Elemental mapping in fossil tooth root section of Ursus arctos by laser ablation inductively coupled plasma mass spectrometry (LA-ICP-MS).

Laser ablation inductively coupled plasma mass spectrometry (LA-ICP-MS) was used to map the matrix (Ca, P) and trace (Ba, Sr, Zn) elements in the root section of a fossilized brown bear (Ursus arctos) tooth. Multielemental analysis was performed on a (2.5 × 1.5)cm(2) area. For elemental distribution, a UP 213 laser ablation system was coupled either with a quadrupole or a time of flight ICP-MS. The cementum and dentine on the slice of the sample surface were clearly distinguishable, especially changes in elemental distribution in the summer and winter bands in the fossil root dentine. Migration and diet of U. arctos were determined on the basis of fluctuations in Sr/Zn ratio and their contents. Quantification was accomplished with standard reference material of bone meal (NIST 1486) and by the use of electron microprobe analysis (EMPA). Changes in Sr/Zn and Sr/Ba ratios relating to the season, and composition of food during the lifetime of the animal are discussed on basis of analysis of light stable isotopes. It was observed that there was an increase in the Sr/Zn ratio during the winter season caused by a reduction of food intake during hibernation. Above mentioned inferences drawn from elemental data obtained by LA-ICP-MS were confirmed independently by determination of carbon, nitrogen and strontium isotopes. Moreover, diagenesis and its interfering influence on the biogenic composition of cementum and dentine were resolved. According to the distribution and/or content of the element of interest, post-mortem alterations were revealed. Namely, U, Na, Fe, Mg and F predicate about the suitability of the selected area for determination of migration and diet.

A study of Cu turnover in proteins of the visceral complex of Littorina littorea by stable isotopic analysis using coupled HPLC-ICP-MS.

A two-dimensional HPLC system, tandemly coupled to an ICP-MS, has been used to study copper accumulation and turnover in the visceral complex cytosol of the gastropod, Littorina littorea. Animals were exposed for 8 weeks to NTA-buffered seawater containing stable isotopic 65Cu and then transferred to media containing stable isotopic 63Cu. The free ion activity of each isotope was maintained at 10(-11) M. Size exclusion (SE) HPLC showed Cu associated with haemocyanin (HC) and metallothionein-like (MT) proteins in two ligand pools with apparent molecular weights of >300 kDa and approximately 17 kDa, respectively. The MT pool was inducible by Cu, could assimilate the metal from both intrinsic and extrinsic sources and showed a higher rate of Cu accumulation and turnover than the HC pool. The induction of this pool also caused the sequestration and cytosolic redistribution of Zn, Cd, Pb, Mn and Co. Further fractionation of the MT pool by ion-exchange (IE) HPLC revealed that the Cu was associated with a single, major isoform of the protein that was Cu inducible and also bound trace quantities of Zn and Pb. A number of additional metal containing proteins were also resolved by IE. the most prominent of which also bound Pb, Mn and minor quantities of Zn. The significance of these findings in metal homeostasis and detoxification is discussed.

Metalloprotein separation and analysis by directly coupled size exclusion high-performance liquid chromatography inductively coupled plasma mass spectroscopy.

The feasibility of using directly coupled size exclusion high-performance liquid chromatography inductively coupled plasma mass spectroscopy (HPLC/ICP-MS) for the separation and subsequent elemental analysis of metalloproteins in biological samples has been studied. Data, on up to eight elements, was acquired simultaneously and the reconstructed elemental profiles from the chromatographed samples were quantified by flow injection analysis. Absolute and relative detection limits, reproducibility, operational dynamic range, and linearity of response were initially evaluated by analyzing standards of metallothionein protein of known elemental composition for Cd, Zn, and Cu. There was evidence of displacement of Zn from the protein during chromatography and the substitution of Cu sequestered from the mobile phase. Cd associated with the protein was fully recovered during chromatography. Memory effects, due to protein adsorption to the glassware in the torch box, were minimal and there was no degradation of the resolution of the chromatographed peak during extended transport through the HPLC/ICP-MS interface. The versatility of the technique has been demonstrated by the quantitative multi-element analysis of cytosolic metal-binding proteins separated from the polychaete worm Neanthes arenaceodentata. Fidelity of analysis has been demonstrated by two independent procedures: first, by comparing the elemental profiles obtained by directly aspirating the HPLC eluant into the ICP-MS to those obtained by collecting fractions and quantifying the metal content of the proteins in the conventional analytical mode; second, by comparing the stable isotopic profiles for 114Cd obtained by simultaneous ICP-MS analysis with radiometric profiles of 109Cd obtained by counting radioactivity associated with collected fractions.(ABSTRACT TRUNCATED AT 250 WORDS)

A rapid, routine technique for the X-ray microanalysis of microincinerated cryosections: an SEM study of inorganic deposits in tissues of the marine gastropod Littorina littorea (L.).

A procedure is described that prepares chemically untreated biological sections for X-ray microanalysis in the scanning electron microscope (SEM). The method aims to retain and localize labile components in tissue sections by a procedure that is both rapid and routine. Large quantities of fresh tissue can be processed for analysis within a single day. Thick cryosections are cut with a steel knife in a conventional cryostat, freeze-dried, and then ashed by either low or high temperature incineration procedures. Controlled microincineration attenuates the organic matrix to reveal sufficient surface relief for effective SEM of some cytological structure and microanalysis of the residual inorganic components. The detectability of various elements is enhanced because the relative concentrations in the residues are increased and the level of nonspecific background in the X-ray spectra is reduced. The technique is applied to different tissues from the visceral complex of the marine prosobranch Littorina littorea. In animals exposed to elevated levels of zinc it can be demonstrated tht the metal is localized both as an insoluble form in granules and as a labile form within the cytoplasm. Other metals, including magnesium, potassium, calcium, manganese, and iron, have been identified and localized. The effectiveness of this technique for retaining labile elements is compared, in outline, with that of conventional fixation procedures.