Histidine

Summary

Histidine (symbol His or H) is an essential amino acid that is used in the biosynthesis of proteins. It contains an α-amino group (which is in the protonated –NH3+ form under biological conditions), a carboxylic acid group (which is in the deprotonated –COO− form under biological conditions), and an imidazole side chain (which is partially protonated), classifying it as a positively charged amino acid at physiological pH. Initially thought essential only for infants, it has now been shown in longer-term studies to be essential for adults also. It is encoded by the codons CAU and CAC. Histidine was first isolated by Albrecht Kossel and Sven Gustaf Hedin in 1896. It is also a precursor to histamine, a vital inflammatory agent in immune responses. The acyl radical is histidyl. Properties of the imidazole side chain The conjugate acid (protonated form) of the imidazole side chain in histidine has a pKa of approximately 6.0. Thus, below a pH of 6, the imidazole ring is mostly pr

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The formation of supramolecular structures is a central issue in bio- and nanotechnology and therein plays an important role for many novel developments such as biocompatible materials for integrating living cells or coating for implantable sensing devices as well as for designing smart molecular sensor surfaces for miniaturized bioanalytical techniques. The main focus of this thesis is the investigation of polypeptide layers on surfaces, in particular the formation of self-assembled monolayers (SAMs). SAMs made of long hydrocarbon chains or aromatic molecules comprising surface active and other functional groups have been deeply characterized over decades. Surprisingly, peptide SAMs did not meet the same strong interest despite their great potential in several areas. Natural (20) and artificial amino acids with different physical and chemical properties offer a plethora of novel possibilities to design coating of solid surfaces. In fact their combination in simple oligopeptide sequences provides a huge number of molecular components for the formation of SAMs. Control of SAM features such as density, flexibility, adaptability, interface properties, by tailoring the amino acid sequence opens a new route to manifold applications ranging from fundamental research to nano- and biotechnology. In this thesis different and complementary techniques have been used to investigate the self-assembling ability of polypeptides on surfaces with different physical and chemical properties. Infrared spectroscopy and circular dichroism allowed the determination of the peptide secondary structure on surfaces and in solution. Surface plasmon resonance provided the optical thicknesses of peptide SAMs on gold whereas contact angle measurements have been used to characterize their interfacial properties. In the first part of the thesis, a series of hydrophobic peptides (Ac-Cys-Alax-CONH2, x=3-6) have been self assembled on gold via the thiol group present in the cysteine. The main interest was whether these peptides formed densely packed SAMs with a defined secondary structure within the layer and how the properties of such SAMs depended on the length of the polypeptide backbone. The second part concerns the study of the interactions of an amphipathic helical peptide with various functionalized substrates. The aim was to investigate whether a proper design of the peptide could be used to predetermine its secondary structure on the substrate and whether the orientation of the peptide on the surface could be directly controlled via certain parameters of the surrounding medium. Since the hydrophilic residues of the peptide are histidines, a particular effort was spent in characterizing the peptide adsorption on substrates exposing nitrilotriacetic acid (NTA) moieties. Once established that the adsorption process did not alter its helical structure, the peptide was adsorbed on a substrate exposing two different functional groups: NTA, that could interact with the histidine residues, and methyl groups, that could interact with the hydrophobic ones. The goal was to bind the peptide in different orientation to the same substrate, exploiting the particular spatial distribution of its residues. The third part of this thesis concern the formation of nano- and micro-sized fibrils through molecular self-assembly of simple oligopeptides and protected amino acids. Such systems were chosen as models to investigate the role of the different driving forces in the formation of fibrillar structures. The aromatic protecting group being fixed, it could be shown that the protected amino acids formed fibrils with different sizes and morphologies, or did not form fibrils at all, depending on how strongly their side chains interact. The possibility of forming fibrils by using protected amino acids is of major importance not only in bio-related field but also in organic nanotechnology.

