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Acetyl group
Acetyl group
Acetyl group
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Acetyl group
Skeletal formula of acetyl with all implicit hydrogens shown
Skeletal formula of acetyl with all implicit hydrogens shown
Names
IUPAC name
Acetyl (preferred to ethanoyl)[1][2][3]
Systematic IUPAC name
Methyloxidocarbon(•)[4] (additive)
Identifiers
3D model (JSmol)
Abbreviations Ac
1697938
ChEBI
ChemSpider
786
  • InChI=1S/C2H3O/c1-2-3/h1H3 checkY
    Key: TUCNEACPLKLKNU-UHFFFAOYSA-N checkY
  • C[C]=O
Properties
C2H3O
Molar mass 43.045 g·mol−1
Thermochemistry
−15 to −9 kJ mol−1
Related compounds
Related compounds
 Acetone
Carbon monoxide
Acetic acid
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
☒N verify (what is checkY☒N ?)

In organic chemistry, an acetyl group is a functional group denoted by the chemical formula −COCH3 and the structure −C(=O)−CH3. It is sometimes represented by the symbol Ac[5][6] (not to be confused with the element actinium). In IUPAC nomenclature, an acetyl group is called an ethanoyl group.

An acetyl group contains a methyl group (−CH3) that is single-bonded to a carbonyl (C=O), making it an acyl group. The carbonyl center of an acyl radical has one non-bonded electron with which it forms a chemical bond to the remainder (denoted with the letter R) of the molecule.

The acetyl moiety is a component of many organic compounds, including acetic acid, the neurotransmitter acetylcholine, acetyl-CoA, acetylcysteine, acetaminophen (also known as paracetamol), and acetylsalicylic acid (also known as aspirin).

Acetylation

[edit]
Main article: Acetylation

Acetylation is the chemical reaction known as "ethanoylation" in the IUPAC nomenclature. It depicts a reactionary process that injects an acetyl functional group into a chemical compound. The opposite reaction is called "deacetylation", and this is the removal of the acetyl group. An example of an acetylation reaction is the conversion of glycine to N-acetylglycine:[7]

H2NCH2CO2H + (CH3CO)2O → CH3C(O)NHCH2CO2H + CH3CO2H

In biology

[edit]

Enzymes which perform acetylation on proteins or other biomolecules are known as acetyltransferases. In biological organisms, acetyl groups are commonly transferred from acetyl-CoA to other organic molecules. Acetyl-CoA is an intermediate in the biological synthesis and in the breakdown of many organic molecules. Acetyl-CoA is also created during the second stage of cellular respiration (pyruvate decarboxylation) by the action of pyruvate dehydrogenase on pyruvic acid.[8]

Proteins are often modified via acetylation, for various purposes. For example, acetylation of histones by histone acetyltransferases (HATs) results in an expansion of local chromatin structure, allowing transcription to occur by enabling RNA polymerase to access DNA. However, removal of the acetyl group by histone deacetylases (HDACs) condenses the local chromatin structure, thereby preventing transcription.[9]

In synthetic organic and pharmaceutical chemistry

[edit]

Acetylation can be achieved by chemists using a variety of methods, most commonly with the use of acetic anhydride or acetyl chloride, often in the presence of a tertiary or aromatic amine base.

Pharmacology

[edit]

Acetylated organic molecules exhibit increased ability to cross the selectively permeable blood–brain barrier.[10] Acetylation helps a given drug reach the brain more quickly, making the drug's effects more intense and increasing the effectiveness of a given dose.[citation needed] The acetyl group in acetylsalicylic acid (aspirin) enhances its effectiveness relative to the natural anti-inflammatant salicylic acid. In similar manner, acetylation converts the natural painkiller morphine into the far more potent heroin (diacetylmorphine).[10]

There is some evidence that acetyl-L-carnitine may be more effective for some applications than L-carnitine.[11] Acetylation of resveratrol holds promise as one of the first anti-radiation medicines for human populations.[12]

