Isolation, identification, and characterization of a palladium complex in the catalytic deprotection of a protected peptide.

The final catalytic deprotection in the large scale synthesis of thymopentin (Arg-Lys-Asp-Val-Tyr) produced an impurity which had not previously been observed. Isolation by preparative HPLC and spectroscopic characterization led to a postulated structure of the impurity as the 1:1 thymopentin-palladium complex. A complex corresponding to the proposed structure was independently synthesized and shown to have identical chromatographic and spectroscopic properties with the isolated material. Proton and carbon (13) NMR were used to determine the coordination sites of the peptide with palladium. The susceptibility of the complex to hydrogenation indicated a possible source for its formation.

19F nuclear magnetic resonance as a probe of structural transitions and cooperative interactions in heavy meromyosin.

An 19F NMR probe has been attached to the reactive sulfhydryl SH1 of the globular heads of rabbit skeletal heavy meromyosin. It serves as a sensitive monitor of the conformational state of the heads of heavy meromyosin in a manner similar to that seen for subfragment-1 (Shriver, J.W., and Sykes, B.D. (1982) Biochemistry 21, 3022-3028; Tollemar, U., Cunningham, K., and Shriver, J.W. (1986) Biochim. Biophys. Acta 873, 243-251). The NMR spectra indicate that there are at least two states for the heads in the SH1 region. The energetics of the interconversion of the two states of heavy meromyosin (HMM) differs significantly from that of S-1. In HMM in the absence of divalent cations, there are two reversible paths between the low temperature and high temperature states with a hysteresis-like behavior. One path is consistent with the head groups behaving independently and similar to S-1 alone. The second path indicates a coupling of the globular head region observed in S-1 with a second region forming a distinctly different cooperative unit. Upon addition of Ca(II) the hysteresis effect is lost and only the second cooperative unit is observed. Two explanations are offered for these results: the globular heads in HMM may couple with the S-2 segment, or the two globular heads of HMM may couple to form a larger cooperative unit. The ability to stabilize the larger cooperative unit with a divalent metal ion implicates a role for the LC2 light chain in coupling regions of the myosin molecule.