Metal remediation and preconcentration using immobilized short-chain peptides composed of aspartic acid and cysteine

Abstract

Short-chain peptides (two and seven residues) consisting of a glycine (Gly) attachment group and various combinations of cysteine (Cys) and/or aspartic acid (Asp) were synthesized by Fmoc solid phase peptide synthesis (SPPS) on Tentagel resin. One selected peptide was synthesized on controlled pore glass (CPG) for comparison. The objective was to evaluate metal binding capacities and selectivities of short-chain peptides when minor alterations in the amino acid sequences were made. Metal binding of Ni 2+, Cd 2+, Co 2+, and Mg 2+ to the synthesized peptides was evaluated using breakthrough curves from a packed microcolumn and flame atomic absorption spectrophotometry (FAAS) detection. Peptides composed primarily of Asp showed single metal capacities as large as 720 μmol metal/g Tentagel resin and 130 μmol metal/g CPG. Simultaneous elution of a multi-metal solution demonstrated that peptides possessing only two Cys residues and four Asp residues were sufficient to yield selective binding of Cd 2+ over Ni 2+ and Co 2+ similar to the selectivity of a six-Cys residue chain but with 60% more Cd 2+ capacity. Interestingly, peptides supported on Tentagel resin appeared to reach equilibrium with metal-containing influent flow rates of at most 2 ml/min (or a linear velocity of 11 cm/s) and is attributed to better mass transport with the resin than with the CPG. Conditional stability constants calculated for the six-Asp residue chain and each metal showed the majority of sites having a log K in the range of 4.6–4.8. The peptides studied were also able to efficiently preconcentrate solutions containing as little as 0.05 μg/ml Cd 2+ or Ni 2+ in an artificial seawater matrix. Uniquely, the seven residue peptides showed surprisingly high metal capacities and metal-to-residue binding ratios (reaching ∼1:2), and are an order of magnitude better than results previously obtained for longer chain polyamino acids (50–70 residues) attached to CPG via silane chemistry.