Dimerization of native myosin LC2(RLC)-free subfragment 1 from adult rabbit skeletal muscle.

We reinvestigated whether the native myosin LC2-free-subfragment 1 (S1) dimer exists by using viscometry, capillary electrophoresis, and laser light scattering. We found that the intrinsic viscosity of the monomer is [eta]m = 6.7 cm3/g and its translation diffusion coefficient is (c = 0) = 4.43 x 10(-)7 cm2/s. For the dimer, [eta]d = 19.8 cm3/g and (c = 0) = 2.54 x 10(-)7 cm2/s. Using the Svedberg equation and introducing the values of the sedimentation coefficients (5.05 S for the monomer and 6.05 S for the dimer), we find the following molecular weights: Mr,m = 108 000 Da and Mr,d = 213 000 Da, which agree well with previous determinations. Capillary electrophoresis successfully separated S1(A1) and S1(A2), in a monomer buffer, and S1(A1) and S1(A2) and a heterodimer S1(A1)-S1(A2), in a dimer buffer. An interesting feature of the monomer-dimer equilibrium is the presence of temperature transitions, whose positions and widths depend upon the buffer conditions. At low temperatures, a pure dimer was observed, whereas at high temperatures only the monomer was present. The dimerization site on both myosin and S1 is extremely labile.

Lithostathine, the presumed pancreatic stone inhibitor, does not interact specifically with calcium carbonate crystals.

Lithostathine (pancreatic stone protein, Reg protein) is, in addition to albumin, the major nonenzymatic protein of the pancreatic juice. It has been assumed to inhibit calcium carbonate precipitation and therefore to prevent stone formation in the pancreatic ducts. This function is, however, debatable. The assumption is based on the inhibition of in vitro crystal nucleation and growth by lithostathine. Considering that these phenomena occur only under certain critical conditions, we re-examined the question using a protein preparation where the purity and folding have been tested by mass spectroscopy and NMR in the absence of nonprotein contaminants. Under these conditions, we showed conclusively that lithostathine does not inhibit calcium carbonate nucleation and crystal growth. We demonstrated that previous findings on the alleged inhibition can be attributed to the uncontrolled presence of salts in the protein preparation used. Moreover, the affinity of lithostathine to calcite crystals, expressed as the half-life of bound iodinated protein in the presence of unlabeled competitor, was significantly lower than that of bovine serum albumin (8.8 and 11.2 h, respectively). Using glass microspheres instead of crystals did not significantly change the half-life of bound lithostathine (8.0 h). These findings are incompatible with the hypothesis of a specific interaction of lithostathine with calcium carbonate crystals. In conclusion, considering that components of pancreatic juice such as NaCl and phosphate ions are powerful inhibitors of calcium carbonate crystal growth, the mechanism of stone formation in pancreatic ducts must be reconsidered. The presence in normal pancreatic juice of small amounts of the 133-residue isoform of lithostathine (PSP-S1), which precipitates at physiological pH, should be noted, and the possibility should be considered that they form micro-precipitates that aggregate and are progressively calcified.

What function for human lithostathine?: structural investigations by three-dimensional structure modeling and high-resolution NMR spectroscopy.

Human lithostathine is a 144-residue protein, expressed in various organs and pathologies. Several biological functions have been proposed for this protein. Among others, inhibition of nucleation and growth of CaCO3 crystals in the pancreas and bacterial aggregation has retained attention, because lithostathine presents high sequence similarities with calcium-dependent (or C-type) lectins. To study its structure-function relationship and compare it with that of C-type lectins, we have built a model for lithostathine. This model is derived from the only two C-type lectins of known structures: rat mannose binding protein and human E-selectin. An original strategy, inspired by that proposed by Havel and Snow, was designed for model building. We have undertaken NMR studies on the natural protein. Although complete structure determination has not yet been achieved, the NMR studies did confirm the main characteristics of the model. From analysis of the proposed model, we concluded that lithostathine is not expected to present sugar- or calcium-binding properties. Therefore, the mechanisms of bacterial aggregation and inhibition of CaCO3 nucleation and growth have not yet been elucidated.