Enzyme: Difference between revisions

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{{SI}}
{{SI}}
[[File:Glucosidase enzyme.png|Glucosidase enzyme|thumb]]
[[File:IUPAC definition for enzymes.png|IUPAC definition for enzymes|thumb]]
[[File:Eduardbuchner.jpg|Eduardbuchner|thumb]]
[[File:Q10 graph c.svg|Enzyme|Q10 graph|thumb]]
[[File:Enzyme structure.svg|Enzyme structure|thumb]]
Enzymes are [[large biological molecules]] that play a crucial role in sustaining life. They drive thousands of [[metabolic processes]] that are essential for the survival of organisms. Their primary function is to act as highly selective [[catalysts]], greatly enhancing both the speed and specificity of metabolic reactions. These reactions range from the [[digestion]] of food to the intricate [[synthesis of DNA]].
Enzymes are [[large biological molecules]] that play a crucial role in sustaining life. They drive thousands of [[metabolic processes]] that are essential for the survival of organisms. Their primary function is to act as highly selective [[catalysts]], greatly enhancing both the speed and specificity of metabolic reactions. These reactions range from the [[digestion]] of food to the intricate [[synthesis of DNA]].


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Several enzymes find commercial applications. For instance, some are employed in the synthesis of [[antibiotics]]. Household products also harness the power of enzymes to expedite biochemical reactions. For example, biological washing powders contain enzymes that break down protein or fat stains on clothes. Likewise, enzymes in meat tenderizers decompose proteins into smaller molecules, rendering the meat more tender and easier to chew.
Several enzymes find commercial applications. For instance, some are employed in the synthesis of [[antibiotics]]. Household products also harness the power of enzymes to expedite biochemical reactions. For example, biological washing powders contain enzymes that break down protein or fat stains on clothes. Likewise, enzymes in meat tenderizers decompose proteins into smaller molecules, rendering the meat more tender and easier to chew.


== Gallery ==
<gallery>
File:Hexokinase induced fit.svg|Hexokinase induced fit
File:Transketolase + TPP.png|Transketolase + TPP
File:Enzyme catalysis energy levels 2.svg|Enzyme catalysis energy levels
File:Enzyme mechanism 2.svg|Enzyme mechanism
File:Michaelis Menten curve 2.svg|Michaelis Menten curve
File:DHFR methotrexate inhibitor.svg|DHFR methotrexate inhibitor
File:Methotrexate vs folate 2.svg|Methotrexate vs folate
</gallery>
=='''See Also'''==
=='''See Also'''==
* [[Metabolism]]
* [[Metabolism]]
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[[Category:Catalysis]]
[[Category:Catalysis]]
[[Category:Process chemicals]]
[[Category:Process chemicals]]
<gallery>
File:Glucosidase_enzyme.png|Enzyme
File:IUPAC_definition_for_enzymes.png|Enzyme
File:Eduardbuchner.jpg|Enzyme
File:Q10_graph_c.svg|Enzyme
File:Enzyme_structure.svg|Enzyme
File:Hexokinase_induced_fit.svg|Enzyme
File:Transketolase_+_TPP.png|Enzyme
File:Enzyme_catalysis_energy_levels_2.svg|Enzyme
File:Enzyme_mechanism_2.svg|Enzyme
File:Michaelis_Menten_curve_2.svg|Enzyme
File:DHFR_methotrexate_inhibitor.svg|Enzyme
File:Methotrexate_vs_folate_2.svg|Enzyme
</gallery>
== Enzyme ==
<gallery>
File:Enzyme mechanism 2.svg|Enzyme mechanism
File:Michaelis Menten curve 2.svg|Michaelis-Menten curve
File:DHFR methotrexate inhibitor.svg|DHFR methotrexate inhibitor
File:Methotrexate vs folate 2.svg|Methotrexate vs folate
</gallery>

Latest revision as of 12:34, 21 March 2025

Editor-In-Chief: Prab R Tumpati, MD
Obesity, Sleep & Internal medicine
Founder, WikiMD Wellnesspedia &
W8MD's medical weight loss NYC, sleep center NYC
Philadelphia medical weight loss and Philadelphia sleep clinics

File:Glucosidase enzyme.png
Glucosidase enzyme
File:IUPAC definition for enzymes.png
IUPAC definition for enzymes
File:Eduardbuchner.jpg
Eduardbuchner
File:Q10 graph c.svg
Q10 graph
File:Enzyme structure.svg
Enzyme structure

Enzymes are large biological molecules that play a crucial role in sustaining life. They drive thousands of metabolic processes that are essential for the survival of organisms. Their primary function is to act as highly selective catalysts, greatly enhancing both the speed and specificity of metabolic reactions. These reactions range from the digestion of food to the intricate synthesis of DNA.

Structure and Composition[edit]

The majority of enzymes are proteins. However, there are also catalytic RNA molecules that have been recognized as enzymes. Enzymes are characterized by their specific three-dimensional structures. To facilitate their catalytic action, enzymes might utilize organic cofactors, such as biotin, or inorganic cofactors, for instance, the magnesium ion.

Functionality[edit]

Enzymatic Reactions[edit]

In enzymatic reactions, the starting molecules or substrates undergo conversion to form different molecules, known as products. For a biological cell to function efficiently and sustain life, nearly all its chemical reactions necessitate enzymes. This is because enzymes accelerate these reactions to rates that are conducive to life. Their selectivity for substrates means that they only expedite specific reactions among myriad possibilities. This specificity is the reason the array of enzymes present in a cell dictates the metabolic pathways that the cell will undertake.

Catalytic Mechanism[edit]

Just like other catalysts, enzymes function by diminishing the activation energy (Ea‡) necessary for a reaction. This results in an exponential increase in the reaction rate. Consequently, products form at a much quicker rate, and reactions attain their equilibrium faster. Notably, enzyme reaction rates can be up to millions of times faster than those of equivalent un-catalyzed reactions. Despite their impressive catalytic ability, enzymes are neither consumed in the reactions they facilitate nor do they modify the reactions' equilibrium. However, they do stand out from many other catalysts due to their remarkable substrate specificity. Currently, enzymes are documented to catalyze approximately 4,000 biochemical reactions. There are also RNA molecules termed ribozymes that have a catalytic function, with parts of the ribosome serving as a prime example. Furthermore, synthetic molecules, referred to as artificial enzymes, exhibit enzyme-like catalysis.

Regulation and Interactions[edit]

Various molecules can influence enzyme activity. While inhibitors are molecules that diminish enzyme activity, activators are ones that enhance it. Numerous drugs and poisons function as enzyme inhibitors. Factors like temperature, pressure, chemical environment (such as pH), and substrate concentration can also impact enzyme activity.

Commercial and Practical Applications[edit]

Several enzymes find commercial applications. For instance, some are employed in the synthesis of antibiotics. Household products also harness the power of enzymes to expedite biochemical reactions. For example, biological washing powders contain enzymes that break down protein or fat stains on clothes. Likewise, enzymes in meat tenderizers decompose proteins into smaller molecules, rendering the meat more tender and easier to chew.

Gallery[edit]

See Also[edit]

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