Glycolysis: The Reactions
Summary
TLDRGlycolysis is a vital cellular pathway that converts glucose into ATP, the cell's energy currency. It involves 10 enzymatic reactions, starting with glucose and ending with two pyruvate molecules, along with ATP and NADH production. This process is crucial for energy generation, with potential for further ATP synthesis through aerobic respiration. Glycolysis can also be influenced by other cellular reactions, such as glycogen breakdown, altering its ATP yield and highlighting its importance in sustaining life.
Takeaways
- đż Glycolysis is a cellular process that converts glucose into ATP, providing energy for cells.
- đ The process involves 10 enzymatic reactions, starting with glucose and ending with pyruvate.
- ⥠Two ATP molecules are consumed in the initial steps, while four ATPs are produced later, for a net gain of two ATPs per glucose molecule.
- đ NADH is also produced during glycolysis, which can be used to generate more ATP in later cellular respiration stages.
- đ Glycolysis occurs in the cytosol and is a crucial pathway for energy production in cells.
- đŹ The process includes both energy-consuming and energy-producing steps, with a net production of energy.
- 𧏠Glycolysis is an essential pathway for the survival of biological organisms, as it contributes to the ATP pool required for various biochemical processes.
- đ The script describes glycolysis as a closed process, but in cells, it can be influenced by substrates from other reactions.
- â© When glycogen is broken down in animals, glucose 6-phosphate can enter glycolysis, skipping the first ATP-consuming step.
- đ Other sugars can also enter glycolysis at different points, affecting the net ATP yield of the pathway.
Q & A
What is the primary purpose of glycolysis in biological organisms?
-The primary purpose of glycolysis is to convert glucose into biochemical energy in the form of ATP, which is required for the survival of biological organisms.
How many ATP molecules are produced directly from one glucose molecule during glycolysis?
-Directly from one glucose molecule, glycolysis produces a net gain of 2 ATP molecules after accounting for the 2 ATPs consumed in the preparatory phase.
What are the two energy-consuming steps in glycolysis?
-The two energy-consuming steps in glycolysis are the addition of a phosphate to glucose to form glucose-6-phosphate and the phosphorylation of fructose-6-phosphate to form fructose-1,6-bisphosphate.
What is the role of NADH in glycolysis?
-NADH is produced during the oxidation of glyceraldehyde-3-phosphate and can be used later in cellular respiration to produce more ATP.
How many pyruvate molecules are formed from one glucose molecule during glycolysis?
-Two pyruvate molecules are formed from the breakdown of one glucose molecule during glycolysis.
What is the significance of the irreversible reactions in glycolysis?
-The irreversible reactions in glycolysis ensure that the process moves forward and glucose is not simply reformed from pyruvate, committing the cell to the energy extraction process.
Can other sugars besides glucose enter the glycolysis pathway?
-Yes, other sugars can enter the glycolysis pathway at different points, each affecting the net number of ATPs produced by glycolysis.
How does the breakdown of glycogen in animals relate to glycolysis?
-When animals break down glycogen, glucose 6-phosphate is produced, which can enter the glycolysis pathway at the second step, requiring one less ATP because the first ATP-consuming step is bypassed.
What is the role of ATP in the energy-producing phase of glycolysis?
-During the energy-producing phase of glycolysis, ATP is generated through substrate-level phosphorylation, where phosphate groups are transferred from high-energy molecules to ADP to form ATP.
What happens to the pyruvate molecules produced at the end of glycolysis?
-The pyruvate molecules produced at the end of glycolysis can be further metabolized in aerobic respiration to produce more energy for the cell.
Why is glycolysis considered a major contributor to the ATP pool in cells?
-Glycolysis is a major contributor to the ATP pool in cells because it is the first step in cellular respiration and provides ATP and NADH for subsequent energy-producing pathways.
Outlines
đż Glycolysis: Energy Conversion in Cells
Glycolysis is a vital cellular process that converts glucose into pyruvate, generating ATP and NADH. It begins in the cytosol with glucose being phosphorylated to glucose-6-phosphate, consuming one ATP. An isomerization step follows, leading to fructose-6-phosphate, which is then phosphorylated again to fructose-1,6-bisphosphate, consuming a second ATP. The pathway then splits fructose-1,6-bisphosphate into two three-carbon sugars, glyceraldehyde-3-phosphate and dihydroxyacetone phosphate, with the latter isomerizing to another glyceraldehyde-3-phosphate. The energy-producing phase starts with the oxidation of glyceraldehyde-3-phosphate to 1,3-bisphosphoglycerate, producing two NADH molecules. A kinase reaction forms ATP and 3-phosphoglycerate, followed by a mutase reaction to form 2-phosphoglycerate. A lyase reaction then generates phosphoenolpyruvate, and finally, another kinase reaction produces ATP and pyruvate. For each glucose molecule, two pyruvate, four ATP, and two NADH are formed. Glycolysis can also be influenced by other cellular reactions, such as glycogen breakdown, which can feed glucose 6-phosphate directly into the pathway, saving one ATP. The process is crucial for ATP production, which is essential for life.