Etymology

[edit]

The term "acetyl" was coined by the German chemist Justus von Liebig in 1839 to describe what he incorrectly believed to be the radical of acetic acid (the main component of vinegar, aside from water), which is now known as the vinyl group (coined in 1851); "acetyl" is derived from the Latin acētum, meaning "vinegar." When it was shown that Liebig's theory was wrong and acetic acid had a different radical, his name was carried over to the correct one, but the name of acetylene (coined in 1860) was retained.[13]

See also

[edit]

References

[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Acetyl group

View on Grokipedia
from Grokipedia
In , the is a with the formula −C(=O)CH₃ (or CH₃CO−). Known systematically as the ethanoyl group in IUPAC nomenclature, it consists of a (C=O) bonded to a (CH₃). Derived from acetic acid (CH₃COOH), the acetyl group plays a key role in reactions, , and the structure of many natural and synthetic compounds.

Structure and Properties

Chemical Structure

The acetyl group is a fundamental in , represented by the formula −C(=O)−CH₃, where a (C=O) is directly bonded to a (CH₃). This moiety arises from acetic acid (CH₃COOH) by removal of the hydroxyl group, making it the simplest , with the systematic IUPAC name ethanoyl group. As a substituent or radical, the acetyl group has the molecular formula C₂H₃O. In structural terms, the carbonyl carbon is sp² hybridized, resulting in a planar trigonal geometry around it, with the C=O double bond consisting of a σ bond and a π bond, and the single bond to the methyl carbon. The methyl carbon, in contrast, is sp³ hybridized and adopts a tetrahedral geometry. This group serves primarily as a in larger molecules, often denoted in shorthand as Ac or CH₃CO−, highlighting its role in modifying the of organic compounds through attachment via the carbonyl carbon.

Physical and Chemical Properties

The acetyl group features a highly polar carbonyl (C=O) bond due to the of oxygen, resulting in a partial negative charge on oxygen and partial positive on carbon. This polarity contributes to dipole moments of approximately 2.7–3.0 D in simple acetyl-containing compounds like acetone. The group also enables hydrogen bonding as the oxygen accepts protons, increasing the water solubility and boiling points of molecules compared to non-polar analogs of similar size. In infrared spectroscopy, the acetyl group's C=O stretching vibration appears as a strong absorption band at 1710–1715 cm⁻¹, characteristic of methyl ketones. Bond lengths are typically 1.20–1.22 Å for the C=O bond and 1.50 Å for the C–CH₃ bond. Chemically, the carbonyl carbon in the acetyl group is electrophilic, owing to resonance delocalization of the oxygen's lone pairs and the electron-withdrawing nature of the group, predisposing it to interactions with nucleophiles.

History and Nomenclature

Discovery

The concept of the acetyl group emerged in the early amid studies of acetic acid derivatives, as chemists began exploring organic compounds through the lens of radical theory, which posited stable atomic groups behaving as units in reactions. This framework allowed researchers to interpret the behavior of substances like acetic acid (CH₃COOH) and its salts, recognizing patterns in their transformations that suggested a common fragment derived from the acid. A pivotal advancement came from during the 1830s and 1840s, as he systematically identified organic radicals through experimental analysis of compounds such as aldehydes and ethers. In 1839, Liebig proposed the term "acetyl" for what he believed to be the radical C₂H₃O (modern understanding adjusts this to the CH₃CO- group), linking it directly to acetic acid based on its role in derivative formations; this nomenclature built on his earlier work with the benzoyl radical and marked a key step in classifying acyl groups. The mid-19th century saw the development of practical acetylation methods, enabling isolation and use of acetyl-containing reagents. In 1852, Charles Frédéric Gerhardt synthesized by heating with , providing a key acetylating agent for and formation. That same year, Gerhardt also prepared from and , further expanding tools for introducing the acetyl group into organic molecules. The proposal of acetyl as a radical received definitive confirmation in the through spectroscopic techniques, which elucidated its electronic and structural properties. Notably, the acetyl radical (CH₃CO•) was first observed via (EPR) spectroscopy in 1963 during photolysis of biacetyl at low temperatures, validating its existence and as predicted by earlier .

