De-novo designed ß-lysine derivatives can both augment and diminish the proliferation rates of E. coli through the action of Elongation Factor P.

An investigation into the effect of modified ß-lysines on the growth rates of eubacterial cells is reported. It is shown that the effects observed are due to the post translational modification of Elongation Factor P (EFP) with these compounds catalysed by PoxA. PoxA was found to be remarkably promiscuous, which allowed the activity of a wide range of exogenous ß-lysines to be examined. Two chain-elongated ß-lysine derivatives which differ in aminoalkyl chain length by only 2 carbon units exhibited opposing biological activities - one promoting growth and the other retarding it. Both compounds were shown to operate through modification of EFP.

Amide-derived lysine analogues as substrates and inhibitors of histone lysine methyltransferases and acetyltransferases.

Histone lysine methyltransferases and acetyltransferases are two classes of epigenetic enzymes that play pivotal roles in human gene regulation. Although they both recognise and posttranslationally modify lysine residues in histone proteins, their difference in histone peptide-based substrates and inhibitors remains to be firmly established. Here, we have synthesised lysine mimics that posses an amide bond linker in the side chain, incorporated them into histone H3 tail peptides, and examined synthetic histone peptides as substrates and inhibitors for human lysine methyltransferases and acetyltransferases. This work demonstrates that histone lysine methyltransferases G9a and GLP do catalyse methylation of the most similar lysine mimic, whereas they typically do not tolerate more sterically demanding side chains. In contrast, histone lysine acetyltransferases GCN5 and PCAF do not catalyse acetylation of the same panel of lysine analogues. Our results also identify potent H3-based inhibitors of GLP methyltransferase, providing a basis for development of peptidomimetics for targeting KMT enzymes.

Strategic Design of Catalytic Lysine-Targeting Reversible Covalent BCR-ABL Inhibitors*.

Targeted covalent inhibitors have re-emerged as validated drugs to overcome acquired resistance in cancer treatment. Herein, by using a carbonyl boronic acid (CBA) warhead, we report the structure-based design of BCR-ABL inhibitors via reversible covalent targeting of the catalytic lysine with improved potency against both wild-type and mutant ABL kinases, especially ABLT315I bearing the gatekeeper residue mutation. We show the evolutionarily conserved lysine can be targeted selectively, and the selectivity depends largely on molecular recognition of the non-covalent pharmacophore in this class of inhibitors, probably due to the moderate reactivity of the warhead. We report the first co-crystal structures of covalent inhibitor-ABL kinase domain complexes, providing insights into the interaction of this warhead with the catalytic lysine. We also employed label-free mass spectrometry to evaluate off-targets of our compounds at proteome-wide level in different mammalian cells.

Synthesis and evaluation of Nα,Nε-diacetyl-l-lysine-inositol conjugates as cancer-selective probes for metabolic engineering of GPIs and GPI-anchored proteins.

Two myo-inositol derivatives having an Nα,Nε-diacetyl-l-lysine (Ac2Lys) moiety linked to the inositol 1-O-position through a self-cleavable linker and a metabolically stable 2-azidoethyl group linked to the inositol 3-O- and 4-O-positions, respectively, were designed and synthesized. The Ac2Lys moiety blocking the inositol 1-O-position required for GPI biosynthesis was expected to be removable by a combination of two enzymes, histone deacetylase (HDAC) and cathepsin L (CTSL), abundantly expressed in cancer cells, but not in normal cells, to transform these inositol derivatives into biosynthetically useful products with a free 1-O-position. As a result, it was found that these inositol derivatives could be incorporated into the glycosylphosphatidylinositol (GPI) biosynthetic pathway by cancer cells, but not by normal cells, to express azide-labeled GPIs and GPI-anchored proteins on cell surfaces. Consequently, this study has established a novel strategy and new molecular tools for selective metabolic labeling of cancer cells, which should be useful for various biological studies and applications.

Comparison of Molecular Recognition of Trimethyllysine and Trimethylthialysine by Epigenetic Reader Proteins.

