenger and ribosomal
o micro RNA, small nuclear RNA and
small interfering RNA

- Barr body: inactivated X chromosome
in females
Cell components- Nucleus
- Variations in shape and polarity of
nucleus help in cell identification:
o Round/ Oval: epithelial
o Spindle-shaped: smooth muscle
o Bi-lobed: Eosinophils
o Flattened: endothelial cells
Cell components- Nucleus
- Nuclear envelope comprises:
o Two lipid bilayers separated by
intermembranous/ perinuclear space
o Outer membrane continuous with E.R.
o Intermembranous space continuous
with E.R. lumen
o Nucleoporins in complex forming
pores
o Lamins which link membrane proteins
to chromatin
Cell components- Nucleus
- Nucleolus:
o Site of rRNA synthesis and assembly;
tRNA processing
o Controls cell cycle and stress
responses
o Comprises ribosomal genes, rRNA,
ribosomal proteins and ribonuclear
proteins
o Changes size with cell activity
 Cell components- Nucleus
- Nucleolus:
o Includes:
i. dense fibrillar components (rRNA
synthesis)
ii. fibrillar centres
iii. granular component (ribosome
assembly)
Cell components- Nucleus
Function:
- Storage and replication of genetic
material
- Allows for differentiation via
variations in histone physical and
chemical structures
Cell components- Endoplasmic Reticulum
Structure:
- Flattened membrane-bound saccules,
tubules, cisternae
- May be smooth or rough (associated
with ribosomes)
 Cell components- Endoplasmic Reticulum
Function:
- Rough ER:
o Protein synthesis
o Modification and folding of proteins
i. creating tertiary structure
ii. forming disulphide bonds
iii. starting glycosylation
Cell components- Endoplasmic Reticulum
Function:
- Smooth ER:
o Lipid synthesis (cholesterol,
phospholipids, steroids), membrane
synthesis and repair
o Metabolism and detoxification via
cytochrome p450 in liver
o Storage and release of Ca 2+ ions
Cell components- Golgi Apparatus
Structure:
- Located near nucleus
- Comprises membrane- bound
cisternae/saccules
- Each cisternae has specific enzyme to
add specific sugar
- Cis (convex) and trans Golgi networks
Cell components- Golgi Apparatus
Function:
- Receive uncoated (COP 2) or coated
(COP 1) vesicles from rER
- Final assembly and glycosylation of
proteins and lipids
- Synthesis of glycosaminoglycans
- Dispatching of proteins to their
ultimate destination
(SNARE proteins allow docking at
particular destination)
Cell components- Lysosomes
Structure:
- Contains hydrolytic enzymes
(protease, lipase, nuclease) at low pH
- May be associated with:
o Secondary/ phagolysosomes
o Late endosomes/ multivesicular bodies
Cell components- Lysosomes
Functions:
- degrade old or unnecessary cellular
cells (autophagy)
- degrade phagocytosed or endocytosed
material
Cell components- Peroxisomes
(microbodies)
Structure:
- Membrane-bound vesicle containing
oxidases and catalase

Functions:
- Production of hydrogen peroxide for
killing pathogens
- detoxification of certain toxic materials
- β-oxidation of long chain fatty acids
- synthesis of bile acids (in liver)
Cell components- Mitochondria
Structure:
- elongated, sausage-shaped; mobile (via
microtubules)
- variable in number. Division, Fusion
and autophagy influence numbers
- Smooth outer membrane, convoluted
inner membrane
- self-replicate
Cell components- Mitochondria
Structure comprises:
o Outer membrane- includes porins,
enzymes
o Inner membrane- folded into cristae
o Inner cavity- has matrix with
mitochondrial DNA, granules,
ribosomes, enzymes
o Intermembranous space- contains
enzymes, cytochromes
Energy production and storage
Cellular respiration (anaerobic or aerobic) leads to provision of energy
Mitochondrial respiration is strictly aerobic
Mitochondrial respiration occurs within matrix and on inner membrane
Energy is usually stored in the form of ATP
Glycolysis:
-begins in cytosol producing pyruvate (and small quantity of ATP).
-Pyruvate migrates to mitochondria where most ATP is produced
ATP production from fatty acids occurs entirely in mitochondria
Ribosomes
Structure:
- Comprises two rRNA subunits bound to
proteins
- May be attached to rER or free
- Contain ribozymes
- May be attached to mRNA (polyribosomes)
Ribosomes
Functions:
- To align mRNA so tRNA can bring respective
amino acids in sequence
- catalyse peptide bond formation between
amino acids
- Attached to rER: Produce and modify proteins
for export, lysosomes, integral membrane
proteins
- Free: Produce modify proteins for cytoplasm,
mitochondria, nucleus;
Proteins- Biosynthesis and Degradation
Proteins may be:
- Structural e.g. collagen, elastin
- Enzymes
- Transport molecules
- Regulatory molecules

All cells types produce protein with some having a more dominant role
Differentiation allows for specific expression by individual cells
Protein Biosynthesis- Procedure
1. Transcription:
Pre-mRNA is formed as a complementary copy
of a gene

