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Have you ever thought about what keeps you alive? Is it food? Is it water? Or is it the processes that occur in your body? Well, it's actually all of them! The water we drink and the food we eat are digested by the body and turned into sugars that we use for energy.
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Jetzt kostenlos anmeldenHave you ever thought about what keeps you alive? Is it food? Is it water? Or is it the processes that occur in your body? Well, it's actually all of them! The water we drink and the food we eat are digested by the body and turned into sugars that we use for energy.
The pathways our bodies take to digest what we consume can be thought of as metabolism. We must understand these processes because they operate in our bodies all the time, keep us functioning, and cycle nutrients throughout different organisms to keep our ecosystem balanced.
So, let's dive into metabolic pathways!
Let's start by looking at the definition of a metabolic pathway.
A metabolic pathway is a series of chemical reactions interconnected by intermediates in a living organism.
The intermediates are chemicals in between that are made from the starting reaction when we consider metabolism as a whole.
Metabolism can be thought of as all the chemical changes that occur within a living organism.
The word metabolism derives from the Greek word “metabolismos,” which means change. This change refers to all the chemical processes that occur inside the body.
Metabolic pathways generally consist of a sequence of reactions activated by enzymes where the product of the previous reaction becomes the starting point or reactant for the following reaction.
Enzymes are proteins that speed up or catalyze chemical reactions in the body.
Proteins are organic compounds that perform essential functions such as transporting materials, controlling physiological processes such as growth, speeding up chemical reactions, storing things, etc. They consist of smaller molecules called amino acids that can be linked together to form polypeptides.
Organic compounds are compounds that contain mainly carbon and can sustain life. Organic compounds are also commonly made of hydrogen, oxygen, or nitrogen.
Major metabolic pathways mostly consist of the synthesis of organic compounds that contribute to reproduction, cell growth, repair, energy uptake, etc.
There are three types of metabolic pathways that you need to be familiar with: anabolic, catabolic and amphibolic pathways.
Anabolic pathways are pathways that require energy to buildup or construct molecules, as shown in Figure 1. For example, the buildup of carbohydrates is an example of an anabolic pathway.
Catabolic pathways create energy through the breakdown of molecules, as shown in Figure 1. For instance, the breakdown of carbohydrates is an example of the catabolic pathway.
Amphibolic pathways are pathways that include both anabolic and catabolic processes.
One of the most important metabolic pathways can involve the breakdown or buildup of organic compounds called carbohydrates to synthesize energy for our bodies.
Carbohydrates are organic compounds consisting of hydrogen, carbon, and oxygen that store energy. They are the body's primary source of energy.
A way to remember that catabolic pathways involve the breakdown of molecules is to think that the c in catabolic stands for "cutting" molecules down. In contrast, anabolic would be the opposite of catabolic.
Another example of an anabolic pathway is making sugar from carbon dioxide or building polypeptides from amino acids. Breaking down amino acids into their intermediates, on the other hand, is an example of a catabolic pathway.
There are a ton of metabolic pathways, some of which are shown in the chart below (figure 2). So, let's do an overview of some of the most important metabolic pathways in humans:
Process name | Type of pathway | Description |
Glycogenesis | Anabolic | This process involves the formation of glycogen from glucose or sugar. |
Glycolysis | Catabolic | Glycolysis is the process of breaking down glucose. |
Gluconeogenesis | Anabolic | Gluconeogenesis is the formation of glucose from non-carbohydrates. This occurs when our body doesn't have enough glucose or carbohydrates. |
Fatty Acid oxidation | Catabolic | Process of breaking down fatty acids into the product to start the citric acid cycle. |
Citric Acid Cycle (Kreb's Cycle or Tricarboxylic Acid Cycle) | Amphibolic | Starts with the product from glycolysis and reduces it to NADH (nicotinamide adenine dinucleotide). |
Oxidative Phosphorylation (Electron Transport Chain) | Catabolic | Process of ATP is synthesized through the breakdown of electron carriers. |
Pentose Phosphate Pathway (PPP) | Amphibolic | Breaks down an intermediate of glycolysis to make important components for RNA and DNA. |
Urea Cycle | Catabolic | Eliminates toxic ammonia from the body by breaking it down into urea which is then excreted as urine. |
Essential definitions to understand the processes in the table above and for the next few sections are:
Glycogen is a polysaccharide used by animals, fungi, and bacteria to store energy. Glycogen is made up of many bonded glucose molecules. In contrast, glucose, a monosaccharide, is the simplest form of sugar from which carbohydrates can be constructed.
Polysaccharides are carbohydrates with multiple amino acids bonded together.
NADH or nicotinamide adenine dinucleotide is a coenzyme that acts as an energy carrier as it transfers electrons from one reaction to the next. NADPH does the same thing as NADH; it's just involved in photosynthesis instead.
\(\text {FADH}_2\) or flavin adenine dinucleotide is a coenzyme that acts as an energy carrier, just like NADH. We use flavin adenine dinucleotide sometimes instead of NADH because one step of the Citric Acid Cycle doesn't have enough energy to reduce NAD+.
A coenzyme or cofactor is a compound that's not a protein that helps an enzyme function.
