Cell Surface of the Extracellular Matrix PDF

Summary

This document provides a detailed overview of the cell surface and extracellular matrix, covering topics such as membrane structure, transport mechanisms, and the role of molecules like proteins and receptors. It describes the various processes, including passive transport, active transport, and bulk transport, occurring across the cell membrane.

Full Transcript

Cell Surface of the membrane with the help of
transport protein.
Extracellular Matrix
Cell Membrane
Two types of membrane transport
- Surrounds the cytoplasm of proteins involved:
living cells, physically
separating the intracellular A. Channel proteins- contain tunnels/
components from the openings that serve as passageways
extracellular environment. of
- The cell membrane, also
known as the plasma molecules.
membrane, is a thin, flexible B. Carrier proteins- undergo
barrier that surrounds and temporary binding to molecule it
protects the contents of a carries resulting in conformational
cell. change that moves the molecule
Cell Transport Concept Map through the membrane.
Active Process
- It is the movement of molecules
from low concentration to high
concentration with the use of
energy in the form of adenosine
triphosphate (ATP).

Passive Process
- Molecules, Ions, and other Bulk Transport
small substances can move - The movement of large amount
through the plasma membrane of materials in and out of the
using various non-energy
cell.
expending processes.
- Bulk transport acts as a
Types: transporter of materials across
1. Diffusion - Movement from high the membrane. It provides help
concentration to low concentration. in balancing the ions and
2. Osmosis - Movement of water molecules in and out of the cell.
through a semipermeable
membrane.
3. Facilitated diffusion - Transport
of various substances through the
There are two types: EXOCYTOSIS
1. Endocytosis - Forces material out of the cell in bulk
by invagination and formation of a
2. Exocytosis
vesicle.
ENDOCYTOSIS
- the process in which cells
absorb molecules by engulfing.
3 Types of Endocytosis
Phagocytocis
(cell eating) process by which cells
take in large particles by infoldings the
cell membrane to form endocytotic
vesicle.
Pinocytosis
CELL ADHESION
(cell drinking) process of taking in
fluids into the cell by invagination of A process where binding with other
cell membrane. Any solute or small cells or with the extracellular matrix
particles in the fluid will move into the (ECM) occurs.
cell.
Receptor-mediated endocytosis Cell adhesion molecules (CAMS)
(cell drinking) compared to pinocytosis, It is the subset of cell adhesion
is very specific. The plasma membrane proteins located on the cell
becomes indented and forms a pit. The surface involved in binding with
pit lined with the receptor proteins other cells or with the
picks specific molecules from its extracellular matrix.
surroundings. The pit will close and
pinch off to form a vesicle which will It helps cells stick to each other
carry the molecules inside the and to their surroundings.
cytoplasm. It plays an integral role in
creating force and movement
and consequently ensure that
organs are able to execute their
functions.
Important in affecting cellular
mechanisms of growth, contact,
inhibition, and apoptosis.
 Ligand – a chemical signal produced
by an organism or received from the
environment that is used to control
their bodily fucntions.
Receptors – are proteins that is
specialized and is selective in the
molecules they attach to.

It composed of three conserved
domains: VACUOLE FORMATION
1.An intracellular domain that interacts Vacuoles - are fluid-filled, enclosed
with the cytoskeleton structures that are separated from the
2. A transmembrane domain cytoplasm by a single membrane.

3. An extracellular domain FUNCTIONS OF PLANT VACUOLE:

TYPES OF BONDING: Turgor Pressure Control

1. Homophilic binding - CAMs bind to Growth of the central vacuole
the same CAMs. aids in cell elongation

2. Heterophilic binding - CAMs bind to Storage vacuoles store
different CAMs. important minerals, water,
nutrients, ions, waste -
3. Extracellular Ligand binding - occurs products, small molecules,
between cells and substrate, where a enzymes, and plant pigments.
mutual extracellular ligand binds two
different CAMs. Molecule degradation

SIGNAL TRANSDUCTION Detoxification

the process of transferring a signal Protection
throughout an organism, especially Seed Germination
across or through a cell. It relies on
proteins known as receptors, which
wait for a chemical, physical, or AUTOLYSIS - a programmed cell
electrical signal. death in plants naturally occurring
process where the plant’s own
enzymes destroy it. The vacuole
ruptures releasing its contents in
the cytoplasm. The digestive
enzyme released from the vacuole
degrades the entire cell.
Extracellular Matrix
Directly translates to “outside of
the cell”.
 Also called “cellular soup” There are four main fibrous proteins
that make up the ECM;
Is a fluid matrix composed of
substances and structures that 1. COLLAGEN
play roles such as maintenance
of cell structure, cell adhesion, Main structural component of the
migration, division, ECM, as well asmost multicellular
differentiation, and apoptosis. animals
COMPONENTS OF THE Most abundant fibrous protein
EXTRACELLULAR MATRIX:
Mostly made up of water, Made from fibroblasts
fibrous proteins, and
Makes up roughly ⅓ of total protein
proteoglycans.
mass in animals.
Made up of relatively sturdy
fibrous proteins: collagens, Stretch resistance and tensile
elastin, and laminins. strength (i.e. scarformation during
wound healing)
The sturdiness of these proteins
helps the ECM maintain its 2. ELASTIN
environment and resist force,
allowing it to withstand Fiber that lends tissues ability to
environmental pressures without recoil and stretch without breaking
collapsing.
Stretch and resilience

3. FIBRONECTIN

Regulates division and specialization
in many tissue types.