Gaining a fundamental insight into the biomolecular recognition of posttranslationally modified histones by epigenetic reader proteins is of crucial importance to understanding the regulation of the activity of human genes. Here, we seek to establish whether trimethylthialysine, a simple trimethyllysine analogue generated through cysteine alkylation, is a good trimethyllysine mimic for studies on molecular recognition by reader proteins. Histone peptides bearing trimethylthialysine and trimethyllysine were examined for binding with five human reader proteins employing a combination of thermodynamic analyses, molecular dynamics simulations and quantum chemical analyses. Collectively, our experimental and computational findings reveal that trimethylthialysine and trimethyllysine exhibit very similar binding characteristics for the association with human reader proteins, thereby justifying the use of trimethylthialysine for studies aimed at dissecting the origin of biomolecular recognition in epigenetic processes that play important roles in human health and disease.

Multipurpose isothiocyanyl alanine/lysine: Use as solvatochromic IR probes and in site specific labeling/ligation of short peptides.

The solvatochromic IR responsivity of small side chain -NCS in two unexplored unnatural amino acids, isothiocyanyl alanine (NCSAla = Ita) and lysine (NCSLys = Itl), without perturbing the conformation is demonstrated in two designed short tripeptide (BocAla-NCSAla-Ala-OMe) and hexapeptide (BocLeu-Val-Phe-Phe-NCSLys-Gly-OMe). Demonstration of site specific fluorescent labeling in both the peptides and ligation type reaction in NCSLys indicates the novelty of these two amino acids as alternative to the available canonical amino acids.

Novel biotin linker with alkyne and amino groups for chemical labelling of a target protein of a bioactive small molecule.

We synthesized a novel linker (1) with biotin, alkyne and amino groups for the identification of target proteins using a small molecule that contains an azide group (azide probe). The alkyne in the linker bound the azide probe via an azide-alkyne Huisgen cycloaddition. A protein cross-linker effectively bound the conjugate of the linker and an azide probe with a target protein. The covalently bound complex was detected by western blotting. Linker 1 was applied to a model system using an abscisic acid receptor, RCAR/PYR/PYL (PYL). Cross-linked complexes of linker 1, the azide probes and the target proteins were successfully visualized by western blotting. This method of target protein identification was more effective than a previously developed method that uses a second linker with biotin, alkyne, and benzophenone (linker 2) that acts to photo-crosslink target proteins. The system developed in this study is a method for identifying the target proteins of small bioactive molecules and is different from photo-affinity labelling.

Development of a Ga-68 labeled PET tracer with short linker for prostate-specific membrane antigen (PSMA) targeting.

Glu-Urea-Lys (GUL) derivatives have been reported as prostate-specific membrane antigen (PSMA) agent. We developed derivatives of GUL conjugated with NOTA or DOTA via a thiourea linker and tested their feasibility as PSMA imaging agents after labeling with 68Ga. NOTA-GUL and DOTA-GUL were synthesized and labeled with 68Ga using generator-eluted 68GaCl3 in 0.1 M HCl in the presence of 1 M NaOAc at pH 5.5. The stabilities of 68Ga-labeled compounds in human serum were tested at 37.5 °C. A competitive binding assay was performed using the PSMA-positive prostate cancer cell line 22Rv1 and [125I]MIP-1072 (PSMA-specific binding agent) as a tracer. Biodistribution and micro-PET studies were performed using 22Rv1-xenograft BALB/c nude mice. The radiolabeling efficiency of NOTA-GUL (>99%) was higher than that of DOTA-GUL (92%). The IC50 of Ga-NOTA-GUL was 18.3 nM. In the biodistribution study, tumor uptake of 68Ga-NOTA-GUL (5.40% ID/g) was higher than that of 68Ga-DOTA-GUL (4.66% ID/g) at 1 h. Tumor/muscle and tumor/blood uptake ratios of 68Ga-NOTA-GUL (31.8 and 135, respectively) were significantly higher than those of 68Ga-DOTA-GUL (16.1 and 31.1, respectively). The tumor/kidney uptake ratio of 68Ga-NOTA-GUL was 3.4-fold higher than that of 68Ga-DOTA-GUL. 68Ga-NOTA-GUL showed specific uptake to PSMA positive tumor xenograft and was blocked by co-injection of the cold ligand. In conclusion, we successfully synthesized 68Ga-NOTA-GUL and 68Ga-DOTA-GUL for prostate cancer imaging. 68Ga-NOTA-GUL showed better radiochemical and biodistribution results. 68Ga-NOTA-GUL may be a promising PSMA targeting radiopharmaceutical.

Synthesis and Deployment of an Elusive Fluorovinyl Cation Equivalent: Access to Quaternary α-(1'-Fluoro)vinyl Amino Acids as Potential PLP Enzyme Inactivators.

