Review Exam Final Cell Biology 2024 PDF

Summary

This document is a review for an exam on cell biology, including topics such as the plasma membrane, Golgi apparatus, and cytoskeleton, along with extracellular matrix, stem cells, and apoptosis. It contains diagrams, notes, and questions related to the course content.

Full Transcript

Review
Exam Final 2024
Plasma Membrane, Golgi, cytoskeleton, extracellular
matrix and Stem Cell/ Apoptosis.
Biological Membrane Class I

L.Spencer
1- Chemical Basics:

- Hydrophobic (non-polar molecules → aggregation)

Insoluble in water: Hydrophobic molecules.

- Hydrophobic Links: The force that produces the bond between non-polar
molecules. These molecules are not able to form bonds with water.

- Non-polar molecules can be bonded to each other, although in weak form
through Van der Waals type interactions

- Polar molecules: Dissolve in polar solvents as water and non-polar
solvents such as Hexane.
2- Phospholipids are amphipathic molecules:

Multiple non-covalent bonds are also essential for stabilizing the
structure of bio-membranes.

Main components: Phospholipids.

Phospholipids: One or more chains of fatty acids.
(Chain of hydrocarbons bound to a carboxyl group (-COOH).
Fatty acids: Saturated (without double bond)
Unsaturated (at least one double bond).

Please, Who can explain this figure?
This table present the most common lipids into the membrane
TO ISOLATE THE ´PROTEIN FROM BIOLOGICAL MEMBRANE
Form organized structure into the water micelle
Sheet of the bilayer
Liposome
Two faces of the a cellular membrane as the Cytosolic face and the exoplasmic face
Steroids: (cholesterol and its derivatives) → anphipatic
Basic structure is a hydrocarbon and 4 rings (abundant in eukaryotic membrane)

General structure of a steroid:

Cholesterol

Hydrophilic region Hydrophobic region
 Table of lipid composition: Each type of membrane has characteristics of lipids and proteins. The relative proportion of them
depends on the membrane.
Other components of membranes Glucoproteins.
Fig 3-32 (3) Glucolipids or Glycolipids.

Carbohydrates attached to sugars increase the hydrophilic character of
lipids and proteins and contribute to stabilize the conformations of many
membrane proteins.

Classification of proteins Surface or peripheral.

Integral or Intrinsic.

On the outside Function intervene in signals
Protein domains Intracellular F. (pores or channels)

Protein domains F. anchorage of the protein of the cytoskeleton in
the cytosolic face

F. Intracellular signaling.
Schematic diagram of the typical membrane proteins of the biological membrane

Plasma membrane defines the cell and separates the inside from the outside.
Types of membrane proteins

2 Protein classes Peripheral
of Membrane
Integrals
(Transmembrane proteins)

Transmembrane or integral proteins:
- Domains that cross the membrane (lipid bilayer)
- Domains that are : α helix
Multi stranded β
outside

inside What type the a.a are?
Classification of amino acids
Erythrocyte membrane
 Fig. 3-34 Structure of Bacterodopsin, contains 2 or more alpha-helices that
cross the membrane.

- Prot. Multiple strands of Porins They form barrels (channels) that
pass through the membrane.

Porins: transmembrane proteins

They provide channels for the passage of disaccharides and phosphates in
E.coli.

By X-Ray Porins are trimers

RECEPTORS in the plasma membrane are proteins that allow the cell to recognize
chemical signals present in its enviroment
What is this figure?
SDS Electrophoresis or SDS -PAGE
Three liquid chromatography to separate proteins based on their
mass, charge or affinity to a ligand
 Result

Western Blotting
We will made in the Lab ELISA TEST
Immunofluorescence to locate protein in the cell

Microscopia confocal
Experiment to demostrate the Evidents
FRAP
Trilaminar
Fusion celular You must review the experiments

Fracture membrane
Secound Part
Aparatus of Golgi
Camilo Golgi (1898) “∆” Owl brain tissue + salts of Os+2
↓

“Apparei reticulaire interne”

-In the middle of the XX century, with the Electronic
Microscope, the existence of the organelle was
established.
Polarization of Dictiosomes
Levels of organization:
-Cisternae (staks): diameter 0.5-
1μm (tubules diameter of 30-
50μm).
-Dictiosomes or bodies of Golgi:
5 to 8 cisternaes
- Golgi complex: Levels of
organization.
Structure of A. Golgi

Cis face
Golgi presents a polarization Trans face
Biochemical Activities of the Golgi
Glycosylation of proteins (eg. glycosylase and glycosyltransferase enzymes
in the Golgi membrane).