Etymology and Naming

The term "acetyl" was coined by in 1839, derived from Latin acetum ("," referring to ) combined with the Greek hylē ("matter" or "substance"), reflecting its role as a radical unit. In modern IUPAC nomenclature, the acetyl group is systematically named the ethanoyl group (CH₃CO-), emphasizing its derivation from ethanoic acid (). This nomenclature extends to related terms like (ethanoyl chloride) and (ethanoic anhydride).

Chemical Reactivity

Acetylation Reactions

refers to the chemical process of attaching an acetyl group (CH₃CO-) to a substrate via nucleophilic acyl substitution, where the acetyl moiety is transferred from an activated donor to a nucleophilic site on the . This reaction is fundamental in for protecting functional groups or modifying molecular properties. The most common acetyl donors are ((CH₃CO)₂O) and (CH₃COCl), which are highly reactive due to the good leaving groups and , respectively. The general mechanism proceeds through a nucleophilic acyl substitution pathway. The , such as an alcohol (ROH) or (RNH₂), attacks the electrophilic carbonyl carbon of the acetyl donor, forming a tetrahedral intermediate. This intermediate then collapses by eliminating the , reforming the carbonyl and yielding the acetylated product. For , the acetate ion serves as the , while for , chloride ion is expelled. The reaction is often facilitated under mild conditions, typically at , to minimize side reactions. Common conditions for acetylation involve base catalysis to scavenge the acid byproduct and enhance nucleophilicity. is a widely used base for with alcohols, amines, and , as it neutralizes the generated acetic acid and acts as a in many protocols. For instance, the of to form esters proceeds efficiently with in , providing high yields under ambient conditions. A representative for the acetylation of an alcohol is: R-OH+(CH3CO)2OR-OCOCH3+CH3COOH\text{R-OH} + (\text{CH}_3\text{CO})_2\text{O} \rightarrow \text{R-OCOCH}_3 + \text{CH}_3\text{COOH} This base-catalyzed approach ensures selectivity, particularly for primary and secondary alcohols or amines, while avoiding harsh conditions that could affect sensitive substrates.