EPFL2008

Metal-based chemosensors for amino acids, peptides, and nucleotides

Andrey Buryak

An organometallic 4d transition metal complex [CpRhCl2]2, together with commercially available dyes, was used to construct indicator displacement assays (IDAs) for the detection of peptides, amino acids, and nucleotides. The combination of the CpRh complex with the dye azophloxine was found to form a chemosensing ensemble for the sequence-selective detection of histidine- and methionine-containing peptides in water at neutral pH. A strong interaction of the rhodium complex with peptides bearing histidine or methionine residue in the position 1 or 2 allowed to detect these peptides down to a concentration of 0.3 µM. The same organometallic complex and three commercially available dyes were employed to compose an array of IDA chemosensors for the detection of natural amino acids. We found that the variation of the pH can effectively be used to modulate the selectivity of an IDA sensor. An excellent discrimination of 20 amino acids was achieved. The combination of [Cp*RhCl2]2 with the dyes gallocyanine, evans blue, and mordant yellow 10 forms a multicomponent indicator displacement assay (MIDA), which can be used to sense low millimolar concentrations of nucleotides and the pyrophosphate anion in buffered aqueous solution. Moreover, the MIDA allows to simultaneously determine the concentrations of adenosine triphosphate and pyrophosphate/cyclic adenosine monophosphate with a single UV-Vis measurement. In the second part of our work we investigated whether dynamic combinatorial libraries (DCLs) can be used for sensing purposes. We found that the dyes arsenazo I, methylcalcein blue, and glycine cresol red, in combination with the metal salts CuCl2 and NiCl2, form a DCL of differently colored metal-dye complexes. The addition of an analyte able to interact with a member(s) of such a library, results in a re-equilibraion easily detectable by UV-Vis spectroscopy. Using dipeptides as analytes we demonstrated that this way of sensing is very effective – even closely related peptides such as regio- (Ala-Phe vs. Phe-Ala) and stereo- (Phe-Ala vs. D-Phe-Ala) isomers can easily be discriminated. Additionally, we found that the identity of the best sensor depends on the problem to be addressed.

EPFL2007

Phage Selection of Bicyclic Peptide Ligands and Development of a New Peptide Cyclisation Method

Jeremy Touati

Bicyclic peptides binding to targets of interest can be isolated from combinatorial libraries using a phage display-based approach. In a first project of this thesis, we aimed at generating bicyclic peptide inhibitors of matrix metalloproteinases (MMPs), a family of proteases that share high structural similarities and have been difficult to target in a specific manner. From phage-encoded combinatorial libraries, we isolated a bicyclic peptide that inhibits specifically the gelatinase MMP-2 with a Ki of 2 μM. This inhibitor was less potent than the best peptidic MMP-2 inhibitor, the linear APP-derived inhibitory peptide (Ki = 13 nM). However, due to its conformational constraint, the bicyclic peptide is expected to be significantly more stable and hence more suitable for applications in biological systems. It may be used as a research tool alternatively to the broadly applied monocyclic peptide MMP-2 inhibitor CTT which is less potent (Ki of 142 μM). If affinity matured, the bicyclic peptide MMP-2 inhibitor might even be developed into an anti-cancer therapeutic. In a second project, bicyclic peptide binders to the centriolar protein SAS-6 were generated. SAS-6 plays an important structural role in centrioles and bicyclic peptide binders are currently applied in cellular assays by the laboratory of Professor Pierre Gönczy (EPFL) to study the process of centriole formation. In a third project of this thesis, we established an enzymatic method to selectively cyclise peptides with unprotected side chains using a transglutaminase (TGase). TGases catalyse the formation of stable amide bonds between the side chains of glutamine and primary amines. They have been used extensively in biotechnological applications to cross-link peptides and proteins or to attach labels to proteins. We found that the microbial transglutaminase (MTGase) of Streptomyces mobaraensis can cyclise quantitatively peptides with an N- terminal glutamine-donor sequence and a C-terminal lysine residue in an intramolecular reaction. Experiments with minimised glutamine-donor substrates revealed that peptides with only an Ala-Leu dipeptide N-terminal to the glutamine and a randomly chosen peptide between the glutamine and lysine residues are efficiently cyclised. By combining the MTGase-based cyclisation strategy with a chemical thiol-based cyclisation reaction, we were able to generate tricyclic peptide structures. It remains to be tested if this method can be applied to cyclise combinatorial peptide libraries on the surface of phage. In a fourth and last project, we developed a method to follow qualitatively and quantitatively chemical or enzymatic modifications applied to peptides displayed on phage. In this method, peptides on phage were chemically modified, cleaved off by a protease, purified, concentrated and analysed by mass spectrometry. The method will help to assess new reactions applied to phage peptides such as the MTGase-based enzymatic cyclisation reaction.

EPFL2012