Peiqun Zhang

The roles of serum selenium and selenoproteins on mercury toxicity in environmental and occupational exposure

Many studies have found that mercury (Hg) exposure is associated with selenium (Se) accumulation in vivo. However, human studies are limited. To study the interaction between Se and Hg, we investigated the total Se and Hg concentrations in body fluids and serum Se-containing proteins in individuals exposed to high concentrations of Hg. Our objective was to elucidate the possible roles of serum Se and selenoproteins in transporting and binding Hg in human populations. We collected data from 72 subjects: 35 had very low Hg exposure as evidenced by mean Hg concentrations of 0.91 and 1.25 ng/mL measured in serum and urine, respectively; 37 had high exposure (mean Hg concentrations of 38.5 and 86.8 ng/mL measured in serum and urine, respectively). An association between Se and Hg was found in urine (r = 0.625; p < 0.001) but not in serum. Hg exposure may affect Se concentrations and selenoprotein distribution in human serum. Expression of both selenoprotein P and glutathione peroxidase (GSH-Px) was greatly increased in Hg miners. These increases were accompanied by elevated Se concentrations in serum. In addition, selenoprotein P bound more Hg at higher Hg exposure concentrations. Biochemical observations revealed that both GSH-Px activity and malondialdehyde concentrations increased in serum of the Hg-exposed group. This study aids in the understanding of the interaction between Se and Hg. Selenoproteins play two important roles in protecting against Hg toxicity. First, they may bind more Hg through their highly reactive selenol group, and second, their antioxidative properties help eliminate the reactive oxygen species induced by Hg in vivo.

Distribution of some rare earth elements and their binding species with proteins in human liver studied by instrumental neutron activation analysis combined with biochemical techniques

Distribution patterns of three rare earth elements and their binding species with proteins in the human liver samples were studied by instrumental neutron activation analysis combined with biochemical techniques. It was indicated that La, Ce and Sm were highly concentrated in microsomes, although the total content of this fraction was the least among all of the liver organelles, which was similar with the behavior of Ca and Fe. More than 85% of La, Ce and Sm was present in the cytosolic protein fractions separated by ammonium sulfate and ethanol. It indicated that these elements were mainly incorporated into protein. It was also revealed by means of size-exclusion chromatography that at least three La-binding proteins (M-x: 335 +/- 50, 94.5 +/- 15.4, 13.6 +/- 3.8 kD), three Ce-binding proteins (M-w: 335 +/- 50, 85.1 +/- 12.0, 22.8 +/- 6.3 kD) and about four Sm-binding proteins (M-w: 335 +/- 70, 82.1 +/- 5.4, 32.3 +/- 5.8 and 13.6 +/- 4.5kD) were present in the supernatant fraction of human liver. Most of La, Ce and Sm were found in the high-molecular weight protein region

Detection of metalloproteins in human liver cytosol by synchrotron radiation X-ray fluorescence after sodium dodecyl sulphate polyacrylamide gel electrophoresis

An improved method of analysis of metals in protein bands with synchrotron radiation X-ray fluorescence (SRXRF) after sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) separation is introduced and applied to human liver cytosol. Through a step of drying the gel before SRXRF determination, the continuous background resulting mainly from the Compton-scattering of X-rays by the gel matrix was substantially reduced, and the detection of biological trace elements, such as Cu, Fe, and Zn in protein bands was thereby made possible. With the new procedure, six Zn-containing proteins with molecular weights (MWs) of 17.5, 20.5, 27, 35, 55, and 63 kDa, respectively were found in human liver cytosol, among which the 63 kDa Zn-containing band was shown to be the dominant form of zinc. In addition, at least four Fe containing proteins with MWs of 20, 23, 43, and 83.5 kDa, respectively, were present in the samples. The metal contents in some metalloproteins, such as the 63 kDa Zn-containing protein, the 23 and 83.5 kDa Fe-containing proteins, and a 22 kDa Cu-containing protein were more closely related to the metal level in the sample. It is demonstrated that the procedure could be widely used to further investigate metal-binding proteins in biological samples

Subcellular distribution of selenium and Se-containing proteins in human liver.

