Aldehyde tag

From Wikipedia, the free encyclopedia

An aldehyde tag is a short peptide tag that can be further modified to add fluorophores, glycans, PEG (polyethylene glycol) chains, or reactive groups for further synthesis.[1] A short, genetically-encoded peptide with a consensus sequence LCxPxR is introduced into fusion proteins, and by subsequent treatment with the formylglycine-generating enzyme (FGE), the cysteine of the tag is converted to a reactive aldehyde group. This electrophilic group can be targeted by an array of aldehyde-specific reagents, such as aminooxy- or hydrazide-functionalized compounds.

The aldehyde tag is an artificial peptide tag recognized by the formylglycine-generating enzyme (FGE). Formylglycine is a glycine with a formyl group (-CHO) at the α-carbon.[2] The sulfatase motif is the basis for the sequence of the peptide which results in the site-specific conversion of a cysteine to a formylglycine residue. The peptide tag was engineered after studies on FGE recognizable sequences in sulfatases from different organisms revealed a high homology in the sulfatase motif in bacteria, archaea as well as eukaryotes.[3]

Aldehydes and ketones are used as chemical reporters due to their electrophilic properties. These properties enable a reaction under mild conditions when using a strong nucleophilic coupling partner. Typically, hydrazides and aminooxy probes are used in bioconjugation by forming stabilized addition products with carbonyl groups that are favored under the physiological reaction conditions. At neutral pH, the equilibrium of Schiff base formation lies far to the reactant side. To form stable hydrazones and oximes, compound derivatives are used to yield more product. Since the pH optimum of 4 to 6 cannot be achieved by adding a catalyst due to associated toxicity, the reaction is slow in live cells. A typical reaction constant is 10−4 to 10−3 M−1 s−1.[4]

A carbonyl group is introduced into proteins as a chemical reporter using various techniques, including methods like stop codon suppression and aldehyde tagging.[3][5] Limiting the use of aldehydes and ketones is their restricted bioorthogonality in certain cellular environments. Limitations of aldehydes and ketones as chemical reporters include:

  • Competition with endogenous aldehydes or ketones in metabolites and cofactors, resulting in low yields and impaired specificity.
  • Side reactions, such as oxidation or unwanted addition of endogenous nucleophiles.
  • Restrained set of probes that form sufficiently stable products.[6][7]

Aldehydes and ketones are therefore best used in compartments where such unwanted side reactions are decreased. For experiments with live cells, cell surfaces and extracellular space are typical fielding areas. Nevertheless, a feature of carbonyl groups is the vast number of organic reactions that involve them as electrophiles. Some of these reactions are readily convertible to ligations for probing aldehydes. A reaction recently employed for bioconjugation by Agarwal et al. is the adaptation of the Pictet-Spengler reaction as a ligation. The reaction is known from natural product biosynthetic pathways [8] and has the major advantage of forming a new carbon-carbon bond. This guarantees long-term stability compared to carbon-heteroatom bonds with similar reaction kinetics.[9]

The modification of cysteine or, more rarely, serine[10] by FGE is an uncommon posttranslational modification that was discovered in the late 1990s.[11] The deficiency of FGE leads to an overall deficiency of functional sulfatases due to a lack of α-formylglycine formation vital for the sulfatases to perform their function. FGE is essential for protein modification and need of high specificity and conversion rate is given in the native setting, which makes this reaction applicable in chemical and synthetic biology.[12]

Aldehyde tags were first inserted into the modified sulfatase motif peptide for proteins of interest in 2007.[13] Since then, similar usage of aldehydes and ketones as chemical reporters in bioorthogonal applications has been demonstrated in self-assembly of cell-lysing drugs,[14] the targeting of proteins,[15][5] as well as glycans [16] and the preparation of heterobifunctional fusion proteins.[17]

Genetically encoding the aldehyde tag

The formylglycine tag or aldehyde tag is a convenient 6- or 13-amino acids long tag fused to a protein of interest. The 6-mer tag represents the small core consensus sequence and the 13-mer tag the longer full motif. The experiments on the genetically encoded aldehyde tag by clearly showed the high conversion efficiency with only the core consensus sequence present. Four proteins were produced recombinantly in E.coli with an 86% efficiency of for the full-length motif and >90% efficiency for the 6-mer determined by mass spectrometry.[3] The size of the sequence is analogous to the commonly used 6x His-Tag[18] and has the advantage that it can also be genetically encoded. The sequence is recognized in the ER solely depending on primary sequence and subsequently targeted by FGE.[11] Notably, in the setup of recombinant expression proteins in E. coli a coexpression of exogenous FGE aids full conversion,[3] although E. coli has endogenous FGE-activity.[19] The introduction of an aldehyde tag has a workflow that consists of three segments: A the expression of the fusion protein, that carries the peptide tag derived from the sulfatase motif, B the enzymatic conversion of Cys to f(Gly) and C the bioorthogonal probing with hydrazides or alkoxy amines (Fig. 1).

Figure 1: Formylglycine aldehyde tag Carrico et al.:[3] A The aldehyde tag is genetically inserted into a protein of interest. In this example, the human growth hormone (hGH, PDB:1HUW), one of the four initially examined proteins, is shown. The N-terminus of the protein is fused to the formylglycine aldehyde tag. B The FGE recognizes the motif and the cysteine (Cys) residue is converted into the formylglycine residue [f(Gly)]. The chemical reporter is formed on location by an enzymatic reaction. C The carbonyl group is probed using typically hydrazide- or alkoxy amine-functionalized dyes or other compounds.

As seen in Fig. 1, the engineered aldehyde tag consists of six amino acids. A set of organisms from all domains of life was chosen and the sequence homology of the sulfatase motif was determined. The sequence used is the best consensus for sequences found in bacteria, archaea, worms and higher vertebrates.[3]

FGE-mechanism of cysteine-formylglycine conversion

The catalytic mechanism of FGE is well studied. A multistep redox reaction with a covalent enzyme: substrate intermediate is proposed. The role of the cysteine residue for the occurring conversion was studied by mutating the cysteine to alanine. No conversion was found using mass spectrometry when the mutated peptide tag was used.[3] The mechanism shows the important role of the redox active thiol group of cysteine in the formation of f(Gly), as seen in Fig. 2. The key step of the catalytic cycle is the monooxidation of the cysteine residue of the enzyme, forming a reactive sulfenic acid intermediate. Subsequently, the hydroxyl group is transferred to the cysteine of the substrate and after hetero-analogous β-elimination of H2O, a thioaldehyde is formed. This compound is very reactive and easily hydrolyzed, releasing the aldehyde and a molecule of H2S,[20][21][12]

Figure 2: Conversion of Cys to f(Gly) by FGE from Dierks et al.:[12] Substrate I binds to FGE, and disulfide isomerization occurs IIb. Cys341 of FGE is oxidized to a sulfenic acid IIc The hydroxyl group is transferred to the substrate and a substrate-sulfenic acid III is generated. β‑elimination of water leads to a thioaldehyde IV which is quickly hydrated to V and after elimination of H2S, the aldehyde VI is formed. The equilibrium lies far to the product side due to the high reactivity of the thioaldehyde IV compared to the aldehyde VI and its arising tendency to form the hydrate V. CysSubs = substrate protein cysteine embedded in sulfatase motif.

Applications

References

Related Articles

Wikiwand AI