Week 2 Lecture 3 v2 PDF

Summary

This document is a lecture on cellular components, energy, and biological processes, specifically on how energy is generated, stored and released in biology and chemistry including biological energy, components of cells, and other related biological topics. It includes images and diagrams.

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Week 2 Lecture 3
Learning Objectives

By the end of this chapter you should be able to:
Identify cell compartments, membranes and structure.
Identify the functions of cell organelles.
Explain protein synthesis and the role of ribosomes.
Describe energy release and consumption in chemical reactions.
Discuss the role of glycolysis
Role of glucose transporters in regulating glucose metabolism
 Components of Cells

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Cytoplasmic Matrix
Cytoskeleton provides Cytoskeleton
the following: Components:
Structural support Microtubules
Framework for Intermediate
organelles filaments
Pathway for Microfilaments
intercellular
communication
 Mitochondrion

Mitochondrial membrane:
Outer membrane — relatively porous
Inner membrane
Selectively permeable
Site of electron transport chain
View inside a macrophage highlighting
the nucleus and mitochondria. This is a
confocal microscope image showing
the cell nucleus (blue) with areas of high
DNA concentration (light blue) and the
tubular mitochondria organized into
fused networks (green).
 HeLa Cells

(A) Deconvoluted STED images
showing changes in the mitochondrial
morphology under concomitant change
of the cristae density upon nutrition
starvation for 3 and 12 h (HBSS
containing Ca2+ and Mg2+).

Morphological changes of the mitochondrial inner
membrane captured by STED microscopy
Nucleus
Largest organelle:
Surrounded by nuclear envelope
Contains DNA:
Cell genome is the entire set of genetic information.
Nucleolus:
Site of RNA transcription
Ribosome assembly/synthesis-The process begins in the nucleus and
completed in the cytoplasm.
Nucleic Acids
DNA and RNA
Adenine, guanine, and cytosine in both:
Uracil in RNA only.
Thymine in DNA only.
Complimentary base pairing of double stranded DNA
RNA is single stranded—But can fold on itself to generate complex
secondary structures.
Hyperuricemia: Accumulation of high concentrations of uric acid causes
uric acid to clump together in sharp crystals. These crystals can settle in
your joints and cause gout, a painful form of arthritis. They can also build
up in your kidneys and form kidney stones.
RNA Comes in Diverse Shapes and plays roles
beyond translation
(A) C. elegans is a useful model
organism for understanding how
different cell types
develop. (B) Ambros and Ruvkun
studied the lin-4 and lin-14 mutants.
Ambros had shown that lin-4 appeared
to be a negative regulator of lin-
14. (C) Ambros discovered that the lin-
4 gene encoded a tiny RNA, microRNA,
that did not code for a protein. Ruvkun
cloned the lin-14 gene, and the two
scientists realized that the lin-4
microRNA sequence matched a
complementary sequence in the lin-14
mRNA.
(A) C. elegans is a useful model
organism for understanding how
different cell types
develop. (B) Ambros and Ruvkun
studied the lin-4 and lin-14 mutants.
Ambros had shown that lin-4 appeared
to be a negative regulator of lin-
14. (C) Ambros discovered that the lin-
4 gene encoded a tiny RNA, microRNA,
that did not code for a protein. Ruvkun
cloned the lin-14 gene, and the two
scientists realized that the lin-4
microRNA sequence matched a
complementary sequence in the lin-14
mRNA.
Ruvkun cloned let-7, a second gene encoding a microRNA. The gene is conserved in evolution, and it is now known
that microRNA regulation is universal among multicellular organisms.
Ribosomes link amino acids together to generate
proteins
 Steps of Protein Synthesis

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Biological Energy
ATP: major storage form of energy in cells
Paul Boyer (Boyer Hall): Received the Nobel Prize for his work on
understanding how ATP-Synthase generates ATP.
ATP synthase is a protein that catalyzes the formation of the energy storage
molecule ATP using ADP and inorganic phosphate (Pi). ATP synthase is a
molecular machine that rotates as protons pass through, joining ADP and
Pi.
Energy is needed for the following:
Physical exertion
Anabolism
Active transport
Transfer of genetic information
Energy Release and Consumption in Chemical
Reactions
Energy comes from macronutrients
Free energy (G)
Transferred from one form to another
Units of energy (cal, kcal, J, kJ):
1 cal=4.18 J, or 1 kcal=4.18 kJ
Potential energy released from bonds of nutrients
Exothermic and Endothermic Reactions (2 of 3)

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Exothermic and Endothermic Reactions (3 of 3)

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The Role of High-Energy Phosphate in Energy Storage

95% of the human body's total creatine
and phosphocreatine stores are found in skeletal muscle, while
the remainder is distributed in the blood, brain, testes, and
other tissues.