Other Reactions

The acetyl group, when present in ester form as in acetate esters (R-OCOCH₃), undergoes hydrolysis under either acidic or basic conditions to cleave the ester bond, regenerating the parent alcohol (ROH) and producing acetic acid (CH₃COOH). In basic hydrolysis, often termed saponification, the reaction proceeds via nucleophilic attack by hydroxide ion on the carbonyl carbon, forming a tetrahedral intermediate that collapses to yield the carboxylate salt (CH₃COO⁻) and alcohol; subsequent acidification liberates acetic acid./21:_Carboxylic_Acid_Derivatives_and_Nitriles/21.05:_Chemistry_of_Carboxylic_Acid_Derivatives-_Hydrolysis) Acidic hydrolysis, catalyzed by H⁺, involves protonation of the carbonyl oxygen to enhance electrophilicity, followed by water addition and eventual deprotonation to the same products. This reversibility highlights the protecting group utility of acetate esters in synthesis, where mild conditions allow selective deprotection without affecting other functionalities. Reduction of the acetyl group varies by its attachment. In acetate esters (CH₃COOR), lithium aluminum hydride (LiAlH₄) reduces the ester to ethanol (CH₃CH₂OH) and the parent alcohol (ROH) through stepwise hydride delivery to the carbonyl, forming an aldehyde intermediate that is further reduced. For acetyl ketones (CH₃COR), where the acetyl is -COCH₃, LiAlH₄ similarly reduces the carbonyl to a secondary alcohol (CH₃CH(OH)R)./Aldehydes_and_Ketones/Reactivity_of_Aldehydes_and_Ketones/Reduction_of_Aldehydes_and_Ketones) In contrast, deoxygenative reductions convert the carbonyl to a methylene group (-CH₂-). The Wolff-Kishner reduction, using hydrazine and base (e.g., KOH at high temperature), forms a hydrazone intermediate that decomposes to CH₃CH₂R, avoiding acidic conditions suitable for acid-sensitive substrates./Aldehydes_and_Ketones/Reactivity_of_Aldehydes_and_Ketones/Wolff-Kishner_Reduction) The Clemmensen reduction employs zinc amalgam in HCl to achieve the same transformation (CH₃COR → CH₃CH₂R), proceeding via carbocation or radical mechanisms under strongly acidic media. Elimination reactions cleave the acetyl group in methyl ketones (CH₃COR) via the , where treatment with halogen (e.g., I₂) and base (OH⁻) leads to trihalogenation of the , followed by nucleophilic attack and cleavage to (CHI₃) and (RCOO⁻). CH3COR+3I2+4OHCHI3+RCOO+3I+3H2O\text{CH}_3\text{COR} + 3\text{I}_2 + 4\text{OH}^- \rightarrow \text{CHI}_3 + \text{RCOO}^- + 3\text{I}^- + 3\text{H}_2\text{O} This reaction is diagnostic for methyl ketones, proceeding through sequential halogenation and C-C bond scission, with applications in structure elucidation and synthesis of carboxylic acids from acetyl-containing precursors. Oxidative cleavage targets the acetyl side chain in contexts like aromatic acetyl compounds (e.g., , PhCOCH₃), where alkaline KMnO₄ oxidizes the to a (PhCOOH), degrading the side chain via benzylic oxidation and subsequent C-C bond rupture. This process requires a benzylic and harsh conditions (heat, basic KMnO₄), converting the -COCH₃ to -COOH while preserving the aryl core, as seen in the quantitative conversion of to .

Biological Role

Acetyl-CoA in Metabolism

Acetyl-coenzyme A () is a central intermediate in cellular , acting as the primary carrier of the acetyl group. It is mainly produced in the mitochondria through the oxidative of pyruvate by the , linking to the tricarboxylic acid (TCA) cycle. In the TCA cycle, condenses with oxaloacetate to form citrate, enabling the production of reducing equivalents (NADH and FADH₂) for and ATP generation. is also generated from the β-oxidation of fatty acids and the of ketogenic . Beyond , serves as a building block for anabolic processes; it is transported to the via the citrate shuttle for the synthesis of fatty acids, , and other . The levels of reflect the cell's nutritional and energy status, influencing metabolic flux and regulatory processes.

Post-Translational Modifications

In post-translational modifications, acetylation plays a pivotal role in regulating and cellular signaling through the modification of proteins such as and non-histone factors. acetyltransferases (HATs) catalyze the addition of groups to specific residues on tails, which neutralizes their positive charge and diminishes the electrostatic attraction to DNA, resulting in a more open structure that facilitates access for transcriptional machinery. This is essential for activating transcription in response to various cellular signals. The core mechanism of histone acetylation involves the enzymatic transfer of an acetyl moiety from acetyl-CoA to the ε-amino group of the target lysine residue, a reaction that alters chromatin architecture without altering the underlying DNA sequence. Acetyl-CoA acts as the universal acetyl donor in these reactions. Beyond histones, lysine acetylation extends to non-histone proteins; for instance, acetylation of the p53 tumor suppressor at multiple lysine sites enhances its stability, DNA-binding affinity, and transcriptional activation of genes involved in cell cycle arrest and apoptosis, thereby reinforcing its role in tumor suppression. Similarly, acetylation of α-tubulin at lysine 40 increases microtubule flexibility and durability, contributing to cytoskeletal stability and resistance to mechanical stress during cellular processes like intracellular transport. Reversibility is maintained by deacetylases (HDACs), enzymes that hydrolyze the acetyl group from residues, thereby reinstating the positive charge and promoting condensation to silence . Dysregulated HDAC activity, often through overexpression in tumor cells, is implicated in cancer progression by suppressing tumor suppressor genes and promoting activity. Therapeutic targeting of HDACs with inhibitors such as (suberoylanilide hydroxamic acid), approved by the FDA for , restores acetylation levels, reactivates silenced genes, and induces cancer cell death.

