The mass-driven assembly of spectrin dimers to form tetramers involves two equal head-to-head alpha-beta associations and requires at least 30 degrees C for interconversion to occur readily. In this paper, the properties of tetramer formation were investigated using two complementary univalent peptides (the alpha I domain and beta monomers). Since the alpha I domain lacks an essential nucleation site required for side-to-side (lateral) heterodimer assembly [Speicher et al. (1992) J. Biol. Chem. 267, 14775-14782], these two peptides can only assemble head-to-head at a single site. This head-to-head assembly readily occurs at lower temperatures, indicating the temperature barrier for dimer-tetramer interconversion is caused by a conformational constraint of the dimer. This constraint, a closed hairpin loop, is released when the laterally associated partner is removed. The univalent alpha I-beta binding affinity at 37 degrees C (Ka = 1.4 x 10(5) M-1) is similar to the dimer-tetramer association constant at the same temperature. As the temperature is decreased from 37 to 0 degrees C, the alpha I-beta binding affinity increases about 32-fold. In contrast with head-to-head associations involving dimers, the second-order rate constants of two complementary univalent peptides (i.e., alpha I and beta) are dramatically higher, and the estimated activation energy (about 50 kJ mol-1) is about 5-fold lower. An open dimer conformation is an obligatory high-energy intermediate required for dimer-tetramer interconversion, and opening the dimer hairpin loop contributes about 190 kJ mol-1 to the activation energy for tetramer association.(ABSTRACT TRUNCATED AT 250 WORDS)
The alpha subunit of ovine lutropin can be nicked with the endoproteinase Arg-C to give a single cleavage of the Arg46-Ser47 peptide bond. Following reduction by sulfitolysis, the N-terminal (residues 1-46) and C-terminal (residues 47-96) fragments can be separated and then recombined and reoxidized to yield a reconstituted nicked alpha that binds to the beta subunit but exhibits only 2-3% of the receptor-binding potency of intact lutropin. We have investigated nicked alpha, the two separated fragments, and reconstituted nicked alpha by circular dichroic spectroscopy and compared the spectra with those of intact alpha and reduced, reoxidized intact alpha. Between 200 and 225 nm the spectra of the two intact preparations are similar, as are the spectra of the two nicked preparations. However, the extremum negative ellipticities of the nicked preparations are substantially less than those of the intact preparations between 210 and 220 nm, indicating a loss in secondary structure accompanying cleavage of the Arg46-Ser47 bond. The sum of the spectra of the two fragments is significantly different from that of reconstituted nicked alpha, showing that the secondary structures in the isolated fragments are quite different from that of the reconstituted nicked protein. Reduced receptor binding by lutropin preparations containing a nicked alpha subunit may be attributable in part to the loss of secondary structure, probably helicity.
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