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The Role of High-Energy Phosphate in Energy Storage

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permitted in a license distributed with a certain product or service or otherwise on a password-protected website for classroom use.
 Glycolysis

Glykis: Sweet Lysis: Splitting
Glycolysis: Splits one molecule of glucose (6 carbon molecule) into
two molecules of pyruvate (3 carbon molecule).

Free energy generated during this process produces two molecules
of ATP and and 2 molecules of NADH.
NADH production consumes NAD+.
ADP is utilized to add a high energy phosphate to make ATP.
Fate of Glucose
 Glucose Metabolism

Complete Glucose Oxidation
Glucose + 6O2 = 6 CO2 + H2O dG=-2840 kJ/mol

Glycolysis
Glucose + 2NAD+ = 2Pyruvate + 2NADH + 2H+ dG=-146 kJ/mol
5.2% of total free energy that can be released by glucose is released during
glycolysis.
 Glycolysis

Glycolysis takes place in the cytosol
where enzymes involved in glucose
processing are found.

Glycolysis is the major ATP generating
pathway found in cells like cornea, lens,
erythrocytes, etc. These are cells that
have little access to oxygen and thus
largely reliant on non-oxidative
processes.
 Glycolysis

Essential for tissues that are
highly reliant on glucose, like the
brain.

Under anaerobic conditions,
glycolysis generates lactate and
ATP.
 Stage of 1 of Glycolysis: Energy Requiring Step

Stage 1 (Reactions 1-5): A preparatory stage in which glucose is phosphorylated,
converted to fructose which is again phosphorylated and cleaved into two
molecules of glyceraldehyde-3-phosphate. In this phase there is an investment of
2 molecules.
 Stage of 1 of Glycolysis: Energy Requiring Step

1. Once phosphorylated gets trapped in cell (no longer able to be transported by GLLUTs).
2. This change from phosphoglucose to phosphofructose allows the eventual split of the sugar into two
three-carbon molecules.
3. It is active when the concentration of ADP is high; it is less active when ADP levels are low and the
concentration of ATP is high.
 Stage of 2 of Glycolysis: Energy Generating Step
Stage 2 (Reactions 6-10): The 2 molecules of glyceraldehyde-3-phosphate are
converted to pyruvate with concomitant generation of four ATP molecules and
two molecules of NADH. Thus there is a net gain of two ATP molecules per
molecule of glucose during glycolysis.
 Stage of 2 of Glycolysis: Energy Generating Step
Step 6: The sixth step in glycolysis (Figure 3) oxidizes the sugar (glyceraldehyde-3-
phosphate), extracting high-energy electrons, which are picked up by the electron
carrier NAD+, producing NADH. The continuation of the reaction depends upon the
availability of the oxidized form of the electron carrier, NAD+. NAD+ can be
generated by pyruvate to lactate conversion.

If NAD+is not available, the second half of glycolysis slows down or stops. If oxygen
is available in the system, the NADH will be oxidized readily, though indirectly, and
the high-energy electrons from the hydrogen released in this process will be used
to produce ATP. In an environment without oxygen, an alternate pathway
(fermentation) can provide the oxidation of NADH to NAD+.
Anaerobic and Aerobic Glycolysis
Aerobic Glycolysis
Aerobic glycolysis is the glycolytic pathway which occurs
in the cytosol in the presence of oxygen. When compared
to anaerobic glycolysis, this pathway is much more
efficient and produces more ATP per glucose molecule. In
aerobic glycolysis, the end product, pyruvate is transferred
to mitochondria for the initiation of Citric acid cycle.
Therefore, the ultimate products of aerobic glycolysis are
34 ATP molecules, water, and carbon dioxide.
Anaerobic Glycolysis
Anaerobic glycolysis takes place in the cytoplasm when a
cell lacks oxygenated environment or lacks mitochondria.
In this case, NADH is oxidized to NAD+ in the cytosol by
converting pyruvate into lactate. Anaerobic glycolysis
produces (2 lactate + 2 ATP + 2 H2O + 2 H+) from one
glucose molecule. Unlike the aerobic glycolysis, anaerobic
glycolysis produces lactate, which reduces the pH and
inactivates the enzymes.
 Anaerobic and Aerobic Glycolysis
What is the difference between Aerobic and Anaerobic Glycolysis?
Aerobic glycolysis occurs in oxygen rich environments, whereas anaerobic glycolysis occurs in
oxygen lack environments.
Aerobic glycolysis is more efficient than anaerobic glycolysis; hence it produces a large amount
of ATP than anaerobic glycolysis.
Aerobic glycolysis occurs only in eukaryotes while anaerobic glycolysis occurs in both
prokaryotes and eukaryotes.
Unlike in anaerobic glycolysis, the end product of Aerobic glycolysis (pyruvate) is used to initiate
other pathways in mitochondria.
Anaerobic glycolysis produces 2ATPs per glucose molecule while aerobic glycolysis produces
36 to 38 ATPs per glucose molecule.
Ultimate end product of anaerobic glycolysis is lactate, which may be harmful to the cell itself,
whereas that of aerobic glycolysis is water and carbon dioxide, which are not harmful to cells.
Unlike in anaerobic glycolysis, NADH + H+ undergo oxidative phosphorylation in the presence
of oxygen in aerobic glycolysis.
Pyruvate is reduced to lactate during anaerobic glycolysis whereas, during aerobic glycolysis,
pyruvate is oxidation to acetyl coenzyme A (acetyl- CoA).
Membrane Transporters of Glucose
Membrane Transporters of Glucose
Membrane Transporters of Glucose
Membrane Transporters of Glucose
 Membrane Transporters of Glucose