Mindmap
Keywords
đĄGlycolysis
đĄATP
đĄNADH
đĄCytosol
đĄEnzymatic reactions
đĄIrreversible reactions
đĄGlucose-6-phosphate
đĄFructose-1,6-bisphosphate
đĄGlyceraldehyde-3-phosphate
đĄPhosphoenolpyruvate
đĄAerobic respiration
Highlights
Biological organisms require energy to survive.
Glycolysis is a pathway for converting sugars into biochemical energy.
Glycolysis occurs in the cytosol of the cell.
Glucose is converted into pyruvate through 10 enzymatic reactions.
Glycolysis produces ATP and other products like NADH.
ATP and NADH are used to produce more ATP for the cell.
Glycolysis begins with the oxidation of one glucose molecule into two pyruvate molecules.
A kinase reaction forms glucose-6-phosphate.
An isomerase reaction converts glucose-6-phosphate into fructose-6-phosphate.
A second kinase reaction forms fructose-1,6-bisphosphate.
A lyase reaction splits fructose-1,6-bisphosphate into two 3-carbon sugars.
Glyceraldehyde-3-phosphate is formed and two ATPs are consumed.
The next five steps of glycolysis are the energy-producing phase.
Glyceraldehyde-3-phosphates are oxidized to 1,3-bisphosphoglycerate.
This step produces two NADHs.
A kinase transfers a phosphate to form ATP and 3-phosphoglycerate.
A mutase reaction forms 2-phosphoglycerate.
A lyase reaction forms phosphoenolpyruvate.
The final step of glycolysis forms ATP and pyruvate.
Two pyruvate molecules, four ATPs, and two NADHs are formed per glucose.
Pyruvates and NADHs can be used in aerobic respiration for more energy.
Substrates from other reactions can enter glycolysis at different points.
Glycolysis is a major contributor to the ATP pool used in essential biochemical pathways.
Transcripts
Biological organisms require energy to survive.
Glycolysis is one of the pathways cells use to transform sugars like
glucose into biochemical energy in the form of ATP.
In the cytosol of the cell,
glycolysis converts glucose into pyruvate,
through a series of 10 enzymatic reactions.
This process produces ATP,
along with other products, such as NADH,
that can be used later to produce even more ATP for the cell.
Let's watch as these enzymes oxidize
one glucose molecule into two pyruvate molecules.
First, a kinase reaction adds a phosphate onto glucose
to form glucose-6-phosphate.
This is one of two energy consumption steps
and is an irreversible reaction.
Next, an isomerase reaction converts glucose-6-phosphate
into fructose-6-phosphate
by rearranging covalent bonds.
Another kinase removes a phosphate group from ATP
and gives it to fructose-6-phosphate
to form fructose-1,6-bisphosphate.
This is the second energy consumption step
and is an irreversible reaction.
In the fourth step of glycolysis,
a lyase reaction splits the 6-carbon
fructose-1,6-bisphosphate
into two 3-carbon sugars,
glyceraldehyde-3-phosphate
and dihydroxyacetone phosphate.
The dihydroxyacetone phosphate is rearranged by another isomerase
to form a second glyceraldehyde-3-phosphate.
At this point in glycolysis,
glucose has been metabolized into two glyceraldehyde-3-phosphates,
and two ATPs have been consumed.
The next five steps of glycolysis are the energy producing phase.
In step six,
both glyceraldehyde-3-phosphates are oxidized
to 1,3-bisphosphoglycerate
by a dehydrogenase.
This step produces one NADH
for each oxidized glyceraldehyde-3-phosphate
for a total of two NADHs.
These NADHs are later used to produce more ATP for the cell.
In step seven, a kinase transfers a phosphate
from 1,3-bisphosphoglycerate to ADP
to form ATP and 3-phosphoglycerate.
This step is reversible even though ATP is formed.
The next step involves a mutase reaction
that moves the phosphate on the
third carbon of 3-phosphoglycerate
to the second carbon position
to form 2-phosphoglycerate.
In step nine, a lyase reaction removes water
from 2-phosphoglycerate
to form phosphoenolpyruvate.
In the final step of glycolysis,
a kinase reaction removes the phosphate group
from phosphoenolpyruvate
and donates it to ADP
to form ATP and pyruvate.
Like reactions one and three,
this step is irreversible.
At this point, two pyruvate molecules,
four ATPs,
and two NADHs are formed
for each glucose
that was broken down in glycolysis.
The pyruvates and NADHs
could be used in aerobic respiration to produce more energy for the cell.
Here we depict glycolysis as a closed process.
But in cells, substrates produced by other reactions
can enter glycolysis at different points.
For example,
when an animal breaks down glycogen,
glucose 6-phosphate is produced
and can then enter the glycolysis pathway at the second step.
Importantly, this means one less ATP is required
for the pathway because the first ATP consuming step is skipped.
Other sugars can also enter the glycolysis
pathway at different points,
each having a different effect
on the net number of ATPs
that are produced by glycolysis.
These ATPs are important energy molecules
required for many biochemical pathways
and ultimately life itself.
Glycolysis is a major contributor
to the pool of ATP used in these pathways,
pathways that are essential
to the survival of biological organisms.
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