Developing specific chemical functionalities to deploy in biological environments for targeted enzyme inactivation lies at the heart of mechanism-based inhibitor development but also is central to other protein-tagging methods in modern chemical biology including activity-based protein profiling and proteolysis-targeting chimeras. We describe here a previously unknown class of potential PLP enzyme inactivators; namely, a family of quaternary, α-(1'-fluoro)vinyl amino acids, bearing the side chains of the cognate amino acids. These are obtained by the capture of suitably protected amino acid enolates with ß,ß-difluorovinyl phenyl sulfone, a new (1'-fluoro)vinyl cation equivalent, and an electrophile that previously eluded synthesis, capture and characterization. A significant variety of biologically relevant AA side chains are tolerated including those for alanine, valine, leucine, methionine, lysine, phenylalanine, tyrosine, and tryptophan. Following addition/elimination, the resulting transoid α-(1'-fluoro)-ß-(phenylsulfonyl)vinyl AA-esters undergo smooth sulfone-stannane interchange to stereoselectively give the corresponding transoid α-(1'-fluoro)-ß-(tributylstannyl)vinyl AA-esters. Protodestannylation and global deprotection then yield these sterically encumbered and densely functionalized quaternary amino acids. The α-(1'-fluoro)vinyl trigger, a potential allene-generating functionality originally proposed by Abeles, is now available in a quaternary AA context for the first time. In an initial test of this new inhibitor class, α-(1'-fluoro)vinyllysine is seen to act as a time-dependent, irreversible inactivator of lysine decarboxylase from Hafnia alvei. The enantiomers of the inhibitor could be resolved, and each is seen to give time-dependent inactivation with this enzyme. Kitz-Wilson analysis reveals similar inactivation parameters for the two antipodes, L-α-(1'-fluoro)vinyllysine (Ki = 630 ± 20 µM; t1/2 = 2.8 min) and D-α-(1'-fluoro)vinyllysine (Ki = 470 ± 30 µM; t1/2 = 3.6 min). The stage is now set for exploration of the efficacy of this trigger in other PLP-enzyme active sites.

A strong developmental isotope effect in Caenorhabditis elegans induced by 5,5-deuterated lysine.

Effects exerted by heavy isotope substitution in biopolymers on the functioning of whole organisms have not been investigated. We report on the decrease of permissive temperature of nematodes fed with bacteria containing 5,5-D2-lysine. We synthesized 5,5-dideuterolysine and, taking advantage of lysine being an essential amino acid, showed that C. elegans with modified lysine poorly develop from larvae into fertile adult hermaphrodites. This effect occurs only at high temperature within the permissible range for C. elegans (25 °C) and completely vanishes at 15 °C. The only known metabolic involvement of C5 in lysine is in post-translational modification through lysyl hydoxylases. Indeed, siRNA experiments showed that deficiency of let-268/plod lysyl-hydroxylase/glycosydase further amplifies the isotope effect making it apparent even at 20 °C, whereas control siRNAs as well as another lysyl-hydroxylase (psr-1/jmjdD) siRNA do not. We report for the first time that a site-specific deuteration may strongly affect the development of the whole animal organism especially under the conditions of deficiency of the corresponding enzyme. These findings provide the basis for our ongoing efforts to employ isotope effects for fine tuning of metabolic pathways to mitigate pathological processes.

An improved synthesis of the radiolabeled prostate-specific membrane antigen inhibitor, [(18) F]DCFPyL.

The radiosynthesis of [(18) F]DCFPyL on 2 distinct automated platforms with full regulatory compliant quality control specifications is described. The radiotracer synthesis was performed on a custom-made radiofluorination module and the Sofie Biosciences ELIXYS. The radiofluorination module synthesis was accomplished in an average of 66 minutes from end of bombardment with an average specific activity at end of synthesis (EOS) of 4.4 TBq/µmol (120 Ci/µmol) and an average radiochemical yield of 30.9% at EOS. The ELIXYS synthesis was completed in an average of 87 minutes with an average specific activity of 2.2 TBq/µmol (59.3 Ci/µmol) and an average radiochemical yield of 19% at EOS. Both synthesis modules produced large millicurie quantities of [(18) F]DCFPyL while conforming to all standard US Pharmacopeia Chapter <823> acceptance testing criteria.

