Medical Biology Lecture 1 2024 PDF

Summary

This document is lecture notes on medical biology, specifically focusing on cells, prokaryotic cells, eukaryotic cells, and cell membrane. It covers the structure, function, and components of these elements.

Full Transcript

Medical Biology
Lec 1
Dr. Khalida Ibrahim

Biology: is a science that studies living things & provides an understanding of life.
Cell biology: is a specialized branch of biology which deals with the study of structure and function of cell
organelles.
Cytology: is the science that deals with studies of the cell.

Cells: are the structural units of all living organisms.
Cells are divided to 2 types:
1. the prokaryotic cell: e.g., bacteria.
Characterized by:
small (1-5 µm) long.
Have cell wall outside the cell
membrane.
Lack a nuclear envelope separating the
genetic material (DNA) from other
cellular constituents.
Have no histones (specific basic
proteins) bound to their DNA.
Have no membranous organelles.
Prokaryotic cells divide by binary
fission.

2. the eukaryotic cells: e.g., amoeba.
Characterized by:
larger than prokaryotic cells.
Have distinct nucleus surrounded by
nuclear envelope.
Histones are associated with the
genetic material.
Numerous membrane-limited
organelles are found in the
cytoplasm.
Eukaryotic cells are divided by
mitosis & meiosis.

Eukaryotic cell components:
The eukaryotic cell is composed of 2
basic parts:
1. cytoplasm.
2. nucleus.

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 Cytoplasm

Is composed of matrix (cytosol) in which are embedded the organelles, cytoskeleton & deposits of
carbohydrates, lipids & pigments.
The cytoplasm of eukaryotic cells is divided into several distinct compartments by membranes that regulate
the intracellular traffic of ions and molecules.
The outermost component of the cell, separating the cytoplasm from its extracellular environment, is the
plasma membrane (plasmalemma). However, even if the plasma membrane is the external limit of the
cell, there is communication between the interior of the cell & extracellular macromolecules.

Plasma membrane
Structure & function

The structure & function of cell plasma membrane are critically dependent on:
a) universally, a plasma membrane protects a cell by acting as a barrier between its living contents and
surrounding environment.
b) It regulates what goes into & out of the cell & marks the cell as being unique to the organism.
c) In multicellular organisms, cell junctions requiring specialized features of the plasma membranes
connect cells together in specific ways and pass on information to neighboring cells so that the
activities of tissues and organs are coordinated.
d) Investigators noted that lipid- soluble molecules entered cells more rapidly than water- soluble
molecules.
e) This promoted them to suggest that lipids are a component of the plasma membrane.
f) The formation of biological membranes is based on the properties of lipids, and all cell membranes
share a common structural organization, bilayers of phospholipids with associated proteins.
g) The fluid- mosaic model of membrane structure is widely accepted at this time which proposed that
the membrane is a fluid phospholipid bilayer in which protein molecules are either partially or
wholly embedded and so the mosaic pattern of membrane is dependent on proteins which vary in
structure and function.

Membrane lipids:
Lipid constitutes 50% of the mass of most cell membranes, although this proportion varies depending on
the type of membrane.

1. phospholipids:
the fundamental building blocks of all cell membranes, which are amphipathic molecules, consisting of
two hydrophobic fatty acid chains
linked to a phosphate- containing
hydrophilic head group.
The hydrophilic (polar) heads of
the phospholipids molecules face
the intercellular and extracellular
fluids.
The hydrophobic (nonpolar) tails
face each other in the membrane
interior.
At body temperature, the
phospholipid bilayer of the plasma
membrane has the consistency of
olive oil. The entire phospholipid
molecule can move side away, all
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 this means that the cell is flexible.
One of the hydrophobic tails of the
phospholipid molecule contain a double
bound which create a bend in the tail
that is important for the general
structure of the membrane, because this
bend prevent the phospholipid from
being too close to each other in the
membrane interior and prevent the
phospholipid from packed together and
this property is very important to
maintain the membrane fluidity and the
membrane will behave as a viscous
fluid.
2. glycolipids:
have a structure like phospholipids except that the hydrophilic head is a variety of sugars joined
to form a straight or branching carbohydrate chain.
Glycolipids have a protective function as they are present in the outer part of membrane only.
3. cholesterol:
is a lipid that is found in animal plasma membranes. It is distributed equally in both the outer
and inner side of the membrane.
Cholesterol reduces the permeability of the membrane to the most biological molecules.

The Lipid Bilayer is a Two-dimensional Fluid: The aqueous environment inside and outside a cell
prevents membrane lipids from escaping from the bilayer, but nothing stops these molecules from moving
about and changing places with one another within the plane of the bilayer. The membrane therefore
behaves as a two-dimensional fluid, which is crucial for membrane function.

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Membrane proteins:
- proteins constituting 25- 75% of the mass of various membranes of the cells.
- Membrane proteins carry out the specific functions of the different membranes of the cell.
- These proteins are divided into 2 general classes, based on the nature of their association with the
membrane:
1. Integral membrane proteins are embedded directly within the lipid bilayer, many integral
membrane proteins called transmembrane proteins span the lipid bilayer with proteins
exposed on both sides
of the membrane.
Others referred to as
membrane associated
or lipid linked proteins.

2. peripheral membrane
proteins are not
inserted into the lipid
bilayer but are
associated with the
membrane indirectly,
generally called protein
attached by interactions
with integral membrane
proteins.

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Notes:
❖ The carbohydrate chains of glycolipids and glycoproteins serve as the fingerprints of the cell.
❖ The carbohydrate chains of the glycolipids & glycoproteins form a carbohydrate coat that envelops
the outer surface of the plasma membrane.
❖ On the inside, proteins serve as
links to the cytoskeletal filaments
and on the outside, some serve as
links to extracellular matrix.
❖ Many integral and peripheral
proteins that function as
components of large enzyme
complexes are in specialized
patches of membrane having
higher concentrations of
cholesterol. Within these regions
called lipid rafts membrane
fluidity is reduced, allowing the
associated proteins to remain in
closer proximity and interact
more efficiently.

Membrane protein variety:
These are some of functions performed by
proteins found in the plasma membrane:

1. channel protein allows a particular
molecule or ion to cross the plasma
membrane freely.

2. carrier protein selectively interacts
with a specific molecule or ion so that
it can cross the plasma membrane.

3. cell recognition protein: a type of
glycoproteins, which are involved in
marking of the cell and are different for
each person. e.g., major histo
compatibility complex.

4. receptor protein is shaped in such a way
that a specific molecule can bind to it.

5. enzymatic protein: catalyzes a specific
reaction.

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