Introduction to Medical Biology and Genetics PDF

Summary

These lecture notes provide an introduction to medical biology and genetics, focusing on fundamental concepts like cells, their components, and the classification of living organisms. The lectures cover universal cell features and differences between plant and animal cells, as well as topics on virus and diseases.

Full Transcript

Introduction to Medical
Biology and Genetics
Dr. Hilal Eren Gözel
Contact Info
[email protected]

1st Floor, Room #129
 Universal features of cells
There are more than 10 million species on Earth.
Although each species is different, they all reproduce yielding a progeny that
represent the copies of themselves (Heredity).
This hereditary information drives a complex system of chemical processes
that are crucial for the cell organization and its survival.
Although, the organisms can be unicellular or multicellular(like us), the
whole organism has been generated by cell divisions from a single cell.
The single cell, therefore, is the vehicle for all of the hereditary information
that defines each species.
 Universal features of cells
All cells store their hereditary information in the same chemical code
system: DNA (or RNA for viruses)
DNA or RNA codes (A, C, G, T or U) and their structures are universal in all
organisms.
The mechanisms that take part in reading the hereditary information
(Protein synthesis) or replication of it, occur very similarly in different
species.
All cells use proteins as catalysts (to increase rate of chemical reactions).
All cells use ATP as their free energy source.
All cells are enclosed in a plasma membrane across which nutrients and
waste materials must pass.
All cells have ribosomes.
 Differences of Cells:
Size
Shape
Chemical requirements

1 mm
Similar And Different!

The scientific study of how
living things are classified is
called taxonomy.
Similar And Different!

The binomial nomenclature
system combines two names
into one to give all species
unique scientific names.
 Divisions of life
Cells are the basic structural and functional units of every organism.

They have two distinct types: Prokaryotic and Eukaryotic.

Prokaryotic cells: Bacteria and Archaea
Eukaryotik cells: Protists, fungi, animals, and plants

Prion, Viroid and Virus!!!
 Divisions of life
Prokaryotic cells Eukaryotic cells
No nuclear membrane (Nucleoid) True nucleus, consisting of nuclear membrane

No Membrane-enclosed organelles Lysosomes, Golgi complex, endoplasmic reticulum,
mitochondria & chloroplasts
Cell Wall: Usually present; chemically complex (typical Cell Wall: When present, chemically simple
bacterial cell wall includes peptidoglycan)
Plasma membrane: No carbohydrates and generally lacks Plasma membrane: Sterols and carbohydrates that serve as
sterols receptors present
Cytoplasm: Simpler cytoskeleton Cytoplasm: Cytoskeleton; cytoplasmic streaming

Ribosomes smaller in size (70S) Larger size (80S)

Single circular DNA, lacks histones Linear DNA with histones

Cell division: Binary Division Cell division: Mitosis

Sexual reproduction: No meiosis; transfer of DNA fragments Meiosis
only (conjugation)
Divisions of life
present in (ribosome-studded) and smooth regions Nucleolus: nonmembranous
mal cells, structure involved in production
cluster of of ribosomes; a nucleus has NUCLEUS ANIMATION
Rough ER Smooth ER Nuclear envelope Rough www.mast
within an one or more nucleoli endoplasmic
NUCLEUS Nucleolus Smooth BioFlix® 3-D
he plasma reticulum endoplasmic Animal Cell
membrane Chromatin: material consisting Chromatin reticulum
of DNA and proteins; visible in
a dividing cell as individual
me: region condensed chromosomes
the cell’s
bules are
ontains a
centrioles Plasma membrane:
Ribosomes (small b
membrane
enclosing the cell
Central vacuole: promin
in older plant cells; func
breakdown of waste pr
N: Golgi apparatus macromolecules; enlarg
shape; major mechanism of pla
movement;
e made of Microfilament
es:
Intermediate
aments filaments

Microtubules
aments
Ribosomes (small brown
tubules dots): complexes that
make proteins; free in
cytosol or bound to
rough ER or nuclear
Mitochondrion
envelope
Peroxisome
li:
Chloroplast: photosynthe
at Plasma membrane organelle; converts energ
l’s sunlight to chemical ener
ea stored in sugar molecules
Cell wall: outer
Golgi apparatus: organelle layer that maintains
active
cell’s shape and protects cell from
in synthesis, modification, sorting,
mechanical damage; made of cellulose,
and secretion of cell products
other polysaccharides, and protein Plasmodesmata: cytoplasmic
In plant cell
channels through cell walls that Chloroplast
connect the cytoplasms of Central vacu
Wall of adjacent cell
Cell wall
ganelle adjacent cells
Plasmodesm
ecialized In animal cells but not plant cells:
ions; Lysosome: digestive
Lysosomes
Mitochondrion: organelle where organelle where
Differences Between Plant and Animal Cells
Differences Between Plant and Animal Cells
 Divisions of life
Prion (Proteinaceous infectious particle):
Prions are not considered living organisms because they are misfolded
protein molecules which may propagate by transmitting a misfolded protein
state.
If a prion enters a healthy organism, it induces existing, properly folded
proteins to convert into the misfolded prion form.
In this way, the prion
acts as a template to
guide the misfolding of
more proteins into prion
form.
 Divisions of life
Bovine spongiform encephalopathy (BSE):
It is commonly known as mad cow disease, is a neurodegenerative
disease of cattle.
Symptoms include abnormal behavior, trouble
walking, and weight loss.
Time from onset of symptoms to death is
generally weeks to months.
 Clinical Correlation
Creutzfeldt–Jakob disease (CJD):
It is a form of brain damage that
leads to a rapid decrease of
movement and mental function.
 Divisions of life - Virus
Virus:
A virus is a small infectious agent that replicates only inside the living cells of other
organisms.
They reproduce by creating multiple copies of themselves through self-assembly by using
host’s metabolism.
This infectious particle consisting of nucleic acid enclosed in a protein coat(capsid) and, for
some viruses, surrounded by a membranous envelope.
No organelles, only some genes.
Their genomes may consist of double-stranded DNA, single-stranded DNA, double-
stranded RNA, or single-stranded RNA, depending on the type of virus.
 Divisions of life
RNA
Capsomere
DNA
Membranous
envelope
RNA

