Cysteine ionizing groups

Some amino acids have additional ionizable groups in their side-chains. These may be acidic or potentially acidic (aspartic acid, glutamic acid, tyrosine, cysteine), or basic (lysine, arginine, histidine). We use the term potentially acidic to describe the phenol and thiol groups of tyrosine and cysteine respectively under physiological conditions, these groups are unlikely to be ionized. It is relatively easy to calculate the amount of ionization at a particular pH, and to justify that latter statement. 

We have shown the cysteine thiol group as uncharged. The pAfa for this group in cysteine is about 10.3, and application of the Henderson-Hasselbach equation (see Section 4.9) indicates there will be negligible ionization at pH 7. Nevertheless, under the influence of a suitable basic group, e.g. arginine pATa 12.5, ionization to thiolate may be possible. In such an environment, thiolate may act as the nucleophile in the mechanism. 

Two kinetic methods have been used to identify catalytic groups from pH profiles. First, the temperature coefficients of the pK values of the various ionizing groups differ considerably. Carboxyl and phosphate groups have A//jo values near zero, whereas histidine, cysteine, and tyrosine groups have values of... 

As the four microscopic constants cannot be determined by a titration curve, spectrophotometric analysis (UV absorption of R-S ) was necessary. The pX (8.65) of cysteine betaine (ionization of a thiol in the presence of a positive nitrogen) and the pK (8.75) of S-methyl cysteine (ionization of an amino group in the presence of neutral sulfur) closely mimic the and /c2 dissociation pathways and suggest that these values should be close to each other... 

Example Peptides often contain sulfur from cysteine. Provided there are at least two cysteines in the peptide molecule, the sulfur can be incorporated as thiol group (SH, reduced) or sulfur bridge (S-S, oxidized). Often, both forms are contained in the same sample. At ultrahigh-resolution, the contributions of these compositions to the same nominal m/z can be distinguished. The ultrahigh-resolution matrix-assisted laser desorption/ionization (MALDI) FT-ICR mass spectrum of native and reduced [D-Pen jenkephalin gives an example of such a separation (Fig. 3.25). [39] The left expanded view shows fully resolved peaks due to and C2 isotopomers of the native and the all- C peak of the reduced compound at m/z 648. The right expansion reveals the peak of the native plus the... 

There are at least three possibile ways in which the inhibitor can bind to the active site (1) formation of a sulfide bond to a cysteine residue, with elimination of hydrogen bromide [Eq. (10)], (2) formation of a thiol ester bond with a cysteine residue at the active site [Eq. (11)], and (3) formation of a salt between the carboxyl group of the inhibitor and some basic side chain of the enzyme [Eq. (12)]. To distinguish between these three possibilities, the mass numbers of the enzyme and enzyme-inhibitor complex were measured with matrix-assisted laser desorption ionization time-of-flight mass spectrometry (MALDI). The mass number of the native AMDase was observed as 24766, which is in good agreement with the calculated value, 24734. An aqueous solution of a-bromo-phenylacetic acid was added to the enzyme solution, and the mass spectrum of the complex was measured after 10 minutes. The peak is observed at mass number 24967. If the inhibitor and the enzyme bind to form a sulfide with elimination of HBr, the mass number should be 24868, which is smaller by about one... 

Similar calculations as above for the basic side-chain groups of arginine pK 12.48) and lysine pK 10.52), and the acidic side-chains of aspartic acid (pATa 3.65) and glutamic acid (pAfa 4.25) show essentially complete ionization at pH 7.0. However, for cysteine (pATa of the thiol group 10.29) and for tyrosine (pAfa of the phenol group 10.06) there will be negligible ionization at pH 7.0. 

An additional point should be noted from table 3.3. Whereas the amino acid side chains (R groups) that are normally charged at physiological pH are restricted to five amino acids (aspartic acid, glutamic acid, lysine, arginine, and sometimes histidine), a number of potentially ionizable R groups are part of other amino acids. These include cysteine, serine, threonine, and tyrosine. The ionization reac-... 

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