Secreted by fibroblast cells in water-
soluble form, but quickly changes once
assembles in a undissolvable mesh

FUNCTIONS OF ECM: Cell migration and positioning within
the ECM, and cell division and
1. Filler that lies between cells in a specialization in various tissues.
tissue
4. LAMININ
2. Water retention and
homeostatic balance Good at assembling itself into sheet-
like protein networks that acts as a
3. Provide major support for each
glue that connects dissimilar tissue
organ and tissue. types
ECM is composed of two main classes
of macromolecules ; Present at the junctions where
1. Proteoglycans connective tissue meet muscle, nerve,
2. Fibrous protein or epithelial lining tissue.
PROTEOGLYCAN TYPES OF CELL SIGNALING:

a macromolecule that has a core Juxtacrine signaling - (also known
protein with one or more as direct cell signaling) is the process
glycosaminoglycan chains. by which cells that are in direct contact
with one another communicate with
Proteoglycans are a type of each other.
glycoproteins present in the body, Paracrine signaling – occurs
especially in connective tissues, bone between cells which are close
and cartilage, and cell surfaces. together, sometime directly, sometimes
via extracellular fluid.
GLYCOSAMINOGLYCAN (GAGS) Endocrine signaling - involves
signaling over large distances, often
Chains of sugar that varies where the signaling molecule is
transported in the circulatory system.
Highly negatively charged molecule Auto signaling - cell stimulates a
produced by animal cells response within itself by releasing
signals for its own receptor.
EXTRACELLULAR FLUID - is known
as interstitial fluid, and surrounds most HOW CELLS RESPOND TO
of the cells in the body. SIGNALS?

Blood plasma Once a receptor protein receives a
signal, it undergoes a conformational
- Extracellular fluid that travels in the change, which in turn launches a
circulatory system and is the liquid series of biochemical reactions within
component of blood. the cell.

Interstitial fluid These intracellular signaling
pathways, also called signal
- Allows cells to carry out processes transduction cascades, typically
using the nutrients and oxygen amplify the message, producing
provided, and to carry wastes back to multiple intracellular signals for every
the blood. one receptor that is bound.

Transcellular Fluid Activation of receptors can trigger the
synthesis of small molecules called
- It is the final fluid which meant to second messengers, which initiate and
provide structural support Can be coordinate intracellular signaling
found in the eye, joint, and pathways.
cerebrospinal fluid.

CELL SIGNALING - is a general term
referring to the many and varied
processes by which communications
controlling cell-level activities are
generated, maintained, used, and
terminated.
RECEPTORS FOR CELL SIGNALS They are;

A cell surface receptor exists Receptor tyrosine kinases
intrinsically embedded in the plasma
membrane. Tyrosine kinase associated receptors

It has two domains of significance - Receptor-like tyrosine phosphatases
the signal molecule binding domain,
which is exposed to the exterior of the Receptor serine/ threonine kinases
cell and the intra-cellular domain in
contact with the cytoplasm. Receptor Guanylyl cyclase’s

CELL SURFACE RECEPTORS 3 Histidine kinase associated receptors
MAIN CLASSES:

1. LIGAND-GATED ION CHANNEL
RECEPTORS - also known as
ionotropic receptors, are responsible
for the rapid transmission of signals
across synapses in the nervous
system by allowing a flow of ions
across the plasma membrane, which
changes the membrane potential,
causing an electrical current.

3. G-PROTEIN-COUPLED
RECEPTORS - are the largest of all
the cell surface receptors. Due to the
large variety of cellular processes that
GPCR's are involved in, they are
usually an attractive target for the
development of drugs to treat variety
of disorders.

2. ENZYME-COUPLED RECEPTORS
- Are transmembrane proteins which
as of 2009, only six types were known.
TYPES OF RECEPTORS: 3. ENZYME-LINKED
RECEPTORS - are cell-surface
▪INTERNAL RECEPTORS, also receptors with intracellular
known as intracellular or cytoplasmic domains that are associated
receptors, are found in the cytoplasm with an enzyme.
of the cell and respond to hydrophobic
ligand molecules that are able to travel AGONIST VS ANTAGONIST
across the plasma membrane.
▪ An agonist is a ligand that binds
▪ CELL-SURFACE RECEPTORS, also to a receptor and produces a
known as transmembrane receptors, biological effect (direct acting) or a
are cell surface, membraneanchored, compound that indirectly produces
or integral proteins that bind to the same effect of a
external ligand molecules. This type of neurotransmitter (indirect acting).
receptor spans the plasma membrane
and performs signal transduction, ▪ An antagonist is a ligand that
converting an extracellular signal into binds to a receptor but does not
an intracellular signal. produce biological effect (direct
acting) or a compound that
3 MAIN COMPONENTS OF CELL- indirectly inhibits the effect of a
SURFACE RECEPTORS: neurotransmitter (indirect acting).
These compounds usually, block or
1. External ligand-binding domain inhibit the actions of a
(extracellular domain) neurotransmitter.