Medial cisternaes → Mannose residuos are added N-acetylglucosamine
(GlcNAc).

TransGolgi → increase residuos of galactose, Sialic Ac. and Fucose

Glycosylation of lipids.

Residue of mannose-6-phosphate directs the enzymes to the lysosome.

The conversion of proteins to the mature form, this is catalyzed by the
Peptidase Ezyme in trans-cisterna and secretory vesicles.
Glycosylation of proteins in ER and Golgi (cis; trans)
↓
Addition of
carbohydrates to
proteins

Nitrogen amídic from aspargine
Structural difference characteristic of N and O bonds of Oligosacharides. They differ in the
residues of sugars.
“O” → One to group Hidroxil of Ser o Thr, vía N-acetilglucosamine (GlcNAc)

“N” → Its bind to Nitrogen of Asp vía (GlcNAc).

Collagen: it binds an hidroxilisine vía galactose (Gal).

hidroxilisin

Acetil-glucosamina

Nitrogeno amídico
Summary of Antiport of the sugar nucleotides used in the synthesis of glycoproteins
that come from the cytosol.
N-acetylgalactosamine

Cisternae
of Golgi

N-galactosyl transferase
Types of blood groups
ABO Blood Types are determined by two Glycosyltransferases.

Ags of blood groups
AgA ➔ Ez N – acetilgalactosamine
Transferase.

AgB ➔ Ez- Galactose Transferases.

AgAB ➔ they have 2 Transferases.

Ag O ➔ They do’n have Transferase
Table of the immune response of blood groups

Laboratory practice: Determination of blood
group un slide and micro-place by
precipitation with antibodies (Agglutination).
Common precursor of N-oligosaccharide in ER proteins

Precursor + Dolicol ➔ Sec: Asn – x – Ser / Thr. (lipid)

Oligosaccharide
Protein
Transferase
 Aspargine

Enzimas

Oligosaccharide protein transferase
 Sialyltransferase
galactosyl transferase
Modifications of N-oligosaccharides are complemented in the Golgi
complex.

Location
Galactosyl Transferase➔ Trans – Golgi

Sialyltransferase ➔ Trans – Golgi and
TNG
Nextwork
Oligosaccharides can promote folding and stabilize proteins: Exp.
Antibiotic Tunicamycin.

Prot HA of influenza blocks Glicosylation Acumulation
+ ==X==> in Dolicol ➔ Prot. HA in RER,
Tunicamycin N - Oligosacharide bag folding

Exp. with mutant in
there is not Accumulation of Prot.
Replacement Asn by ============> HA of virus of influenza bad
glutamine of the prot. HA folding
Glicosylation
Some Proteins are secret in their final destination without being
glycosylated. E.g: Fibronectin by fibroblasts.

Fibronectin ➔ Non-glycosylated

Rapidly degraded by tissue
proteases of Extracellular
matrix
Conclusion: These results demonstrate that the oligosaccharide chains
confer stability to many extra-cellular glycoproteins
Peroxisome
 Manosa-6-phosphate (M6P) is target for
lysosomes
Phosphorylation of the mannose residue in the lysosomal enzyme.
GlcNAc Ez. Eliminates GlcNAc
Phosphodiesterase
Other Route of the M6P of Ez. Lysosomal (Trans-Golgi) M6P receptor.

The segregation of M6P-bearing lysosomal
enzymes from secreted and membrane
proteins occurs in the trans-Golgi network.
Here transmembrane mannose 6-phosphate
receptors bind the M6P residues on
lysosome-destined proteins very tightly and
specifically.

pH5,5

lysosomal storage disease
pH6
or Cell Disease I
Proteins that undergo proteolytic processes in
maturation (Occurs in secretory vesicles)
Cleavage

Inective precursors = Pro – Protein ➔ Active Protein

FURIN PROTEASE

Endoproteases

Carboxypeptidase
Some Proteins transporting the Golgi complex to the Apical or Basolateral membrane.
Fig. Plasma membrane in MDCK epithelial cells are polarized in 2 domains

