Medical Biology and Genetics Lecture Notes 2024 PDF

Summary

These lecture notes from Kocaeli Health and Technology University cover Medical Biology and Genetics, specifically focusing on organelles, ribosomes, and the plasma membrane. The notes also include information on lysosomes and related disorders.

Full Transcript

KOCAELİ HEALTH AND TECHNOLOGY UNIVERSITY
FACULTY OF PHARMACY (ENGLISH)

MEDICAL BIOLOGY and GENETICS
Lecture-3
Organelles

Assist. Prof. Dr. Seval ÇINAR
[email protected]

2024
Nucleus
The nuclear envelope is a double membrane structure that encloses the
nucleus in eukaryotic cells, separating the nucleoplasm from the
cytoplasm.
The nuclear envelope comprises two lipid bilayers:
the inner nuclear membrane and
the outer nuclear membrane, which is continuous with the endoplasmic
reticulum.
Nuclear pores that facilitate the transport of proteins and RNA
molecules.
 Nuclear Envelope-Related Disorders:

Disorders associated with defects in the nuclear envelope can result in a range
of diseases, often referred to as nuclear envelope disorders or
laminopathies.
Many of these disorders are linked to mutations in the genes encoding nuclear
envelope proteins, particularly lamin A/C, which are key elements of the
nuclear lamina. Some notable disorders include:

→Muscular Dystrophy:
Inherited genetic disorders characterized by progressive weakness and
degeneration of the skeletal muscles
These disorders primarily occur due to mutations in the genes responsible for
maintaining healthy muscle fibers.
Certain forms of muscular dystrophy, such as Emery-Dreifuss muscular
dystrophy, are associated with mutations in the emerin (a nuclear envelope
protein). This leads to muscle wasting and joint contractures.
 Nuclear Envelope-Related Disorders:

→Progeria (Hutchinson-Gilford Progeria Syndrome):
Progeria Syndrome is a rare genetic disorder
characterized by rapid aging in children.
Caused by a mutation in the LMNA gene that produces a
defective form of lamin A called progerin. This leads to
premature aging features, cardiovascular problems, and
reduced life expectancy.
LMNA gene encodes lamin A and lamin C
Ribosomes
They are found in all cells
They are not membranous.
Ribosomes are the sites of protein synthesis in both prokaryotic and eukaryotic cells.
Both prokaryotic and eukaryotic ribosomes consist of large and small subunits, which
contain both ribosomal proteins and rRNAs.
Their basic structure is the RNA-protein complex (ribonucleoprotein)
→ Location in the Cell:
Free Ribosomes: These float freely in the cytoplasm and typically synthesize proteins that function
within the cytosol.
Bound Ribosomes: These are attached to the endoplasmic reticulum (ER), forming rough ER, and
are involved in synthesizing proteins that are either secreted from the cell or incorporated into cellular
membranes.
 Ribosomes
Intact prokaryotic and eukaryotic ribosomes are designated
70S and 80S, respectively, on the basis of their sedimentation
rates in ultracentrifugation.
S: Svedberg unit=Sedimentation coefficient

In eukaryotes, the large subunit is known as 60S, and the small
subunit is 40S, combining to form an 80S ribosome.
In prokaryotes, the subunits are 50S (large) and 30S (small),
forming a 70S ribosome.

The small subunit is primarily responsible for reading the
mRNA (messenger RNA)
The large subunit is where peptide bonds are formed between
amino acids to create proteins.
Cytoplasm:

The gel-like substance within the cell membrane that contains
organelles, where various cellular processes occur.
Cytoplasm: It is the name given to all the contents of the cell.
Cytoplasm contains cytosol, organelles (in eukaryotes), ribosomes,
nutrient granules, metabolites and ions.
Cytosol: The fluid that fills the cytoplasm.
 The Plasma Membrane
All cells—both prokaryotic and eukaryotic—are surrounded by a plasma membrane (cell membrane)
Separates and protects the interior of all cells from the external environment.
It plays a critical role in maintaining the cell's integrity and homeostasis.