Synthetic Applications

In Organic Synthesis

The acetyl group is widely employed as a for alcohols and amines in due to its facile installation via reaction with or , typically in the presence of a base such as or triethylamine, and its straightforward removal through base-catalyzed or mild acidic conditions. For alcohols, forms stable esters that tolerate a range of basic and nucleophilic reagents but can be selectively deprotonated and cleaved under aqueous basic conditions, such as with or . This reversibility stems from the basic reactivity of , where the linkage is hydrolyzed to regenerate the free hydroxyl group. In carbohydrate synthesis, acetyl protection is particularly valuable for masking multiple hydroxyl groups in polyols; for instance, peracetylation of glucose with in proceeds in over 95% yield, enabling regioselective glycosylations or oxidations at unprotected sites before deacetylation with methanolic . Similarly, for amines, N- yields acetamides that protect the nitrogen during electrophilic additions or coupling reactions, with deprotection achieved via in yields exceeding 90% using aqueous acid or base. As a directing group, the acetyl moiety functions as a meta-director in (EAS) reactions owing to its strong electron-withdrawing through the carbonyl, which deactivates the ring and favors meta substitution over ortho/para positions. This property is exploited in multi-step aromatic functionalizations, such as in the synthesis of meta-substituted anilines or pharmaceuticals, where initial Friedel-Crafts installs the acetyl group using and a Lewis acid like aluminum chloride, followed by meta-selective with and to afford the meta-nitroacetophenone in 70-80% yield, with the acetyl later removed by Wolff-Kishner reduction or . The meta-directing ability ensures high , often achieving >90% meta product in subsequent EAS steps like . In the total synthesis of complex natural products like and glycopeptides, the acetyl group plays a key role in protecting phenolic and alcoholic functionalities during assembly, allowing orthogonal manipulation of other sites. For example, in a convergent synthesis of aglycon, acetyl groups were used to protect hydroxyls on the aromatic rings, surviving macrocyclization and biaryl coupling steps before global deprotection with in . This approach highlights the acetyl's compatibility with transition-metal and its selective removal without affecting other protections. The acetyl group's advantages include its orthogonality to silyl ether protections, such as tert-butyldimethylsilyl (TBS) ethers, which are base-stable but fluoride-labile; in polyol syntheses, selective acetylation of secondary alcohols (using /DMAP, 85-95% yield) alongside TBS protection of primaries enables differential deprotection—acetyl via K2CO3/MeOH (90% yield) and TBS via TBAF (92% yield)—facilitating stereocontrolled fragment couplings in polyketide chains.

In Pharmaceutical Development

The acetyl group is a common structural feature in many pharmaceutical compounds, enhancing properties such as stability, solubility, and . A prominent example is aspirin (acetylsalicylic acid), where the acetyl moiety irreversibly acetylates the serine residue in (COX) enzymes, inhibiting synthesis and contributing to its , , and effects. In , is employed to create prodrugs that improve absorption or reduce side effects; for instance, acetyl-L-carnitine serves as a neuroprotective agent by providing acetyl groups for synthesis and mitochondrial energy production. Additionally, modifies or peptides to target specific transporters, as seen in N-acetyl-leucine, which leverages anion transport for therapeutic delivery in vestibular disorders. These applications underscore the acetyl group's role in optimizing and in modern pharmaceuticals.

