4. Cell.pptx

Transcript

The Human
Cell
- Dr.Sonam Yoezer
Outcomes
1. What is cell ?

2. Contents of cell ?

3. Organelles

4. Cellular respiration

5. Function of organelles?
What is cell?
1. The smallest structural and functional
unit of life.

2. Building block of life.

Contains : Cell membrane, nucleus
Cytoplasms and organelles.
Eukaryotic vs Prokaryotic
Nucleus :
Eukaryotic has nuclear membrane. Prokaryotic has
DNA in nucleoid region.

Size : Eukaryotic cells are larger than
prokaryotic : 10-100 micro meter vs 0.1 to 5.0
micro meter

Complexity : prokaryotes lack membrane bound
organelles (ER, Golgliapparatus and lysosomes.
 Cell Division : mitosis for both and meiosis in
eukaryotes

Cytoskeleton : less complex and rudimentary
cytoskeleton in prokaryotes.

Ribosomes : larger ribosomes (80S) smaller
ribosome (70S)
Main contents of the cell ?
Water
Proteins
Lipids
Carbohydrates
Nucleic acid
Electrolytes
Vitamins
Trace minerals, peptides, steroids,
glycoproteins…
 Which atom makes the most part of
you?

Oxygen : 65% of body mass
Carbon : 18 percent
Hydrogen : 10 % of body mass
Nitrogen : 3% of body mass
 By number of atoms :

Hydrogen : 63% (4.4 X 10 27
atoms)
Oxygen : 25 %
Carbon : 10 %
Important electrolytes
Sodium (0.1% i.e 100gm in 70kg ; 2.6 X 10
24
)
Potassium (0.2% i.e 140 gm in 70 kg, 2.2 X 10
24
)
Calcium
Magnesium
Chloride
Phosphate
Zinc, Iron, copper, manganese, molybdenum,
iodine
Gold? (0.2 mg (200 mcg) in a 70 kg
How big/small is a cell ?
Animal cell : 10 -30 micrometers

Smallest? Longest ? Biggest? In human

Neurons can reach over a meter in
human
Muscle cells can be 30 cm long
Smallest : 6-8 micometer
Largest : Oocyte about 100 micro meter
Plasma Membrane
is a thin, pliable, elastic structure.
Consists of two layers of phospholipids (bilayer)
with some protein molecules embedded in them.

One end (phosphate end) of each phospholipid
molecule is hydrophilic and soluble in water.
The other end (fatty acid portion) is
hydrophobic and soluble in fats.
 The hydrophilic phosphate portions:
in contact with intracellular water on
the inside
extracellular water on the outside
surface.

The hydrophobic portions:
are repelled by water but are mutually
attracted.
Cell membrane Proteins
(globular)
Integral proteins: Embedded partially or
throughout the bilayer.

Functions:

Transport : Aquaporins, Glucose Transorter
(GLUT), Sodium-potassium pump.

Receptors : G-Protein coupled receptors, Insulin
receptors.
 Enzymatic proteins : cytochrome P450; Adenylyl
cyclase

Cell Adhesion Molecules : cadherins and
integrins.

Glycoproteins and glycocalyx : cell recognition,
immune response, cell adhesion, structural
support. Eg. ABO blood group antigen
Anchoring proteins for cell size and structure
maintenance. Eg. spectrins, dystrophin.
 Ion channels : ions such as : calcium, sodium,
chloride.

Toll-like receptors :

recognize Pathogen associated molecular patterns
and activate innate immune response. This will
stimulate and lead to two key transcription factors.

Cytokines : TNF – alpha, IL-6 and IL-1beta.
Signal transduction proteins.

Convert extracellular signal into intracellular
responses :

Receptor Tyorsine Kinases : Epidermal Growth
Factor Receptor (EPGFR) in cell growth and
differentiation and Insulin.

G Protein Coupled Receptors : ligands activate
G-protein and modulate adenylate cyclase and
phospholipase C. eg. Adrenaline and
2. Peripheral proteins:

Attach to exterior or interior surface. Bound to
integral proteins or phospholipids.

Functions : structural support, cell signaling
and aiding in cell’s response to external
stimuli.

3. Cholesterol :

Modulating membrane fluidity and stability
Organelles
Organum : latin for tools
-elle : French for a mini version

Specializes structures within the cell that
performs specific functions essentials for the
cell’s survival and operations.
Functions of Cell membrane
Selective permeability
Protection from outside
Anchoring and attachment points for
cytoskeleteon giving support and shape.
Receptors molecules allow the cell to
receive signals and communicate.
Molecules on surface for recognition and
adhesions, immune response and tissue
formation.
Organelles
 Nucleus
 Mitochondria
 Ribosomes
 Endoplasmic reticulum
 Golgi apparatus
 Lysosomes
 cytoskeleton
Cell transportation
Passive transport : No energy required

1. Simple Diffusion : small non polar. High to low
concentration.
2. Facilitated Diffusion : Glucose and ions. Across
cell membrane through channels and proteins.
3. Osmosis : across semi permeable membrane
along concentration gradient.
Active Transport

1. Primary active transport : sodium/potassium
pump.

2. Secondary active transport (AKA Co-transport).
Two types :
Symport: eg. sodium glucose transporter
Antiport: eg. sodium calcium exchanger, sodium
hydrogen exchanger.
Cytoskeleton pic here
Cytoplasm
- is a cell component present inside the
cell membrane except nucleus.
- The jelly-like fluid portion of the
cytoplasm is called cytosol
- Cytoplasm = cytosol + organelles
Endoplasmic reticulum
Network of tubular structures called as
cisternae and flat vesicular structures.