Structure of the Eukaryotic Plasma Membrane
1.Phospholipid bilayer:
1. Hydrophilic heads face outward
2. Hydrophobic tails face inward
Amphipathic (Amphiphilic) Molecule:
It is a molecule that has both hydrophilic and hydrophobic
parts in its structure.
Phospholipids are amphipathic
2. Membrane proteins:
1. Integral proteins: span the entire membrane
2. Peripheral proteins: attached to one side
3. Cholesterol: provides stability and fluidity
4. Glycoproteins and glycolipids: carbohydrate
chains on the outer surface
 The membranes of animal cells contain five
major phospholipids:
phosphatidylcholine,
phosphatidylethanolamine,
phosphatidylserine,
phosphatidylinositol,
sphingomyelin
Phospholipids are asymmetrically
The outer leaflet consists predominantly of
phosphatidylcholine, sphingomyelin, and
glycolipids
Organization of plasma membrane lipids
The inner leaflet contains
phosphatidylethanolamine, phosphatidylserine,
and phosphatidylinositol.
Cholesterol is distributed in both leaflets.
The Fluid Mosaic Model
Proposed by Singer and Nicolson
in 1972
Describes the plasma membrane
as a fluid structure with freely
moving components
Key features:
Phospholipids can move laterally
within the membrane
Proteins can diffuse within the lipid
bilayer
Asymmetrical distribution of lipids
and proteins
Membrane fluidity affected by
temperature and cholesterol
content
Functions of the Eukaryotic Plasma Membrane
1.Selective permeability:
1. Controls movement of substances in and out of the cell
2. Acts as a selective barrier between cell and environment
3. Allows passage of small, nonpolar molecules
4. Regulates movement of larger or charged molecules
2.Cell recognition:
1. Glycoproteins and glycolipids on the outer surface
2. Glycoproteins act as cellular ‘ID tags’
3. Important for immune system function and cell-cell communication
3.Signal transduction:
1. Membrane proteins can act as receptors for hormones and other signaling
molecules and detect external signals
2. Triggers intracellular responses
4.Enzymatic activity:
1. Some membrane proteins function as enzymes
 Membrane Transport Mechanisms
The passage of most biological molecules is mediated
by carrier or channel proteins that allow polar and
charged molecules to cross the plasma membrane
without interacting with its hydrophobic interior.

1.Passive transport:
1. Diffusion: movement of molecules from high to low
concentration
2. Facilitated diffusion: assisted by channel or carrier proteins
2.Active transport:
1. Requires energy (ATP)
2. Pumps molecules against their concentration gradient
3.Bulk transport:
1. Endocytosis: brings materials into the cell
2. Exocytosis: releases materials from the cell
1. Passive Transport
It does not require energy (ATP)
It occurs along the concentration gradient,
meaning substances move from an area of
higher concentration to an area of lower
concentration.
Simple Diffusion: The movement of small,
nonpolar molecules (like oxygen and carbon
dioxide) directly through the lipid bilayer.
Facilitated Diffusion: This involves specific
transport proteins that help larger or polar
molecules (like glucose and ions) pass through
the membrane. Examples include:
Carrier Proteins: Bind to specific molecules and
change shape to shuttle them across the membrane.
Channel Proteins: Form pores that allow specific
ions or water to pass through.
Osmosis: The diffusion of water across a
semipermeable membrane. Water can move
through the lipid bilayer but more commonly
passes through specialized channels called
aquaporins
2. Active Transport
Movement of molecules against concentration
gradient
Requires energy input (usually ATP)
Moves substances from areas of lower to higher
concentration
Essential for maintaining cellular homeostasis
Mechanisms of Active Transport
1.Primary Active Transport:
Directly uses ATP for energy
Example: Na⁺/K⁺-ATPase pump
2.Secondary Active Transport:
Uses electrochemical gradient created by primary
active transport
Examples: glucose and amino acid transport
3. Bulk Transport (Vesicular Transport)
This mechanism is used for transporting large molecules or particles
that cannot fit through the membrane.
It requires energy and involves the creation of vesicles.
Endocytosis: The process of bringing substances into the cell.
Phagocytosis: "Cell eating" - engulfing large particles or cells.
Pinocytosis: "Cell drinking" - taking in fluids and small solutes.
Exocytosis: The process of expelling materials from the cell by
vesicles that fuse with the plasma membrane, releasing their
contents outside.
Phagocytosis

