Aerobic organisms continuously produce reactive free radicals through respiration, metabolism and phagocytosis. Approximately 1-2% of oxygen consumed is converted into superoxide radicals by the respiratory chain, one of the main sources of free radicals in cells. While oxygen is necessary for life, its partial reduction can produce reactive oxygen species (ROS) that damage living systems. The body has multiple antioxidant defenses to combat ROS, including superoxide dismutase, catalase, glutathione peroxidase and vitamin C, which help convert ROS into less reactive species and protect biomolecules from oxidative damage.
Seal of Good Local Governance (SGLG) 2024Final.pptx
ROS ANTIOXIDENTS
1.
2. • Aerobic organisms produce a number of reactive free radicals
continuously in cells during respiration, metabolism and
phagocytosis.
• Out of these, the most important source of free radicals being
the respiratory chain where ~ 1 to 2% oxygen is converted into
superoxide radicals (O2•−).
• Oxidation reactions ensure that molecular oxygen is
completely reduced to water
• Products of partial reduction of oxygen are highly reactive and
make havoc in the living systems
• Hence they are also called Reactive oxygen species (ROS)
Introduction
3. • The oxygen is needed for each living organism
for survival .but oxygen is toxic as well.
According to Salvemini oxygen is double edge
sword :it is vital for life but leads to formation
of toxic by products such as superoxide (o-
2)
anion. Oxygen is more prone to produce
superoxide radicals because molecular oxygen
contain two unpaired electrons with parallel
spins
Free radicals
4. • These unpaired electrons reside in separate
orbitals unless their spins are opposed.
Reduction of o2 by direct insertion of a pair of
electrons,e-,into its partially filled orbitals is
not possible without inversion of one
electronic spin and such inversion of spin is a
slow process
5. hence electrons are added molecular oxygen as
single electron molecule when oxygen
molecule takes up one electron,by univalent
reduction,it becomes ”superoxide” anion O-2.
O2 + e- O2
-
6. Members of ROS
group
• Superoxide anion radical (O2
-)
• Hydroperoxyl radical (HOO●)
• Hydrogen peroxide (H2O2)
• Hydroxyl radical (OH●)
• Lipid peroxide radical (ROO●)
• Singlet oxygen (1O2)
• Nitric oxide (NO●)
• Peroxy nitrite (ONOO--●)
7. Ionizing radiation (x-rays and UV) can lyse
water, leading to the formation of hydroxyl
radicals. Transition metal ions, including Cu+,
Co2+, Ni2+ and Fe2+ can react nonenzymically
with oxygen or hydrogen peroxide, again
leading to the formation of hydroxyl radicals.
There Are Multiple Sources of Oxygen
radicals in the Body
8.
9. Peroxidation (auto-oxidation) of lipid exposed to
oxygen is responsible not only for deterioration of
foods (rancidity), but also for damage to tissues in
vivo, where it may be a cause of cancer,
inflammatory diseases, atherosclerosis, and aging.
The deleterious effects ae considered to be caused
by free radicals (ROO*, RO*, OH*) produced
LIPID PEROXIDATION IS A
SOURCE OF FREE RADICALS
10. During peroxide formation from fatty acid
containing methylene-interrupted double
bonds, that is, those found in the naturally
occurring polyunsaturated fatty acids. Lipid
peroxidation is a chain reaction providing a
continuous supply of free radicals that initiate
future peroxidation and thus has potentially
devastating effects. The whole process can be
depicted as follows:
12. Initiation
phase
• During this phase, the primary event is the production of R●
(PUFA radical) or ROO● (lipid peroxide radical) by the
interaction of a PUFA with free radicals generated by other
means
R●
RH + OH● + H2O
ROOH ROO● + H+
•The R● and ROO●, in turn, are degraded to malondialdehyde
which is estimated as an indicator of fatty acid breakdown by
free radicals
13. Propagation
phase
• The R● rapidly reacts with molecular oxygen forming ROO●
which can attack another polyunsaturated lipid molecule
R●
+ O2
ROO● + RH
ROO●
ROOH + R●
•
• The net result of two reactions is conversion of R● to ROOH
• But there is simultaneous conversion of a R● to ROO●. This
would lead to continuous production of hydroperoxide with
consumption of equimolecular quantities of PUFA
• The progression of this chain of events will destroy PUFA
present in the membrane lipids
Accumulation of such lipid damages lead to the destruction of
fine architecture and integrity of the membranes
14. Termination
phase
• The reaction would proceed unchecked till a peroxyl
radical reacts with another peroxy radical to form inactive
products
ROO● + ROO● RO-OR + O2
R-R RO-ORR●
+ R●
ROO● + R●
15. Free radicals are highly reactive molecular
species with an unpaired electron; they persist
for only a very short time (of the order of 10-9
to 10-12 sec) before they collide with another
molecule and either abstract or donate an
electron in order to achieve stability.