Cisternal space is connected to the
space between the two membrane
surfaces of nuclear membrane.
Rough ER (Granular)
- covered in ribosomes.
- synthesize proteins that are then
transported to be used inside or
outside the cell.
- Also send to golgi bodies

Smooth ER (Agranular)
- more tubular sacs, not covered by
ribosomes.
- It contains enzymes important for
synthesizing fats and lipid substances
Golgi Apparatus

Is composed of four or more stacked layers of thin,
flat, enclosed vesicles lying near one side of the
nucleus.

is prominent in secretory cells. Examples :

Pancreatic acinar cells, salivary glands,

plasma cells – antibodies, enodcine glands :
thyroid, goblet cells – mucus.
 functions in association with the
endoplasmic reticulum. - endoplasmic
reticulum vesicles (transport vesicles)
continually pinch off from the endoplasmic
reticulum and then fuses with the Golgi
apparatus.
Used to store, pack and distribute proteins
and lipids made in the ER to form lysosomes,
secretory vesicles, and other cytoplasmic
components
Ribosomes

Tiny granules composed of rRNA and proteins.
synthesize new protein molecules in the cell.

80 S in eukaryotes

70S in prokaryotes

S = Svedberg unit : sedimentation rate : size
and density.
Lysosomes
are vesicular organelles that form by
breaking off from the Golgi apparatus.
Contains hydrolase (digestive) enzymes.

Function:
provides an intracellular digestive
system that allows the cell to digest the
following :
 damaged cellular structures

food particles that have been ingested by
the cell

(protein is hydrolyzed to form amino acids,
glycogen is hydrolyzed to form glucose, and
lipids are hydrolyzed to form fatty acids and
glycerol )
Peroxisomes
- are physically similar to lysosomes, but
they are different in two important
ways.

1st: formed by self-replication (or
perhaps by budding off from the SER)
rather than from the Golgi apparatus.
2nd: contain oxidases rather than
hydrolases
Secretory Vesicles
(secretory granules )
- Are storage vesicle.
- formed by the endoplasmic reticulum– Golgi
apparatus system which are then released from
the Golgi apparatus into the cytoplasm.

- store protein proenzymes. (enzymes that are
not yet activated).
Mitochondria

- The “powerhouse“
- of the cell.

- sausage-shaped
structures in the
cytoplasm
Function:
- involves in cellular respiration through which
chemical energy is made - adenosine
triphosphate (ATP).

- Example:
Cardiac muscle has more than adipocytes
Cellular respiration
Multistep process that cells use to
convert glucose and oxygen to ATP,
carbondioxide and water.

Glycolysis : Happens in cytoplasm. Glucose
to pyruvate. Anaerobic process. End product:
2 molecules of ATP and 2 molecules of NADH.
Citric Acid Cycle
Citric acid cycte (Kreb’s cycle) :

Takes place in Mitochondrial matrix ,
pyruvate is further broken down releasing
electrons transferred to NADH and FADH2.
These are High energy electron carriers.
 Electron Transport Chain : inner
mitochondrial membrane , series protein
complexes transfer electrons from NADH and
FADH2 to oxygen. (ETC is embedded in the cell membrane
for prokaryotes)

Chemiosmosis and ATP synthesis : proton
enters into the mitochondrial matrix through
ATP synthase. ADP and Inorganic phosphate
 Mitochondria are self-replicative

 Mitochondrial DNA is inherited
exclusively from the mother

 Mitochondrial deficiency, Mitochondrial
disease
Cytoskeleton
Micro filaments (actin) : cell shape and cell
movement
Intermediate Filaments (keratins, vimentin) :
maintain structure
Microtublues (tubulin) : intracellular transport
and mitotic spindle in cell division.

synthesized by ribosomes.
originate as precursor proteins  then
polymerize in the cytoplasm.
Network of protein fibers :

Structural support
Maintain cell shape
Various cellular movement.

Dynamic structure and participates in :

Cell division, intracellular transport and cell
signaling
Nucleus
is the “control center” of the cell and sends
messages to the cell to grow and mature,
replicate, or die.

Every cell in body has a nucleus ( except
mature erythrocytes).
 contains chromosomes: body’s genetic
material in the form of large double chains
of molecules of deoxyribonucleic acid (DNA)

Chromosomes = clusters of DNA molecules
Functional subunits of chromosomes are
called genes.

The genes reproduce to create two identical
sets of genes mitosis forms two daughter
cells.
Functions
Genetic material storage : contains DNA

Regulate gene expression and cellular
response to stress, signaling pathway
and external stimuli

Cell division and DNA replication

Nuclear transport of mRNA, ribosomal
Nuclear Membrane (Nuclear
envelope)
is a two separate bilayer
membranes.

The outer membrane is continuous
with the endoplasmic reticulum

The nuclear membrane is penetrated
by several thousand nuclear pores.
Nucleolus

Nucleolus: Synthesize and assemble
rRNA in to ribosomal sub-units.

enlarges when the cell is actively
synthesizing proteins.

Formation of the nucleoli begins in
the nucleus.
 First, specific DNA genes in the
chromosomes cause RNA to be
synthesized.

Synthesized RNA is stored in the
nucleoli, but most of it is transported
outward through the nuclear pores
into the cytoplasm.

Then plays role in forming cytoplasmic
Coming up next….