Virus Influenza: Prot. HA Apical Membrane
Transcytosis
MDCK
Virus VSV: Prot. G Basolateral Membrane
Part of final Exam

Cytoskeleton
Microvillus: Villin joining F-actin
 As Profilin and Thymosin act in the assemblage of F. Actin

Recruits actin
◼ F. Actin Cutters Protein

P. Superfamily of GeIsolin: Requires ↑ [Ca+2] to Cut Actin´s
filaments
Microfilament Motor Proteins Myosin
 Coupling of ATP hydrolysis to Myosin shift on the actin filament

Steps:
1- Fixing ATP
2- Hydrolysis
3- Pi release
4- Release of ADP

Pivot movement
Model of Sliding Filaments Actin - Myosin in muscle contraction
Actin and myosin in non-muscle cells

Fluorescent antibodies reveal the localization of myosin I and
myosin II during cytokinesis.
Fluorescence micrograph of a Dictyostelium ameba
during cytokinesis reveals that myosin II (red) is concentrated in
the cleavage furrow, whereas myosin I (green) is localized at the
poles of the cell. The cell was stained with antibodies specific for
myosin I and myosin II, with each antibody preparation linked to
a different fluorescent dye. [Courtesy of Y. Fukui.]
Myosin VI is the
only one that
travels on F. From
actin to negative
end

Electron micrograph (a) of a section of the apical domain of polarised Cartoon illustrating the possible involvement of myosin VI (arrows indicate
human intestinal brush border cells (Caco-2 cells) after cytochalasin D direction of myosin VI movement) in sequential steps of endocytosis in
treatment. Depolymerisation of actin ¢laments clearly increases the polarised cells containing microvilli at their apical domain: (1) spatial
number of clathrin coated pits at the base of microvilli. Gold label organisation of the endocytic machinery at the base of microvilli; (2)
indicates molecules of ricin binding to the microvillar surface. b^d: movement of receptors down to the base of a microvillus for sequestering
Immuno EM localisation of myosin VI (5 nm gold) labelled with and coated pit formation; (3) invagination of the plasma membrane; (4)
arrowheads and clathrin (15 nm gold) in NRK cells. In b myosin VI is vesicle scission with myosin VI attached to the plasma membrane moving
associated with an early stage of clathrin coated pit formation, whereas in towards the minus end of actin ¢laments and thereby driving the filament to
c it can be seen in a deeply invaginated pit and in d myosin VI is constrict the neck; (5) transport of clathrin coated vesicles away from the
associated with a clathrin coated vesicle in the cytosol. plasma membrane into the cell.
Cytoskeleton II
Types of filaments :
2) F. Intermediate:
Fibers resembling strands.
Structural paper, are in
multicellular organisms.
D. 10nm (E.g.. Lamin)
Give strength and resistance (hair,
nails)
Fig. 16-16 Structure of the intermediate filaments ( Protein Lamin)
8 Tetramer and 32 Colloidal helixes
Keratin and cutaneous
diseases

The bunds of Keratin are
united by cross-links of
FILACRIN

Deletion mutations of the
terminal domains

Cause:
Epidermolysis bullosa
simple
Cytoskeleton II
3) Microtubules (Directs intra-
cellular transport, cilia and
flagella) Long, cylindrical and
hollow
Formed by tubulin protein
Ø 25nm
One end (-) → MTCO = Centrosome
(MTCO)

MT have polarity
Cytoskeleton I
Structure of a microtubule and its subunits

interchanged
Dynamic Instability
Dynamic Instability Catastrophe ( - )
Rescue (+)

Fig. 16-11 Dynamic Instability

Permanent = Flagellar Axonema
MT Form structures
Transient Polymerization
and
depolymerization

Acrosome spindle of mitosis
Schematic of Dynamic Instability

Cap of
Tiubulin-GTP

grows MT
 Cytoskeleton I

Polymerization of the
nucleated tubulin to a ring
complex
 Cytoskeleton I
Microtubules leave a centrosome(MTOC)
Centrosome → Located next to the nucleus

2 Centrioles in the shape of
"L" (right angle)
 Microtubules -Similar to myosin II
Kinesin -2 Heavy heads (globular)
2 types of motor prot. direction(+) -2 Light chains
(Anterograde movement) -1 Coiled tail

Dynein
Towards the negative
end of the MT(-)
(Retrograde Movement)

Fig. 16-55: Kinesin and related proteins.
There are at least 10 families of related proteins or KRPs. They are involved in the formation of
the achromatic spindle and separation of the chromosomes during cell division.