2. Post-transcription processing:
Spliceosome (small nuclear RNA)+proteins
remove introns (non-coding regions of genes)
to form mRNA

3. Translation
mRNA leaves nucleus and binds to ribosomes
and mRNA is read
 Protein Degradation
1. Damaged or useless proteins bind to Ubiquitin

2. Proteasomes (proteolytic enzymes closely associated but without an enclosing membrane) take
up bound proteins

OR

3. Proteolytic enzymes within lysosomes degrade proteins
 Lipid Biosynthesis
Occurs in all cells
Fatty acids, triglycerides are synthesised in the
cytosol
Cholesterol and phospholipids are synthesised
in the sER
May be done to:
i. replenish membranes
ii. Store energy
iii. Transport lipids
iv. Transfer information to other cells
Cell components- Cytoskeleton
Structure:
- Includes: microfilaments, intermediate
filaments and microtubules
- Made of protein subunits (monomers)
bound into filaments (polymers)
- Include motor proteins (actin, myosin
kinesin)
Cell components- Cytoskeleton
Functions:
- maintain cell shape and orientation
- cell movement
- movement of organelles around the
cell
- movement of chromosomes during cell
division
Cell components- Cytoskeleton
Microfilaments
- F-actin: 5-7 nm strands with two
protofilaments twisted together
- G-actin: monomers making up
protofilaments, associated with ATP
- These structures are then arranged into
3D structures
- Sliding of actin and myosin (in
muscle) cause contraction
Cell components- Cytoskeleton
Intermediate filaments
-~10 nm in diameter
- Self assemble and bind intracellular
structures together
- Many varieties exist, which aid in
identification
Cell components- Cytoskeleton
Microtubules
-~25nm in diameter
- Form from polymerisation of subunits
(alpha and beta tubulin)
-Centrosome: 2 centrioles (diplosome)
from which tubulin molecules originate
(microtubule organizing centre)
 Intra and Intercellular transport
1. Passive Diffusion
- Movement down an electrochemical gradient in the absence of energy
- Influenced by size, polarity and charge of molecule
- Includes:
o Lipids and lipid soluble (non-polar) molecules e.g. hormones
o Gases (CO2, H2O, N2)
o Small polar molecules- Water, urea
Intra and Intercellular transport
2. Facilitated Diffusion
- Use of special proteins to move hydrophilic molecules
- Carriers may be pores/ channels or transporters
- Some channels are gated
-Includes transport of: water, ions, glucose, amino acids
Intra and Intercellular transport
3. Active transport
- Pumping of substances against electrochemical gradient using energy generated by ATP

4. Bulk transport
- Occurs vis use of vesicles
- Vesicles form from addition of membrane to a protein coat
- Includes: endocytosis, exocytosis, intracellular transport
Intra and Intercellular transport
5. Transmembrane signaling
- Occurs via:
o hormones entering cell and binding to receptor (oestrogen)
o Receptor binding leading to intracellular signaling (insulin)
o Binding to ion channels causing depolarization (neurotransmitters)
Intra and Intercellular transport
Exocytosis
- Can be constitutive (all cells) or regulated
- Regulated exocytosis is signal-dependent
- Procedure:
o Coated vesicles leave Golgi and fuse with
others to form larger vesicles
o Microtubules aid movement of vesicles
o As they approach lumen they become more
concentrated as they lose excess membrane
o Vesicle merges with membrane and release
contents via porosome
Intra and Intercellular transport
Endocytosis
-Includes phagocytosis (> 0.5 µm), pinocytosis,
transcytosis
- Pinocytosis may be:
o Clathrin-mediated (involves clathrin, receptors,
ligands)
o Caveolae- mediated
o Macropinocytosis
S.E.- Sorting endosome; R.E.- Recycling endosome;
CV- coated vesicle; MVB- multivesicular body; LE-
late endosome; EL- endolysosome
Intra and Intercellular transport
-Phagocytosis:
o Includes WBC’s such as neutrophils,
macrophages
o Pseudopodia form around substrate
after binding with receptors
o Phagosome forms then fuses with
lysosome, becoming phagolysosome
o Residual bodies may remain,
accumulating with time to form
lipofuscin granules
Cell components- Cytoskeleton
Microtubules
- Motor proteins (dynein and kinesin)
move along tubules
- Addition or removal of subunits cause
movement
- Alpha tubulin ring complexes form
area for polymerization
- Microtubule associated proteins
stabilize structure
 References
1. Young, B., Woodford, P., & O’Dowd, G. (2013). Wheater’s functional histology (6th ed.).
Churchill Livingstone.
2. www.youtube.com. (n.d.). Endosome, Lysozome and phagosome. [online] Available at:
https://www.youtube.com/watch?v=6MZN24Il5Sc [Accessed 3 Oct. 2022].
3. www.youtube.com. (n.d.). Cytoskeleton Structure and Function - YouTube. [online] Available at:
https://www.youtube.com/watch?v=YTv9ItGd050.