GLUT1 was the first GLUT identified and is the most ubiquitously expressed glucose
transporter. It allows glucose to cross the blood–brain barrier and supplies glucose to the
developing central nervous system during embryogenesis.

GLUT1 is responsible for the supply of glucose to erythrocytes, endothelial cells of the
brain, and most fetal tissue.

Its importance is evident in GLUT1 deficiency syndrome in which patients experience
seizures beginning in early infancy due to insufficient glucose supply to the brain. Treatment
includes strict adherence to a ketogenic diet that raises levels of ketone bodies in the blood
to be used as fuel for the brain and other tissues.
 Membrane Transporters of Glucose

GLUT2 is a low-affinity, high-capacity transporter with predominant expression in
the β-cells of the pancreas, liver, small intestine, and kidney. GLUT2 is involved
in the transport of most monosaccharides from enterocytes into the portal blood
via the basolateral membrane. And when the concentration of glucose in the
intestinal lumen is high, it can transport glucose and fructose into the enterocyte
through the brush border.

The rate of transport is highly dependent upon the blood glucose concentration.
In the pancreas, GLUT2 appears to be the sensitive indicator of blood glucose
levels and is involved in the release of insulin from the β-cells.
 Membrane Transporters of Glucose

GLUT3 is a high-affinity glucose transporter with predominant expression in
tissues such as the brain and neurons that are highly dependent on glucose as
a fuel. It is also expressed in cells and tissues that have a high requirement for
glucose such as spermatozoa, the placenta, and preimplantation embryos.
Some data suggest that a possible dysregulation of GLUT3 might lead to
glucose deficits in the brain and thus to dyslexia in children.
 Membrane Transporters of Glucose

GLUT4 is the primary means by which insulin
regulates the cellular uptake of blood glucose in
muscle and adipose tissue. Other cells and tissues
such as the liver, kidneys, erythrocytes, and brain do
not express GLUT4 and therefore are not dependent
upon insulin for glucose uptake. One of the actions
of insulin is to cause the translocation of GLUT4
from intracellular storage vesicles to the plasma
membrane (discussed in the next section).
 Membrane Transporters of Glucose

GLUT5 is highly specific for fructose and does not recognize glucose. It is expressed
primarily in the small intestine and to a lesser degree in kidney, brain, skeletal
muscle, and adipose tissue. Its main function is to transport dietary fructose across
the brush border membrane of enterocytes.
Electron Microscopy of Insulin Secreting Cells
 Glycemic Index
Calculating Glycemic Index

The elevation in blood glucose level above
the baseline following consumption of a
high-glycemic index food or 50 g of glucose
in a reference food (glucose or white bread).
The glycemic index of the reference food is
by definition equal to 100.

The elevation of blood glucose levels above
the baseline following the intake of 50 g of
glucose in a low-glycemic index food.

The glycemic index is calculated by dividing
the area under the curve for the test food by
the area under the curve for the reference
food and multiplying the result by 100.
Some studies of GI have used glucose as
the reference food, while others used
white bread (Table 3.3). The reference
food is assigned a score of 100. In
practice, the GI is measured by
determining the elevation of blood glucose
for 2 hours following ingestion and plotting
the values against time. The area-under-
the-curve for the test food is divided by
the area-under-the-curve for the reference
food, then multiplied by 100. If glucose is
used as the reference food and assigned
a GI of 100, white bread has a GI of about
71. When white bread is used as the
reference, some foods will have a GI of
greater than 100.
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9982099/#:~:text=The%20glycemic%20index%20(GI)%20ranks,
same%20test%20portions%20(15).