Oxidation occurs when a reactant loses electrons during a chemical reaction. In comparison, reduction occurs when a reactant gains electrons during a chemical reaction.
Fatty Acids are the building blocks of lipids, the organic compounds that store energy and make up the cell membrane. Examples of lipids are oils and waxes.
DNA stands for deoxyribonucleic acid. It is a double-stranded molecule that carries around the genetic information of living organisms.
RNA stands for ribonucleic acid. It is a single-stranded molecule made from DNA that synthesizes proteins.
If the chart above didn't show how complex metabolism is, figure 2 certainly does! To the eye, it just looks like a mess of lines, but these lines represent the connections of all the interconnected processes' reactants, intermediates, and products. Our body really does a lot to keep us alive!
Are you overwhelmed by the big picture yet? Well, don't worry! Next, we'll look at some of the most important examples of metabolic pathways to better understand metabolism.
Let's take a look at two of the most vital processes that allow living organisms to gain energy and break it down for usage: photosynthesis and cellular respiration.
Photosynthesis is the process plants use to make energy.
Photosynthesis is an overall anabolic process because plants get energy from the sun to convert carbon dioxide (\(CO_2\)) into glucose (\(C_6H_{12}O_6\)) or sugar.
Plants use these sugars for their own needs, but we can consume the plants to gain their energy. The overall reaction for photosynthesis is:
$$ 6CO_2+ 6H_2O + \text{solar energy} \longrightarrow C_6H_{12}O_6 + 6O_2 $$
The steps to photosynthesis are:
1. Light-dependent reactions: Solar energy is converted to chemical energy in the form of ATP and NADPH.
Protein complexes and chlorophyll molecules in the photosystems together produce chemical energy.
Since chemical energy in the form of ATP and NADPH are being formed, this process is anabolic.
2. Light-independent reactions or The Calvin cycle: Uses chemical energy from the light-dependent reactions to form glucose.
Since glucose is formed from ATP and NADPH, this process is also anabolic.
Up next, we have cellular respiration.
Cellular respiration is the process we use to break down glucose for energy, making it an overall catabolic process.
The overall reaction for cellular respiration is:
\(C_6H_{12}O_6 + 6O_2 \longrightarrow 6CO_2+ 6H_2O + \text {chemical energy}\)
The steps to cellular respiration are as follows:
1. Glycolysis: Glycolysis is the process of breaking down glucose, making it a catabolic process.
Glycolysis begins with glucose and ends up broken down into pyruvate.
The conversion or oxidation of pyruvate from glycolysis to acetyl-COA, an essential cofactor.
This process is catabolic since it involves oxidizing pyruvate into acetyl-COA.
3. Citric Acid Cycle (TCA or Kreb's Cycle):
Starts with the product from pyruvate oxidation and reduces it to NADH (nicotinamide adenine dinucleotide).
This process is amphibolic or both anabolic and catabolic.
The catabolic part occurs when acetyl-COA is oxidized into carbon dioxide.
The anabolic part occurs when NADH and \(\text {FADH}_2\) are synthesized.
Oxidative Phosphorylation involves the breakdown of electron carriers NADH and \(\text {FADH}_2\) to make ATP.
The breakdown of the electron carriers makes it a catabolic process.
Take notice that the overall reaction of cellular respiration and photosynthesis are almost the opposite. This is because they work in tandem, as plants use the energy from the sun to convert carbon dioxide that other organisms release through cellular respiration into glucose, which we break down for energy.
Simultaneously, plants also release oxygen that we use to breathe and perform cellular respiration with. The broken-down glucose allows us to utilize chemical energy in the form of ATP, which can provide energy for many cellular processes. This "cycle of life" is shown in Figure 3, which is crucial for survival.
Keep in mind that there are other metabolic processes that are not aerobic or do not involve oxygen. These processes are called anaerobic processes, such as fermentation. Anaerobic metabolism can break down carbohydrates for energy in the absence of oxygen.
Scientists think that anaerobic processes like glycolysis evolved many years ago when there was no oxygen in the atmosphere. Despite the complexity of metabolism, living organisms still share some pathways indicating our shared evolutionary history.
Glycolysis is a metabolic pathway common to cellular respiration and fermentation as it evolved before oxygen was available and demonstrates common ancestry between living organisms.
A metabolic pathway is a series of chemical reactions connected by intermediates.
Aerobic processes are metabolic pathways that require oxygen.
An example of a prominent metabolic pathway is cellular respiration.
Oxidative Phosphorylation is the metabolic pathway that produces the most ATP as its coupled with ATP synthesis.
What is a metabolic pathway?
A metabolic pathway is a series of chemical reactions connected by intermediates in your body.
What is metabolism?
Metabolism can be thought of as all the chemical changes that occur within a living organism.
How do enzymes and coenzymes relate to metabolic pathways?
Metabolic pathways generally consist of a sequence of reactions activated by enzymes where the product of the previous reaction becomes the starting point or reactant for the following reaction.
What are the types of pathways?
Anabolic pathways are pathways that require energy to buildup or construct molecules. For example, the buildup of carbohydrates is an example of an anabolic pathway.
What are some examples of anabolic pathways?
photosynthesis
What are some examples of catabolic pathways?
cellular respiration
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