人体硒代谢与硒营养研究进展

硒是人体所必需的重要微量营养元素,综述了当前国内外人体硒代谢与硒营养的研究进展,包括硒源形式与吸收、人体的硒含量与分布、硒的代谢途径、硒的生物活化形式、硒与疾病、硒中毒和硒的安全摄入量。在此基础上,提出了针对我国硒资源分布、硒反应症分布和居民膳食结构硒摄入量的研究建议,为满足居民通过膳食和补充剂补硒预防和治疗疾病提供理论和实践指导。     

Methylselenocysteine treatment leads to diselenide formation in human cancer cells: evidence from X-ray absorption spectroscopy studies

The selenoamino acids methylselenocysteine (MeSeCys) and selenomethionine (SeMet) have disparate efficacies as anticancer agents. Herein, we use X-ray absorption spectroscopy to determine the chemical form of selenium in human neuroblastoma cells. Cells treated with MeSeCys contain a significant diselenide component, which is absent from SeMet-treated cells and suggests that metabolites of MeSeCys are capable of altering the redox status of the cells. The differences in the speciation of Se in the selenoamino acid-treated cells may provide insight into the differing anticancer activities of MeSeCys and SeMet.     

Selenium metabolism and bioavailability

Selenium (Se) is at once an essential and toxic nutrient that occurs in both inorganic and organic forms. The biological functions of Se are mediated through at least 13 selenoproteins that contain Se as selenocysteine (Se-cyst). The endogenous synthesis of this amino acid from inorganic Se (selenide Se⁻²) and serine is encoded by a stop codon UGA in mRNA and involves a unique tRNA. Selenium can also substitute for sulfur in methionine to form an analog, selenomethionine (Se-meth), which is the main form of Se found in food. Animals cannot synthesize Se-meth or distinguish it from methionine and as a result it is nonspecifically incorporated into a wide range of Se-containing proteins. The metabolic fate of Se varies according to the form ingested and the overall Se status of an individual. This paper reviews the bioavailability, including absorption, transport, metabolism, storage, and excretion, of the different forms of exogenous and endogenous Se.     

Chemical Form of Selenium Affects Its Uptake,Transport, and Glutathione Peroxidase Activity in the Human Intestinal Caco-2 Cell Model

Determining the effect of selenium (Se) chemical form on uptake, transport, and glutathione peroxidase activity in human intestinal cells is critical to assess Se bioavailability at nutritional doses. In this study, we found that two sources of L-selenomethionine (SeMet) and Se-enriched yeast each increased intracellular Se content more effectively than selenite or methylselenocysteine (SeMSC) in the human intestinal Caco-2 cell model. Interestingly, SeMSC, SeMet, and digested Se-enriched yeast were transported at comparable efficacy from the apical to basolateral sides, each being about 3-fold that of selenite. In addition, these forms of Se, whether before or after traversing from apical side to basolateral side, did not change the potential to support glutathione peroxidase (GPx) activity. Although selenoprotein P has been postulated to be a key Se transport protein, its intracellular expression did not differ when selenite, SeMSC, SeMet, or digested Se-enriched yeast was added to serum-contained media. Taken together, our data show, for the first time, that the chemical form of Se at nutritional doses can affect the absorptive (apical to basolateral side) efficacy and retention of Se by intestinal cells; but that, these effects are not directly correlated to the potential to support GPx activity.     

稻田硒循环转化与水稻硒营养研究进展

稻田土壤氧化还原电位的交替变化和土壤组分的特殊性决定了硒在稻田环境中的循环转化机制明显有别于旱地土壤,并且影响到土壤硒的有效性及水稻对硒的吸收与积累.深入研究稻田土壤硒的循环转化及水稻硒营养吸收对实现土壤无机硒向有机硒的转化具有重要意义.本文对稻田土壤硒的循环机制及形态转化、水稻体内硒的代谢机制及吸收积累特性进行综述,分析硒在土壤 水稻系统中转化及向水稻体内迁移的研究现状与发展趋势,为土壤硒有效性研究及培育富硒营养稻米提供参考.     