Free Radical Reactions Are Self-
Perpetuating Chain Reactions
16. Damage produced by
ROS
• Free radicals are extremely reactive
• Their mean effective radius of action is only 30Å
• Their half life is only a few milliseconds
• When a free radical reacts with a normal compound, other free
radicals are generated
• Peroxidation of PUFA in plasma membrane leads to loss of
membrane functions
• Lipid peroxidation and consequent degradation products such as
malondialdehyde are seen in biological fluids
• Their estimation in serum is often employed to assess the
oxidative stress
17. Damage produced by
ROS
• Almost all biological macromolecules are damaged by the
free radicals
•Oxidation of sulfhydryl containing enzymes,
modification of amino acids, loss of function and
fragmentation of proteins are noticed
•Polysaccharides undergo degradation
•DNA is damaged by strand breaks
•The DNA damage may directly cause inhibition of
protein and enzyme synthesis and indirectly cause cell
death or mutation and carcinogenesis
18. Free radicals are formed in the body under
normal conditions. They cause damage to
nucleic acids, proteins, and lipids in cell
membranes and plasma lipoproteins. This can
cause cancer, atherosclerosis and coronary
artery disease, and autoimmune diseases.
BIOMEDICAL IMPORTANCE
19.
20.
21.
22.
23.
24.
25.
26. Superoxide
dismutase
• SOD is a non-heme protein
• The gene coding SOD is on chromosome 21
• Different iso-enzymes of SOD are described.
• The mitochondrial enzyme is manganese dependent;
cytoplasmic enzyme is copper-zinc dependent
• A defect in SOD gene is seen in some patients with
amylotrophic lateral sclerosis
28. Glutathione
reductase
• The oxidised glutathione is reduced by glutathione
reductase (GR) in presence of NADPH
• This NADPH is generated with the help of glucose-6-
phosphate dehydrogenase (G6PD) in HMP shunt pathway
• Therefore in G6PD deficiency the RBCs are liable to lysis,
especially when oxidising agents are administered (drug
induced hemolytic anemia)
29. Catalase
• When H2O2 is generated in
large quantities, the
enzyme catalase is also
used for its removal
30. Alpha-
tocopherol
• Alpha tocopherol (T-OH) would intercept the peroxyl free
radical and inactivate it before a PUFA can be attacked
T-OH + ROO● TO● + ROOH
• The phenolic hydrogen of the alpha tocopherol reacts with the
peroxyl radical, converting it to a hydroperoxide product
• The tocopherol radical thus formed is stable and will not
propagate the cycle any further
• The tocopherol radical can react with another peroxyl radical
getting converted to inactive products
TO● + ROO● inactive products
31. Alpha
tocopherol
• Vitamin E acts as the most effective naturally occurring chain
breaking antioxidant in tissues
• Only traces of tocopherol is required to protect considerable
amounts of polyunsaturated fat
• But in this process vitamin E is consumed
• Hence it has to be replenished to continue its activity
• This is achieved by daily dietary supply
32. Vitamin C
• Vitamin C, or ascorbic acid, is a water-soluble vitamin.
• This vitamin is a free radical scavenger, it is considered
to be one of the most important antioxidants in extra
cellular fluids.
• Its protective effects extend to cancer, coronary artery
disease, arthritis and aging.
33. • superoxide dismutase:this enzyme is present In
both cytosol and mitochondria.It can destroy
superoxide anions O-
2
• 2H+ + 2 O-
2
superoxide dismutase H2O2+O2
Scavengers of free radicals
34. • The enzyme is present in all major aerobic
tissues protecting aerobic organisms against
the potential toxic effects of superoxide anion
O-
2 .
35. • Catalase
• This enzyme having high Km value situated
close to aerobic dehydrogenases , like liver
peroxisomes, can destroy H2o2 formed in the
tissues to O2.
• H2o2+H2O2 CATALASE 2H2O+O2
36. • Glutathuone Peroxidase:
• When H2O2 level is less than optimum requird
forhydrogenperoxidatio by catalase,the selenium
containing enzyme Glutathione peroxidase can
destroyH2O2 with reduced gluthion(G-SH),having low
Km,present in cytosole and mitochondria
• H2O2+2G-SH G-S-S-G + 2H2O
• Reduced glutathione oxidized glutathione