Capsid Head DNA
Virus:
Capsomere
Tail
of capsid
sheath

Tail
fiber

Glycoprotein
Glycoproteins

18 × 250 nm 70–90 nm (diameter) 80–200 nm (diameter) 80 × 225 nm

20 nm 50 nm 50 nm 50 nm
(a) Tobacco mosaic virus has (b) Adenoviruses have an (c) Influenza viruses have an (d) Bacteriophage T4, like
a helical capsid with the icosahedral capsid with a outer envelope studded with other “T-even” phages, has a
overall shape of a rigid rod. glycoprotein spike at each glycoprotein spikes. The complex capsid consisting of
vertex. genome consists of eight an icosahedral head and a
different RNA molecules, each tail apparatus.
wrapped in a helical capsid.
 Clinical Correlation: Influenza viruses
Seasonal influenza (the flu) is an acute respiratory infection caused by influenza viruses.
It is common in all parts of the world. Most people recover without treatment!
Influenza spreads easily between people when they cough or sneeze.
Vaccination is the best way to prevent the disease.
 World Health Organization – Facts
There are around a billion cases of seasonal influenza annually, including 3–5 million cases of
severe illness.
It causes 290 000 to 650 000 respiratory deaths annually.
Ninety-nine percent of deaths in children under 5 years of age with influenza-related lower
respiratory tract infections are in developing countries.
There are four types of influenza viruses: A, B, C, and D.
Influenza A and B viruses cause seasonal epidemics of disease in people (known as flu season)
almost every winter.
Influenza A viruses are the only influenza viruses known to cause flu pandemics (i.e., global
epidemics of flu disease). A pandemic can occur when a new and different influenza A virus
emerges that infects people, has the ability to spread efficiently among people, and against
which people have little or no immunity.
Influenza C virus infections generally cause mild illness and are not thought to cause human
epidemics.
Influenza D viruses primarily affect cattle but are not known to infect people to cause illness.
Influenza A viruses
Influenza A viruses are
classified by subtypes based on
the properties and
combinations of their surface
proteins: [hemagglutinin (HA),
neuraminidase (NA)].
RNP: Ribonucleoprotein
HA binds to a virus
receptor on the host cell
and mediates virus
attachment to the cell
surface.
The hydrolytic enzyme
NA cleaves sialic acid
from viral receptors and
Influenza viruses

Swine flu
Influenza viruses
Mahal, A., Duan, M.,
Zinad, D. S., Mohapatra,
R. K., Obaidullah, A. J.,
Wei, X.,... & Zhu, Q.
(2021).
Recent progress in
chemical approaches for
the development of
novel neuraminidase
inhibitors.
RSC advances, 11(3),
1804-1840.
Levels of Organization
 Cell
Cells are the smallest units that still retain the characteristics of life, including
complex organization, metabolic activity and reproductive behavior.
1665, Robert Hooke observed tiny, empty compartments of a thinly sliced
piece of cork under microscope. He gave them the Latin name «cellulae»
(small rooms)
 Theories in Science
A scientific theory is an explanation of an aspect of the natural
world that can be repeatedly tested and verified in accordance
with the scientific method, using accepted protocols of
observation, measurement, and evaluation of results.
A theory is general enough to spin off many new, specific
hypotheses that can be tested.
 Cell theory
«Schleiden» 1838 - Plant tissues are made of cells.
«Schwann» 1839 - Animal tissues are made of cells.

All living organisms are composed of one or more cells.
The cell is the basic living unit of organization for all organisms.
All cells arise from preexisting cells.
References & Thank You
WHO – who.org

cdc.gov

Mahal, A., Duan, M., Zinad, D. S.,
Mohapatra, R. K., Obaidullah, A. J.,
Wei, X.,... & Zhu, Q. (2021). Recent
progress in chemical approaches for
the development of novel
neuraminidase inhibitors. RSC
advances, 11(3), 1804-1840.