Selenium is an essential trace element in many living organisms. In the present paper, the subcellular distribution of selenium and Se-containing proteins in human liver samples, which were obtained from normal subjects who had an accidental death, was investigated by differential centrifugation and column chromatography. Selenium was mainly enriched in nuclei, mitochondria and cytosol. Almost half of Se existed in the nuclei due to their large amount in liver and high Se concentration. 15-30% of Se was found in small compounds with Mr<2000 in the liver components separated by dialysis. The average abundance of Se in small molecular mass species of whole-liver was 23.6%, which suggested most of Se associated with biological macromolecules. Eight kinds of Se-containing proteins with molecular mass of 335+/-20, 249+/-15, 106+/-11, 84.6+/-5.8, 70. 5+/-5.4, 45.6+/-1.5, 14.8+/-2.6, 8.5+/-1.2 kDa were found in the subcellular fractions of human liver. Among them the 335, 84.6 and 8. 5 kDa proteins were individually present in one subcellular fraction, whereas the others coexisted in two, three or four subcellular fractions. The most abundant Se-containing proteins, 70.5 and 14.8 kDa, accounted for 33.6% and 48.5% in the whole-liver soluble Se-containing protein, respectively. The former was enriched in cytosol and the latter was mainly present in nuclei and mitochondria.

Detection of metalloproteins in human liver cytosol by synchrotron radiation X-ray fluorescence combined with gel filtration chromatography and isoelectric focusing separation

Synchrotron radiation X-ray fluorescence (SRXRF) spectroscopy is an advanced method of quantitative multielemental analysis with space resolution of several microm and sensitivities in the microg g(-1) range. It can be used for keeping track of trace elements after an electrophoretic separation of biological samples. In this paper, proteins in human liver cytosol were separated with gel filtration chromatography and thin layer isoelectric focusing (IEF). The contents of metal ions in protein bands were determined by SRXRF. The results showed that in the molecular weight (MW) range of 10 approximately 25 kDa, there were at least 2 Zn-containing bands with isoelectric point (pI) of 5 approximately 6 and 6.2 approximately 7, respectively and about 11 Fe-containing proteins with pI of 4.4, 4.6, 4.8, 5.0, 5.2, 5.3, 5.5, 5.6, 6.6, 6.8, and 7.2, respectively, present in human liver cytosol. The Zn-containing band with pI of 5-6 is the dominant species of zinc in this MW range. In addition, the Cu-containing bands with pI of 5.0 and below 4.8 were also detected. It is demonstrated that the procedure could be widely used in further investigations of the chemical species of trace elements in biological samples.

Investigation of selenium distribution in subcellular fractions of human liver by neutron activation analysis

Selenium is an important and essential trace element to living systems. In the article, two methods of instrumental neutron activation analysis and hydride generation-atomic fluorescence spectrometry were applied to determine Se in biological samples and the accuracy was evaluated by several reference materials. The subcellular distribution of selenium in human liver samples, which were obtained from normal subjects who had an accidental death, was investigated by differential centrifugation combined with INAA. Selenium was mainly enriched in mitochondria, nuclei, and cytosol. Almost half of the total Se content existed in nuclei as a result of the large amount in liver and the high Se concentration. Generally, the highest Se concentration in the mitochondrial fractions of each liver sample suggested that Se had important functions in this liver component.

Preliminary study of selenium and mercury distribution in some porcine tissues and their subcellular fractions by NAA and HG-AFS

Selenium and mercury distribution in porcine tissues and their subcellular fractions from a mercury-polluted area of Guizhou Province and from a not mercury-exposed area of Beijing in China have been studied with neutron activation analysis and hydride generation-atomic fluorescence spectrometry. Both the selenium and mercury levels are higher in Guizhou porcine tissues and their subcellular fractions than those in Beijing. These two elements are highly enriched in kidney and liver of Guizhou pig, while selenium is only enriched in the kidney of Beijing pig. Exposure of mercury may result in redistribution of Se and Hg in vivo. The Hg/Se molar ratio of the subcellular fractions is very low in the case of relatively low mercury level and gradually reaches to a high constant value with increasing level of mercury, which implies that selenium and mercury may form some special complexes in the organisms.

Subcellular localization of several heavy metals of Hg, Cd and Pb in human liver

Liver, as an important metabolic and detoxicological organ of human body, can be used as a good bioindicator for evaluating body burden of environmental pollutants. Its elemental contents and their chemical forms are closely related to the status of human health and disease. In this paper, the liver samples collected from normal subjects were separated to different subcellular fractions of nuclei, mitochondria, lysosome, microsome and cytosol by differential centrifugation. Then their concentrations of heavy metals of As, Pb, Cd, and Hg were determined by atomic absorption and atomic fluorescent spectroscopy. Our results show no significant difference with literature ones when comparing their gross concentrations. In the case of their subcellular distribution, the Hg concentrations are higher in mitochondrial, microsomal and cytosolic fractions; the Cd concentrations are higher in cytosolic and mitochondrial fractions, while As highest in nuclear fraction. The highest concentration of Pb is found in microsomal fraction with similarity to Fe. Mercury in liver is mainly in the form of inorganic, and methylmercury ranged from 9% to 50% with the average value of 20.9%±13.3%. These results indicate that the cellular distribution and the accumulated target organelles are quite different among these heavy metals, which suggest their various pathways and toxic mechanismin vivo.