Effect of charged amino acid side chain length on lateral cross-strand interactions between carboxylate- and guanidinium-containing residues in a ß-hairpin.

ß-Sheet is one of the major protein secondary structures. Oppositely charged residues are frequently observed across neighboring strands in antiparallel sheets, suggesting the importance of cross-strand ion pairing interactions. The charged amino acids Asp, Glu, Arg, and Lys have different numbers of hydrophobic methylenes linking the charged functionality to the backbone. To investigate the effect of side chain length of guanidinium- and carboxylate-containing residues on lateral cross-strand ion pairing interactions at non-hydrogen-bonded positions, ß-hairpin peptides containing Zbb-Agx (Zbb = Asp, Glu, Aad in increasing length; Agx = Agh, Arg, Agb, Agp in decreasing length) sequence patterns were studied by NMR methods. The fraction folded population and folding energy were derived from the chemical shift deviation data. Peptides with high fraction folded populations involved charged residue side chain lengths that supported high strand propensity. Double mutant cycle analysis was used to determine the interaction energy for the potential lateral ion pairs. Minimal interaction was observed between residues with short side chains, most likely due to the diffused positive charge on the guanidinium group, which weakened cross-strand electrostatic interactions with the carboxylate side chain. Only the Aad-Arg/Agh interactions with long side chains clearly exhibited stabilizing energetics, possibly relying on hydrophobics. A survey of a non-redundant protein structure database revealed that the statistical sheet pair propensity followed the trend Asp-Arg < Glu-Arg, implying the need for matching long side chains. This suggested the need for long side chains on both guanidinium-bearing and carboxylate-bearing residues to stabilize the ß-hairpin motif.

Development of orthogonally protected hypusine for solid-phase peptide synthesis.

An orthogonally protected hypusine reagent was developed for solid-phase synthesis of hypusinated peptides using the Fmoc/t-Bu protection strategy. The reagent was synthesized in an overall yield of 27% after seven steps from Cbz-Lys-OBzl and (R)-3-hydroxypyrrolidin-2-one. The side-chain protecting groups (Boc and t-Bu) are fully compatible with standard Fmoc chemistry and can be readily removed during the peptide cleavage step. The utility of the reagent was demonstrated by solid-phase synthesis of hypusinated peptides.

Synthesis and inhibitory activity of substrate-analog fructosyl peptide oxidase inhibitors.

Fructosyl peptide oxidases (FPOXs) play a crucial role in the diagnosis of diabetes. Their main function is to cleave fructosyl amino acids or fructosyl peptides into glucosone and the corresponding amino acids/dipeptides. In this study, the substrate-analog FPOX inhibitors 1a-c were successfully designed and synthesized. These inhibitors mimic N(α)-fructosyl-L-valine (Fru-Val), [N(α)-fructosyl-L-valyl]-L-histidine (Fru-ValHis), and N(ε)-fructosyl-L-lysine (εFru-Lys), respectively. The secondary nitrogen atom in the natural substrates, linking fructose and amino acid or dipeptide moieties, was substituted in 1a-c with a sulfur atom to avoid enzymatic cleavage. Kinetic studies revealed that 1a-c act as competitive inhibitors against an FPOX obtained from Coniochaeta sp., and Ki values of 11.1, 66.8, and 782 µM were obtained for 1a-c, respectively.

Direct access to site-specifically phosphorylated-lysine peptides from a solid-support.

Phosphorylation is a key process for changing the activity and function of proteins. The impact of phospho-serine (pSer), -threonine (pThr) and -tyrosine (pTyr) is certainly understood for some proteins. Recently, peptides and proteins containing N-phosphorylated amino acids such as phosphoarginine (pArg), phosphohistidine (pHis) and phospholysine (pLys) have gained interest because of their different chemical properties and stability profiles. Due to its high intrinsic lability, pLys is the least studied within this latter group. In order to gain insight into the biological role of pLys, chemical and analytical tools, which are compatible with the labile P(=O)-N bond, are highly sought-after. We recently reported an in-solution synthetic approach to incorporate pLys residues in a site-specific manner into peptides by taking advantage of the chemoselectivity of the Staudinger-phosphite reaction. While the in-solution approach allows us to circumvent the critical TFA cleavage, it still requires several transformations and purification steps to finally deliver pLys peptides. Here we report the synthesis of site-specific pLys peptides directly from a solid support by using a base labile resin. This straightforward and highly efficient approach facilitates the synthesis of various site-specific pLys-containing peptides and lays the groundwork for future studies about this elusive protein modification.