Dyneins:
-It moves towards the negative end of the MT.
-Involved in vesicular traffic and ciliary beat.
-2 or 3 heavy chains (motor domains).
-1 or more associated light chains.
Ej. cytoplasmic dynein 2 heads
ciliary dynein 3 heads
Kinesin has a movement directed towards the + end (anterograde)
Kinesin and Kinesin-related proteins
Another representation of the model of binding of a vesicle to the Microtubule
Structure of axonemes of cilia and flagella
Fig. 16-78: Dynein ciliary
Extreme arms of axonema dynein

Fig. 16- 79: Flexion of an axoneme. (Prot. Union = nexin)
The displacement of the microtubules causes flexion.

Nexin
Make a table of the differents filaments of Cytoskeleton

And

What is the difference between cilia and flagella?
Extravasion: Inward displacement of tissues
↓
It requires the successive formation and rupture of the intercellular contacts between
leukocytes and Endothelial cell
↓
Mediated by Selectin P

Fig. 22-4: Interaction between the cell adhesion molecule (CAM-Selectin) and
an active endothelial cell
Adhesion and Extracellular Matrix
Cell-Cell and Cell-Extracellular matrix interactions

Different types of cells in tissues are arranged in complex
patterns. ↓
The coordinated functioning of cells in tissues = Move,
metabolize, reproduce, etc.
The key to the Evolution of Multicellularity has been the ability
to establish contact and interaction with other cells.
CAM: Different integral membrane proteins called "Cell-
Adhesion Molecules"
Function: To facilitate the adhesion between itself and other
cells, or with others of the same type → giving firmness and
specificity
Fig. 22-1: General Scheme of the Molecules that bind the cells together and with.
ECM
Types of adhesion: - Homophilic
- Heterophilic

Classes of CAM (Adhesion Molecules)
Cadherins Homophilic
Igs Super Family
Selectin Heterophilic
Mucins
Integrins Cell-Matrix interaction
Intercellular adhesion:
Cadherin
Depends on Ca+2
Selectin
Integrins (C-ME) It does not depend on
Super Family Igs Ca+2
Fig. 6.2 CAM classes (Adhesion Molecules)
 Genetic defect of β 2 Integrin synthesis
Leukocyte adhesion deficiencies→ Bacterial infections

Connections containing cadherins connect cells to each other →
Desmosomes (clusters of adhesion molecules)

Fig. 22.5: Adhesion molecules at the junctions involved in intercellular
adhesion
 Fig 22-5:
Desmosomes: -Adhesion Plate
Cadherina E + Prot. - Prot. Trans-membrane → desmoglein
Adaptadora → desmocollin
Catenina + F. actina
- Prot. Plate : Placoglobin
-F. Intermediate: keratin +Desmoplaquin
GAP Unions → cilindric particles (prot. Conexin) → H2O channels→
Bind cytosols → Displaces small molecules and ions
, a.a, fosfonucleotides, cAMP(secund menssenger) + hormone
Metabolic Cooperation of Cells

Fig 22-7: Micrograph E. of the fine cut of the GAP junction → Allows the
passage of small molecules between cells
Fig. 22-8: GAP Unions Structure.
 GAP or Cleft Model
- Sub-units of conexin (prot 25.000-50.000 kDa)
↓
6 molec. (Cell)
Hexagonal Particle : 2 conexina molecules
6 molec. (Cell) → Semichannel
- 12 genes have been cloned → Family of Conexin
↓
Different peptides
↓
Heterodynamic Channels

Difference in the permeability of the channels

Adhesion between cells and the ECM
In the functions of the CAMs are the unions directly involve
ECM and the cytoskeleton
Tabla 6.6 Some vertebrate integrins and their ligands (relatively low
affinity)
↓
Modulates the adhesion to the MEC
 Platelets: they are small cellular fragments of the blood and
they act in the coagulation
E.g.: Cell-ECM por integrins

Platelet membrane (Integrinas αIIb β3)
↓
Formation of clot
↓
Binding integrins to collagen + Fibrinogen after activating
platelets

