The requirement for cobalt of sheep grazed on cobalt-deficient pastures

Experimental proof is presented that cobalt injected intravenously or into the abomasum at the rate of 1 mg/day is without any measurable effect on the cobalt deficiency syndrome in sheep. Similarly, depot therapy with colloidal cobalt is of no benefit. It is confirmed that, to be effective, cobalt supplements must be introduced frequently into the rumen, by mouth or by direct injection; although administration by other routes leads to a considerable accumulation of cobalt in the tissues this does not reach the rumen in effective amounts, if at all. For sheep grazing grossly cobalt-deficient pastures the total intake of cobalt necessary to ensure optimum growth and haemoglobin production was found to be equivalent to almost precisely 0.08 mg/day when supplementary cobalt was provided three times each week; in growing lambs the requirement was greater. Analytical evidence is presented in support and the findings are discussed in relation to certain conclusions arrived at by others.

Protein aggregation. Studies of larger aggregates of C-phycocyanin

Aggregates of phycocyanin sedimenting at 17s, 22s and 27s are demonstrated to constitute more than 40% of crude blue-green-algal extracts, pH6.0 and I0.1, and are retained in highly purified preparations. Sedimentation-velocity studies of the large aggregates as a function of pH are reported. Sucrose-density-gradient experiments performed as a function of time of sedimentation indicate that: (1) with increasing time of sedimentation, the largest aggregates are dissipated at the leading protein boundary and the several phycocyanin species present are not completely resolved; (2) phycocyanin fractions with the largest aggregates exhibit the highest E(620)/E(280) ratio and the largest relative fluorescence efficiency. Gel-filtration experiments with Sephadex G-200 do not resolve the species completely, and reapplication of phycocyanin gel-filtration fractions to the column results in an elution pattern similar to the original, except that there is an enhancement of the allophycocyanin fraction and the amount of denatured protein. Increasing the sedimentation times in a sucrose density gradient also enhances the allophycocyanin fraction. Fluorescence results demonstrate that there are possibly three excitation maxima, one corresponding to the monomer (approx. 600mmu), one for higher aggregates (625-630mmu) and one for the allophycocyanin fraction (approx. 650mmu). Only a single fluorescence-emission band is detected, which is fairly symmetrical and which has a red shift with higher aggregation and with the appearance of allophycocyanin. The appearance of allophycocyanin may be correlated with the irreversible disaggregation of the largest phycocyanin species. It is suggested that the largest protein aggregates are in the size range of the biliprotein aggregates reported in electron microscopy of algal cells.

Protein aggregation. The effect of deuterium oxide on large protein aggregates of C-phycocyanin

The amount of 11s aggregate in phycocyanin, normally stimulated by hydrophobic forces, is dramatically increased by the presence of deuterium oxide. Proteins in which hydrophobic forces are not proposed as a mechanism for aggregation are unaffected by deuterium oxide. These observations are consistent with the lower critical micelle concentration reported for ionic detergents in deuterium oxide. Phycocyanin samples containing a majority of material sedimenting faster than 11s were also investigated in the presence of deuterium oxide with the following findings: the most rapidly sedimenting species in water buffer is 24s; in deuterium oxide more than 10% of the protein sediments at 67s and substantial amounts of other species with sedimentation coefficients larger than 24s are present. These large quantities of species sedimenting faster than 24s are found in deuterium oxide buffers from pD5.5 to 7.0. Sucrose-density-gradient studies in deuterium oxide at pD6.0 confirm the presence of large amounts of more rapidly sedimenting species. Spectrophotometric studies on fractions from the sucrose-density-gradient experiments indicate with the presence of higher aggregates a red shift of the visible-absorption maximum and an enhancement of the E(620)/E(280) ratio. Fluorescence-emission studies show a greater relative fluorescence efficiency for these higher aggregates and are consistent with the suggested enhancement of higher aggregates in deuterium oxide. The existence of phycocyanin aggregates of such a large size is suggested to be of importance in vivo, with phycocyanin playing a role as a structural protein.