Cisplatin mediates selective downstream hydrolytic cleavage of Met-(Gly)(n)-His segments (n=1,2) in methionine- and histidine-containing peptides: the role of ammine loss trans to the initial Pt-S(Met) anchor in facilitating amide hydrolysis

Presence of short and cyclic peptides in Acacia and Ziziphus honeys may potentiate their medicinal values

Acacia honey is characterized by high nutritional, antioxidant, antibacterial and immuno-modulatory values. This work investigated the presence of short and cyclic peptides in Acacia and Ziziphus honey samples. Acacia honey samples (Acacia tortilis and Acacia hamulosa) and three Ziziphus honeys (Ziziphus spina-christi) were screened for their short and cyclic peptide contents using the LC-MS and the chemical structure databases. Moreover, the total protein content was determined using the Bradford method. The A. tortilis honey contained three short peptides; HWCC, DSST, and ECH, and the A. hamulosa honey sample contained five short peptides and one cyclic peptide. The short peptides of the A. hamulosa honey were Ac-GMGHG-OH (Ac-MGGHG-OH), Boc-R(Aloc)2-C(Pal)-OH, H-C (1)-NEt2·H-C (1)-NEt2, APAP (AAPP), and GAFQ (deamino-2-pyrid-4-yl-glycyl-dl-alanyl-dl-norvalyl-dl-asparagine). The cyclic peptide of the A. hamulosa honey was cyclo[Aad-RGD-d-F] (cyclo[Aad-Arg-Gly-Asp-d-Phe]). The Ziziphus honey was characterized by the presence of either Almiramide B or Auristatin-6-AQ. A. tortilis, A. hamulosa, and Ziziphus honeys are characterized by the presence of short and cyclic peptides which may contribute to their medicinal values.

Fast Amide Bond Cleavage Assisted by a Secondary Amino and a Carboxyl Group-A Model for yet Unknown Peptidases?

Unconstrained amides that undergo fast hydrolysis under mild conditions are valuable sources of information about how amide bonds may be activated in enzymatic transformations. We report a compound possessing an unconstrained amide bond surrounded by an amino and a carboxyl group, each mounted in close proximity on a bicyclic scaffold. Fast amide hydrolysis of this model compound was found to depend on the presence of both the amino and carboxyl functions, and to involve a proton transfer in the rate-limiting step. Possible mechanisms for the hydrolytic cleavage and their relevance to peptide bond cleavage catalyzed by natural enzymes are discussed. Experimental observations suggest that the most probable mechanisms of the model compound hydrolysis might include a twisted amide intermediate and a rate-determining proton transfer.

Influence of the amino acid side chain on peptide bond hydrolysis catalyzed by a dimeric Zr(iv)-substituted Keggin type polyoxometalate

Structurally different dipeptides were hydrolyzed by [{α-PW₁₁O₃₉Zr-(μ-OH)(H₂O)}₂]⁸⁻. The rate constants were dependent on bulkiness and chemical nature of the dipeptide.

A site-selective, irreversible inhibitor of the DNA replication auxiliary factor proliferating cell nuclear antigen (PCNA)

Proliferating cell nuclear antigen (PCNA) assumes an indispensable role in supporting cellular DNA replication and repair by organizing numerous protein components of these pathways via a common PCNA-interacting sequence motif called a PIP-box. Given the multifunctional nature of PCNA, the selective inhibition of PIP-box-mediated interactions may represent a new strategy for the chemosensitization of cancer cells to existing DNA-directed therapies; however, promiscuous blockage of these interactions may also be universally deleterious. To address these possibilities, we utilized a chemical strategy to irreversibly block PIP-box-mediated interactions. Initially, we identified and validated PCNA methionine 40 (M40) and histidine 44 (H44) as essential residues for PCNA/PIP-box interactions in general and, more specifically, for efficient PCNA loading onto chromatin within cells. Next, we created a novel small molecule incorporating an electrophilic di-chloro platinum moiety that preferentially alkylated M40 and H44 residues. The compound, designated T2Pt, covalently cross-linked wild-type but not M40A/H44A PCNA, irreversibly inhibited PCNA/PIP-box interactions, and mildly alkylated plasmid DNA in vitro. In cells, T2Pt persistently induced cell cycle arrest, activated ATR-Chk1 signaling and modestly induced DNA strand breaks, features typical of cellular replication stress. Despite sustained activation of the replication stress response by the compound and its modestly genotoxic nature, T2Pt demonstrated little activity in clonogenic survival assays as a single agent, yet sensitized cells to cisplatin. The discovery of T2Pt represents an original effort directed at the development of irreversible PCNA inhibitors and sets the stage for the discovery of analogues more selective for PCNA over other cellular nucleophiles.