Binding of a bacterium to the cell surface
stimulates the extension of a pseudopodium,
which eventually engulfs the bacterium.
Fusion of the pseudopodium membranes then
results in formation of a large intracellular
vesicle (a phagosome).
The phagosome fuses with lysosomes to form a
phagolysosome within which the ingested
bacterium is digested.
 4. Specialized Transport Mechanisms
Aquaporins: Water channels that facilitate rapid water movement
across the membrane.
Ion Channels: Specialized proteins that allow specific ions to pass
through the membrane, typically responding to stimuli (voltage-
gated, ligand-gated, or mechanically gated).
 Protein Sorting and Transport

The Endoplasmic Reticulum, Golgi Apparatus, and Lysosomes
The endoplasmic reticulum (ER):
Eukaryotic cells have a variety of membrane-enclosed organelles within their cytoplasm, in addition
to nucleus.
ER is a network of membrane-enclosed tubules and flattened sacs that extends from the nuclear
membrane throughout the cytoplasm.
There are two membrane domains within the ER that perform different functions within the cell:
The rough ER,which is covered by ribosomes on its outer (cytosolic) surface
Protein synthesis and modification
Produces proteins for secretion or insertion into cell membranes
The smooth ER is not associated with ribosomes. Main functions:
Lipid synthesis
Carbohydrate metabolism
Detoxification of drugs and harmful substances
The ER and Cellular Transport

ER works closely with the Golgi apparatus
Vesicles bud off from the ER, carrying proteins
and lipids
These vesicles fuse with the Golgi for further
processing
Some proteins are sent directly to their
destinations from the ER

The ER's role in protein targeting:
Signal Recognition Particle (SRP): Recognizes signal sequences
Translocation: Movement of proteins into the ER lumen
Post-translational modifications in the ER:
1.Folding
2.Glycosylation
3.Disulfide bond formation
 Protein Sorting
Proteins synthesized on free ribosomes
either remain in the cytosol or are
transported to the nucleus, mitochondria,
chloroplasts, or peroxisomes.
In contrast, proteins synthesized on
membrane-bound ribosomes are
translocated directly into the ER through the
translocon.
These proteins contain signal sequences
(indicated in red) that are cleaved during
translocation.
Proteins that are translocated into the ER
may be either retained within the ER or
transported to nuclear membranes,
peroxisomal membranes, or the Golgi
apparatus and, from there, to endosomes,
lysosomes, the plasma membrane, or the
cell exterior via secretory vesicles.
 Protein targeting to the endoplasmic reticulum
(ER) is a crucial process in cellular biology that
ensures proteins are correctly localized within
the cell.
1. Signal Peptide: ER-bound proteins usually have
an N-terminal signal peptide that is recognized
by the signal recognition particle (SRP) during
translation.
2. Translation and SRP: As a protein is targeting of secretory proteins to the ER
synthesized, the signal peptide emerges,
prompting SRP to bind and direct the complex
to the ER membrane, pausing translation.
3. Translocon: The ribosome binds to the ER
membrane via the translocon, allowing the
polypeptide to enter the ER lumen or
membrane.
4. Co-Translational Translocation: Translation
resumes as the polypeptide chain is threaded
into the ER.
5. Protein Folding and Modifications: In the ER,
proteins fold with the help of chaperones and
undergo modifications like glycosylation.
6. Quality Control: The ER ensures only correctly
folded proteins move along the secretory
pathway. Misfolded proteins are targeted for
degradation.
7. Transport to Golgi Apparatus: Correctly folded
proteins are packaged into vesicles and sent to
the Golgi for further processing.
Endoplasmic Reticulum (ER) Stress and Related Disorders:

ER stress occurs when misfolded
proteins accumulate
Under normal conditions, the ER
maintains cellular homeostasis;
however, various stressors—such as
oxidative stress, inflammation—can
lead to ER stress.
Since only correctly folded proteins
are transported to the Golgi
apparatus, unfolded proteins
accumulate in ER and cause ER
stress.
Endoplasmic Reticulum (ER) Stress and Related Disorders:

This stress triggers a cellular response
known as the unfolded protein response
(UPR).
UPR aims to restore normal ER function
by:
Increasing protein folding capacity
Decreasing protein synthesis
Increasing degradation of misfolded proteins
Prolonged or unresolved ER stress can
lead to cell dysfunction and death,
contributing to various diseases.
Endoplasmic Reticulum (ER) Stress and Related Disorders:
ER dysfunction linked to various diseases:
1.Neurodegenerative Diseases:
Alzheimer's Disease:
Complex neurodegenerative disorder characterized by progressive cognitive
decline, memory loss, and behavioral changes.
Certain genes increase the risk of developing Alzheimer's. The presence of the
‘apolipoprotein E’ allele is a significant genetic risk factor
One area of research that has also gained attention in recent years is the role of
endoplasmic reticulum (ER) stress in Alzheimer's disease.
Emerging evidence indicates that ER stress contributes to the development of AD.
In AD, protein aggregation (such as, amyloid-beta and tau) can overwhelm the
protein folding capacity of the ER, leading to ER stress and neuronal death.
Endoplasmic Reticulum (ER) Stress and Related Disorders:

ER dysfunction linked to various diseases:
2. Metabolic Disorders:

Insulin Resistance: ER stress has been implicated in the development of
insulin resistance, a hallmark of type 2 diabetes. When the ER is stressed, it
can lead to inflammation and impaired insulin signaling pathways,
contributing to metabolic dysfunction.

Obesity: ER stress in adipocytes (fat cells) can lead to altered lipid
metabolism and inflammation, promoting the development of obesity-related
metabolic disorders.
Golgi apparatus
The Golgi apparatus, also known as the Golgi
complex.
Often described as the cell's "shipping and packaging
center"
Plays a vital role in modifying, sorting, and packaging
proteins and lipids for distribution

Structure of the Golgi Apparatus
Composed of a series of flattened, membrane-bound
sacs called cisternae
Typically arranged in a stack of 5-8 cisternae
Two distinct faces:
cis face: Receives vesicles from the endoplasmic
reticulum
trans face: Sends modified molecules to their final
destinations
Associated with numerous small vesicles for transport
Golgi apparatus
Importance in Cell Function
Essential for proper protein and lipid modification
Crucial for cellular secretion processes
Vital for the formation of the cell wall in plant cells
Congenital Disorders of
Plays a role in cell division by helping to form the cell plate
Glycosylation
Disorders related to Golgi dysfunction can lead to various
diseases, including Congenital Disorders of
Glycosylation (CDG)

→CDGs are a group of inherited metabolic disorders
caused by defects in the glycosylation process, which often
involves the Golgi apparatus.
These disorders can lead to a range of symptoms, including
developmental delays, intellectual disability, and multiorgan
dysfunction.
Lysosomes
Lysosomes are membrane-bound organelles found
in eukaryotic cells that contain enzymes necessary
for breaking down various biomolecules.
They play a crucial role in the cell's waste disposal
system by digesting macromolecules, old cell parts,
and microorganisms.
Here are some key features and functions of
lysosomes:
Structure:
Membrane-bound: Lysosomes are surrounded by a single
lipid bilayer that protects the rest of the cell from the
enzymes contained within.
Enzymes: They contain hydrolytic enzymes, including
proteases, lipases, and nucleases, which are active at the
acidic pH maintained inside the lysosome.
Functions of lysosomes:
1.Digestion: They break down complex
molecules (proteins, lipids, carbohydrates,
and nucleic acids) into simpler ones that can
be reused by the cell.
2.Autophagy: Lysosomes play a significant role
in autophagy, the process where cells
degrade and recycle their own components,
including damaged organelles.
3.Defense: They can destroy pathogens that
have been engulfed by the cell, such as
bacteria and viruses.
Autophagy
4.Cell signaling: Lysosomes also participate in Regions of the cytoplasm or internal organelles (such as
cellular signaling pathways and can influence mitochondria) are enclosed by membranes derived from
the endoplasmic reticulum, forming autophagosomes.
metabolic processes. Autophagosomes fuse with lysosomes to form large
phagolysosomes in which their contents are digested.
Associated Diseases:
Lysosomal storage disorders:
Inability to break down certain molecules.
These conditions are caused by genetic defects that affect the enzymes
responsible for processing substrates within the lysosome.
Result: accumulation of harmful substances in cells
Examples: Gaucher disease, Tay-Sachs disease
→Gaucher disease is the most common lysosomal storage disease and but is quite
rare.
Mutations in the GBA gene, which is responsible for the production of enzymes that
break down lipids, cause this condition.
→Tay Sachs disease, a rare genetic disorder, deeply affects the nervous system,
especially in infancy.
 Topology of the secretory pathway

The lumens of the ER and Golgi apparatus are
topologically equivalent to the exterior of the
cell.

Consequently, those portions of polypeptide
chains that are translocated into the ER are
exposed on the cell surface following transport
to the plasma membrane.