Pharmacological Aspects

Role in Drug Molecules

The acetyl group is integral to the structure and pharmacological profile of several key drugs, often enhancing , stability, or targeted activity while mitigating side effects. In aspirin (acetylsalicylic acid), the acetyl moiety esterifies the phenolic hydroxyl group of , effectively masking the free functionality. This modification reduces the drug's ity and local gastric irritation upon , a common issue with itself. , esterases hydrolyze the acetyl group, releasing as the responsible for aspirin's , , and effects. Similarly, in (diacetylmorphine), the presence of two acetyl groups on the scaffold dramatically increases compared to unmodified . This structural alteration facilitates rapid diffusion across the blood-brain barrier, leading to quicker onset of effects in the . The enhanced —nearly 100-fold greater transport efficiency—underpins 's faster euphoric and action relative to . The acetyl group also features prominently in neurotransmitter mimics and related therapeutics targeting the cholinergic system. In , the natural , the acetyl ester linkage is essential for its recognition by receptors and subsequent by , driving synaptic transmission. Synthetic analogs, such as (an acetyl ester derivative), retain this acetyl motif to elicit activity in diagnostics and treatments for conditions like . In management, drugs like donepezil enhance signaling by inhibiting , thereby prolonging the action of endogenous and underscoring the acetyl group's central role in this pathway. Beyond these, the acetyl group contributes to the efficacy of other analgesics and protectants. In acetaminophen (paracetamol), the N-acetyl substitution on the p-aminophenol core supports its central mechanism, potentially via metabolism to the bioactive endocannabinoid-like compound AM404, which modulates pain pathways without significant peripheral anti-inflammatory effects. Likewise, in N-acetylcysteine (NAC), the acetyl moiety improves oral and stability of the underlying , enabling NAC's dual role as a mucolytic agent—by cleaving bonds in viscous —and as an precursor to replenishment in acetaminophen overdose and respiratory disorders.

Biotransformation and Metabolism

Acetylation serves as a key phase II process in , primarily catalyzed by N-acetyltransferase (NAT) enzymes, which transfer an acetyl group from to substrates such as aromatic amines and hydrazines. This conjugation reaction facilitates the inactivation and elimination of xenobiotics, including pharmaceuticals, by modifying their chemical structure to enhance . NAT1 and NAT2 isoforms exhibit distinct tissue distributions, with NAT2 predominantly active in the liver and intestines, playing a central role in hepatic . A prominent example is the of isoniazid, a first-line antitubercular drug, where NAT2 converts the moiety to acetylisoniazid, significantly influencing the drug's plasma and therapeutic efficacy. Rapid acetylators exhibit shorter (approximately 1-2 hours) and require higher doses to maintain effective concentrations, while slow acetylators experience prolonged exposure, increasing the risk of . Genetic polymorphisms in the NAT2 determine these phenotypes, with slow acetylators (prevalent in about 50-60% of certain populations, such as Caucasians) facing heightened adverse effects from drugs like sulfonamides, where incomplete acetylation leads to accumulation of toxic parent compounds and increased reactions. This variability necessitates dosing adjustments to optimize safety and efficacy. Beyond specific drugs, acetylation contributes to the of various xenobiotics by promoting their urinary , as seen in the N-acetylation of caffeine metabolites like 5-acetylamino-6-formylamino-3-methyluracil by NAT1. This process neutralizes potentially reactive species, preventing cellular damage and facilitating clearance through the kidneys. Pharmacokinetically, acetylation generally increases the polarity and solubility of metabolites, enhancing renal clearance and reducing systemic exposure; for instance, acetylated conjugates are more readily filtered and excreted in compared to lipophilic precursors. However, when acetylation occurs on primary groups, it can convert charged species to neutral amides, modestly increasing and potentially improving penetration across the blood-brain barrier in certain contexts, as observed with acetylated prodrugs designed for delivery.

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