Mechanism of peptide hydrolysis by co-catalytic metal centers containing leucine aminopeptidase enzyme: a DFT approach

In this density functional theory study, reaction mechanisms of a co-catalytic binuclear metal center (Zn1-Zn2) containing enzyme leucine aminopeptidase for two different metal bridging nucleophiles (H(2)O and -OH) have been investigated. In addition, the effects of the substrate (L-leucine-p-nitroanilide → L-leucyl-p-anisidine) and metal (Zn1 → Mg and Zn2 → Co, i.e., Mg1-Zn2 and Mg1-Co2 variants) substitutions on the energetics of the mechanism have been investigated. The general acid/base mechanism utilizing a bicarbonate ion followed by this enzyme is divided into two steps: (1) the formation of the gem-diolate intermediate, and (2) the cleavage of the peptide bond. With the computed barrier of 17.8 kcal/mol, the mechanism utilizing a hydroxyl nucleophile was found to be in excellent agreement with the experimentally measured barrier of 18.7 kcal/mol. The rate-limiting step for reaction with L-leucine-p-nitroanilide is the cleavage of the peptide bond with a barrier of 17.8 kcal/mol. However, for L-leucyl-p-anisidine all steps of the mechanism were found to occur with similar barriers (18.0-19.0 kcal/mol). For the metallovariants, cleavage of the peptide bond occurs in the rate-limiting step with barriers of 17.8, 18.0, and 24.2 kcal/mol for the Zn1-Zn2, Mg1-Zn2, and Mg1-Co2 enzymes, respectively. The nature of the metal ion was found to affect only the creation of the gem-diolate intermediate, and after that all three enzymes follow essentially the same energetics. The results reported in this study have elucidated specific roles of both metal centers, the nucleophile, indirect ligands, and substrates in the catalytic functioning of this important class of binuclear metallopeptidases.

Mass spectrometry evidence for cisplatin as a protein cross-linking reagent

Cisplatin is a potent anticancer drug, which functions by cross-linking adjacent DNA guanine residues. However within 1 day of injection, 65-98% of the platinum in the blood plasma is protein-bound. It is generally accepted that cisplatin binds to methionine and histidine residues, but what is often underappreciated is that platinum from cisplatin has a 2+ charge and can form up to four bonds. Thus, it has the potential to function as a cross-linker. In this report, the cross-linking ability of cisplatin is demonstrated by Fourier transform ion cyclotron resonance (FTICR) mass spectrometry (MS) with the use of standard peptides, the 16.8 kDa protein calmodulin (CaM), but was unsuccessful for the 64 kDa protein hemoglobin. The high resolution and mass accuracy of FTICR MS along with the high degree of fragmentation of large peptides afforded by collisionally activated dissociation (CAD) and electron capture dissociation (ECD) are shown to be a valuable means of characterizing cross-linking sites. Cisplatin is different from current cross-linking reagents by targeting new functional groups, thioethers, and imidazoles groups, which provides complementarity with existing cross-linkers. In addition, platinum(II) inherently has two positive charges which enhance the detection of cross-linked products. Higher charge states not only promote the detection of cross-linking products with less purification but result in more comprehensive MS/MS fragmentation and can assist in the assignment of modification sites. Moreover, the unique isotopic pattern of platinum flags cross-linking products and modification sites by mass spectrometry.

Cisplatin interaction with amino acids cysteine and methionine from gas phase to solutions with constant pH

This work is focused on the computational studies of reactions of hydrated forms of cisplatin with sulphur-containing amino acids cysteine and methionine. First, the appropriate model for solvation of the examined complexes was searched for. The suggested procedure employs the B3LYP density functional, 6-311++G(2df,2pd) basis set with Stuttgart-Dresden pseudopotentials on heavy atoms, the D-PCM solvation model and the UAKS cavity which uses more realistic NPA partial charges instead of formal partial charges for platinum ligands. In the second part this model is applied to the evaluation of the Legendre transformed reaction Gibbs free energy of cisplatin with cysteine and methionine in solution at constant pH.

On the many roles of NH3 ligands in mono- and multinuclear complexes of platinum

The role of the NH(3) ligands in the highly successful antitumour agents cisplatin and carboplatin is not fully understood. Suggestions that the ammonia ligands are involved in target recognition through hydrogen bond formation, e.g. with guanine-O6, have been questioned. Here, we review the roles and functions of NH(3) ligands of cis-PtCl(2)(NH(3))(2) and likewise of its trans-isomer in complexes with model nucleobases as well as other N-heterocyclic ligands. Specifically, their roles in hydrogen bonding interactions with nucleobases as well as anions, the influence on acid-base properties of co-ligands, their involvement in condensation reactions, as well as a variety of displacement reactions will be examined. As a result, it can be stated that the ammonia ligands in cis- and trans-Pt(II)(NH(3))(2) entities display additional features to those generally discussed in the last four decades since the discovery of the antitumour activity of cisplatin.

Peculiar mechanistic and structural features of the carboplatin-cytochrome c system revealed by ESI-MS analysis

Carboplatin (CPT), today the most important platinum(II) anticancer drug, manifests an extreme kinetic inertness, in vitro, at physiological pH; the actual mechanisms for its activation inside cells are still poorly understood. We show here that horse heart cytochrome c reacts with CPT, leading to the formation of stable platinum/protein adducts. The two major CPT-cytochrome c species resulting from the aforementioned reaction were characterised by electrospray ionisation mass spectrometry (ESI-MS). Notably, both these adducts have the ability to react with guanosine 5'-monophosphate (5'-GMP), giving rise to the respective cytochrome c-CPT-5'-GMP ternary complexes. Additional ESI-MS measurements on enzymatically cleaved cytochrome c adducts suggest that protein platination probably occurs at Met65. The mechanistic implications of these findings are discussed.