2. A hydrophobic membrane-spanning NOTCH SIGNALING
region
▪ The Notch signaling pathway is a
3. Intracellular domain inside the cell fundamental signaling system used by
neighboring cells to communicate with
3 GENERAL CATEGORIES OF CELL each other in order to assume their
SURFACE RECEPTORS proper developmental role. Notch
proteins are cell surface
1. ION CHANNEL LINKED transmembrane spanning receptors
RECEPTORS - bind a ligand which mediate critically important
and open a channel through the cellular functions through direct cell-
membrane that allows specific cell contact.
ions to through. To form a of
cellsurface receptor has an ▪ The Notch pathway regulates cell
extensive membrane-spanning proliferation, cell fate, differentiation,
region. and cell death in all metazoans.
2. G-PROTEIN-LINKED
RECEPTORS - bind a ligand TYPES OF CELLS SIGNALING
and activate a membrane 1. DIRECT CONTACT - When cells
protein called a G-protein. The are very close to one another,
activated G-protein then some of the molecules on the cells'
interacts with either an ion plasma membranes may bind
channel an enzyme in the together in specific ways.
membrane. 2. PARACRINE SIGNALING - Like
direct contact, paracrine signaling
 plays an important role in early b.) Enzymatic receptors - single-
development, coordinating the pass transmembrane proteins,
activities of clusters of neighboring with the part binding the signal
cells. molecule outside the cell and
3. ENDOCRINE SIGNALING - These the enzymatic part exposed to
longer-lived signal molecules, the cell's interior.
which may affect cells very distant c.) G-Protein Linked Receptors -
from the releasing cell, are called indirectly influence enzymes or
hormones, and this type of ion channels in the cell
intercellular communication is membrane with the help of a
known as endocrine signaling. protein called a G protein.
4. SYNAPTIC SIGNALING - The
narrow gap between the two cells C. INTRACELLULAR ADHESION
is called a chemical synapse. JUNCTION
While paracrine signals move Connections between cells within
through the fluid between cells, tissues.
neurotransmitters cross the are not just casual touches but are
synapse and persist only briefly long-lasting and essential for
maintaining the structure and
A. RECEPTORS THAT ACT AS functions of tissues in a
GENE REGULATORS multicellular organism.
CORTISOL - is a steroid hormone 3 CATEGORIES
produced by the adrenal glands in 1. TIGHT JUNCTIONS - connect the
response to stress and various plasma membranes of adjacent
physiological signals. cells in a sheet, preventing small
cortisol is released into the blood molecules from leaking between
stream; it circulates throughout the the cells and through the sheet
body. 2. ANCHORING JUNCTIONS -
Inside target cells, cortisol binds to mechanically attach the
specific intracellular receptors cytoskeleton of a cell to the
This binding activates the cytoskeletons of other cells or to
glucocorticoid receptor, and the the extracellular matrix.
hormone receptor complex then 3. COMMUNICATIONG JUNCTIONS
enters the cell nucleus - establish direct physical
In the nucleus, the cortisol- connections that link the cytoplasm
activated receptor binds to specific of two cells together, permitting
DNA sequences, called small molecules or ions to pass
glucocorticoid response elements from one to the other.
(GREs), to regulate the
transcription of genes involved in TYPES OF ANCHORING JUNCTION
various cellular processes, Gap Junctions - specialized structures
including metabolism and immune found in animal cells that serve as
response communicating junctions.

B. CELL SURFACE RECEPTORS Connexons: Each connexon is made up
a.) Chemically gated channel - of six identical transmembrane proteins.
When cells are very close to These proteins are arranged in a circular
one another, some of the pattern, creating a channel through the
molecules on the cells' plasma cell's plasma membrane
membranes may bind together
in specific ways.
Channel Formation: Connexons create
channels that protrude several
nanometers from the cell's surface.

Aligning Connexons: A functional gap
junction is formed when the connexons of
two neighboring cells align perfectly,
creating an open channel that spans the
plasma membranes of both cells.

Passage of Small Substances: They
permit the passage of small substances
like simple sugars and amino acids, which
are important for cell communication and
coordination

Size Selectivity: This selectivity is
essential for maintaining cellular integrity
and preventing the movement of
potentially harmful substances between
cells

Connexon Dynamics: Gap junction
channels are dynamic structures that can
open or close in response to various
factors, including the presence of calcium
ions (Ca²⁺) and hydrogen ions (H⁺). This
ability to open and close is known as
"gating."

Protective Function: Gap junctions serve
a protective function as well. When a cell
is damaged, its plasma membrane may
become leaky, allowing ions in high
concentrations outside the cell, like
calcium ions (Ca²⁺), to flow into the
damaged cell.
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