Patient with defect in the Integrin cytosolic domain
β subunit
↓
Hemorrhage
Collagen:
Fibrous Protein of ME and connective T.
Most abundant Individual Protein
There are at least 16 types(80% → collagen types I,II,III)
Molecules are grouped into thin fibers
Collgen triple helix : Abundant
glycine, proline and hydroxyproline
motif Gli-Pro-X
- Large protein (300 nm)
- Ø 1.5 nm
- 3 Coiled subunits
Table 6-1: Types of Collagen
Fig. 22-17: Assembly F. Collagen begins RE and is completed outside the cell. Steps of Collagen
Biosynthesis
Fig. 22-17: Collagen type IV. Basal lamin
 Component NO Collagen of Extracellular Matrix
ECM:
- Collagen (insoluble)
1) Prot. Multiadhesives:
- Function: Join Molecule tail to ME
- They bind Fibronectin receptors
2) Proteoglycans: Molecule Protein center
and multi-chains polysaccharide
3) Hyaluronano (Hyaluronic Ac.)
Function: Give ECM volume, diffusion of molecules
between cells and tissues

Prot. Laminin + Collagen IV Form the two-dimensional
reticulum of the basal lamina
Fig 22-19: Structure of laminin → Protein in the shape of a cross.
Heterodimer multiadhesive product. It is on all the basal lamina
Fig. 6-13: Model of the basal lamin

Entactin
Fibronectins: Dimer of 2 polypeptides attached at the
carboxyl termini by Disulfide bonds, c/u → 60-70 mm de
largo. Ø → 3nm

Fig 22-22: Structure of the fibronectin chain (6 adhesion
domains)
Proteoglycans: It consists of multiple glycosaminoglycans linked
by a central protein

Function: They act as anchors of cells. Fibronectins bind +
Collagen in ECM

Fig. 6-22: Proteoglycan aggregate
structure of a cartilage
What is Mechanotransduction?
Interaction between endothelial cells

Also, this molecule is called
as ………..
CELL BIRTH or Stem Cell,
LINEAGE,
AND DEATH
Prof. Lilian Spencer
The mode of reproduction also changed, with some cells becoming specialized as germ cells (e.g., eggs,
sperm), which give rise to new organisms, as distinct from all other body cells, called somatic cells.

- The mode of reproduction also changed, with some cells becoming specialized as germ cells (e.g., eggs,
sperm), which give rise to new organisms, as distinct from all other body cells, called somatic cells.

Cell lineages are controlled by intrinsic (internal) factors—cells acting according to their history and internal
regulators—as well as by extrinsic (external) factors such as cell-cell signals and environmental inputs
(FIGURE)

A cell lineage begins with stem cells, unspecialized cells that can potentially reproduce themselves and
generate more-specialized cells indefinitely.

What is a Stem Cell?
Stem cells are defined functionally as cells that have the capacity to self-renew as well as the ability to
generate differentiated cells.
A cell lineage ultimately culminates in formation of terminally differentiated cells such as skin cells, neurons,
or muscle cells. Terminal differentiation generally is irreversible, and the resulting highly specialized cells often
cannot divide; they survive, carry out their functions for varying lengths of time, and then die.

- Many cell lineages contain intermediate cells, referred to as precursor cells or progenitor cells¸ whose potential
to form different kinds of differentiated cells is more limited than that of the stem cells from which they arise.

- Typically we think of cell fates in terms of the differentiated cell types that are formed. A quite different cell fate,
programmed cell death, also is absolutely crucial in the formation and maintenance of many tissues
Stem Cells Give Rise to Stem Cells and to Differentiating Cells:

A pluripotent (or multipotent) stem cell has the capability of
generating a number of different cell types, but not all.

A pluripotent blood stem cell will form more of itself plus multiple
types of blood cells, but never a skin cell. In contrast, a unipotent
stem cell divides to form a copy of itself plus a cell that can form only
one cell type.
In contrast to apoptosis, cells that die in response to tissue damage exhibit very different morphological changes,
referred to as necrosis. Typically, cells that undergo this process swell and burst, releasing their intracellular contents,
which can damage surrounding cells and frequently cause inflammation.
Process of Apoptosis
What are the genes that regulate the apoptosis process?
Final Examen

Martes 26 de Noviembre
Hora: 8: 30 AM

Aula: aula A-17 del segundo piso del Senecyt (SE-PA2-A17)
Por confirmar