Rapid and scalable synthesis of innovative unnatural α,ß or γ-amino acids functionalized with tertiary amines on their side-chains.

We report a selective ruthenium catalyzed reduction of tertiary amides on the side chain of Fmoc-Gln-OtBu derivatives, leading to innovative unnatural α,ß or γ-amino acids functionalized with tertiary amines. Rapid and scalable, this process allowed us to build a library of basic unnatural amino acids at the gram-scale and directly usable for liquid- or solid-phase peptide synthesis. The diversity of available tertiary amines allows us to modulate the physicochemical properties of the resulting amino acids, such as basicity or hydrophobicity.

Genetic encoding of the post-translational modification 2-hydroxyisobutyryl-lysine.

We report the synthesis and genetic encoding of a recently discovered post-translational modification, 2-hydroxyisobutyryl-lysine, to the genetic code of E. coli. The production of homogeneous proteins containing this amino acid will facilitate the study of modification in full-length proteins.

Short one-pot chemo-enzymatic synthesis of L-lysine and L-alanine diblock co-oligopeptides.

Amphiphilic diblock co-oligopeptides are interesting and functional macromolecular materials for biomedical applications because of their self-assembling properties. Here, we developed a synthesis method for diblock co-oligopeptides by using chemo-enzymatic polymerization, which was a relatively short (30 min) and efficient reaction (over 40% yield). Block and random oligo(L-lysine-co-L-alanine) [oligo(Lys-co-Ala)] were synthesized using activated papain as enzymatic catalyst. The reaction time was optimized according to kinetic studies of oligo(L-alanine) and oligo(L-lysine). Using (1)H NMR spectroscopy and matrix-assisted laser desorption/ionization time-of-flight mass spectrometry, we confirmed that diblock and random co-oligopeptides were synthesized. Optical microscopy further revealed differences in the crystalline morphology between random and block co-oligopeptides. Plate-like, hexagonal, and hollow crystals were formed due to the strong impact of the monomer distribution and pH of the solution. The different crystalline structures open up interesting possibilities to form materials for both tissue engineering and controlled drug/gene delivery systems.

A new HPLC-based assay for the measurement of fructosamine-3-kinase (FN3K) and FN3K-related protein activity in human erythrocytes.

BACKGROUND: An impact on glycation, and possibly on diabetic complications, is attributed to fructosamine-3-kinase (FN3K) and its related protein (FN3K-RP) because they degrade Amadori compounds in vivo. Little is known about individual differences in FN3K-RP activity, which might contribute to an individual risk for diabetic complications. METHODS: An HPLC-based activity assay for FN3K-RP in erythrocytes with the substrate N-α-hippuryl-N-ε-psicosyllysine was developed. The activities of FN3K and FN3K-RP were also analysed in erythrocytes of 103 consecutive participants of a health-care survey amongst a high-risk group for diabetes. The potential associations of these activities with the subjects' health background (anthropometric data, glucose tolerance and HbA1c, blood lipids, history of metabolic diseases in the subjects and their families, and medication) were examined. RESULTS: The interindividual variability of FN3K-RP is less pronounced than that of FN3K [60-135 vs. 2.8-12.5 mU/g haemoglobin (Hb)]. No correlations with age, sex, body weight, blood cholesterol, or plasma glucose in an oral glucose tolerance test were observed. Subjects with kidney disease had higher activity of mainly FN3K-RP [111±15 vs. 98±18 mU/g Hb, mean±standard deviations (SDs), n=16 vs. 87, p=0.009], whereas subjects whose parents or siblings had a stroke showed lower FN3K activity (6.2±1.6 vs. 7.1±1.8 mU/g Hb, mean±SD, n=24 vs. 66, p=0.040). CONCLUSIONS: There is a likely impact of FN3K and FN3K-RP on the glycation cascade in vivo with potential positive and negative effects. The new screening method enables further studies to elucidate the function and importance of FN3K-RP.

A click-and-release pyrrolysine analogue.

What's the catch? A pyrrolysine analogue bearing a terminal alkyne and an ester functionality can be incorporated into recombinant proteins and render them amenable to capture by the click reaction and subsequent release through ester hydrolysis. The utility of this pyrrolysine-inspired technology is demonstrated for the identification of SUMOylation sites.