施硒对水稻土壤硒有效性的影响

硒在华南稻区酸性土壤中极易被固定使其有效性较低.本研究旨在通过盆栽试验,探明施用硒肥对水稻根际和非根际土壤硒有效性的影响.结果表明: 施硒能提高水稻产量,增加籽粒硒含量;水稻根际土壤中水溶态硒、交换态硒、铁锰氧化物结合态硒、有机物-硫化物结合态硒和残渣态硒含量均低于非根际土壤.各施硒处理之间,根际和非根际土壤中硒的迁移系数没有显著差异;施硒对根和叶片之间硒的迁移系数也没有显著影响,但是施硒提高了叶片和籽粒之间硒的迁移系数.施用0.5 mg·kg^-1硒增加了水稻根系有机酸的分泌,而施用1.0、5.0 mg·kg^-1硒则降低了有机酸的分泌.根系有机酸的分泌对根际土壤pH值影响不大,根际土壤pH值反而高于非根际土壤,但施硒显著降低了根际土壤pH值.随着施硒水平的提高,根际土壤黏土矿物(高岭石)的红外吸收光谱不断增强.施入土壤中的硒多转化为水稻难以吸收利用的形态,且不易向根际移动.根系分泌的有机酸也并不是通过影响土壤pH值来提高土壤硒的有效性.     

Selenium-tolerant diamondback moth disarms hyperaccumulator plant defense

BACKGROUND: Some plants hyperaccumulate the toxic element selenium (Se) to extreme levels, up to 1% of dry weight. The function of this intriguing phenomenon is obscure. RESULTS: Here, we show that the Se in the hyperaccumulator prince's plume (Stanleya pinnata) protects it from caterpillar herbivory because of deterrence and toxicity. In its natural habitat, however, a newly discovered variety of the invasive diamondback moth (Plutella xylostella) has disarmed this elemental defense. It thrives on plants containing highly toxic Se levels and shows no oviposition or feeding deterrence, in contrast to related varieties. Interestingly, a Se-tolerant wasp (Diadegma insulare) was found to parasitize the tolerant moth. The insect's Se tolerance mechanism was revealed by X-ray absorption spectroscopy and liquid chromatography-mass spectroscopy, which showed that the Se-tolerant moth and its parasite both accumulate methylselenocysteine, the same form found in the hyperaccumulator plant, whereas related sensitive moths accumulate selenocysteine. The latter is toxic because of its nonspecific incorporation into proteins. Indeed, the Se-tolerant diamondback moth incorporated less Se into protein. Additionally, the tolerant variety sequestered Se in distinct abdominal areas, potentially involved in detoxification and larval defense to predators. CONCLUSIONS: Although Se hyperaccumulation protects plants from herbivory by some invertebrates, it can give rise to the evolution of unique Se-tolerant herbivores and thus provide a portal for Se into the local ecosystem. In a broader context, this study provides insight into the possible ecological implications of using Se-enriched crops as a source of anti-carcinogenic selenocompounds and for the remediation of Se-polluted environments.     

环境中硒的生物地球化学循环和营养调控及分异成因

硒是环境中重要的生命元素,它在环境中含量水平的高低直接影响着人及动植物的健康安全。结合国内外资料及最新的研究进展,阐述了环境中硒的生物地球球化学循环,包括环境中硒的生物地球化学循环特征,土壤中硒的含量分布、形态及有效性,大气和水环境中硒的形态分布,植物体中的硒及其对硒的吸收关系;讨论了低硒高硒环境中硒营养水平的调节及环境分异的成因,诸如母质类型、气候特征、风化淋失、气体挥发、土壤质地和地力耗竭等方面;并提出了环境中硒研究的前沿及今后关注的热点问题,以促进今后环境中硒的研究。     

X-Ray Fluorescence Microscopy Reveals the Role of Selenium in Spermatogenesis

Selenium (Se) is a trace element with important roles in human health. Several selenoproteins have essential functions in development. However, the cellular and tissue distribution of Se remains largely unknown because of the lack of analytical techniques that image this element with sufficient sensitivity and resolution. Herein, we report that X-ray fluorescence microscopy (XFM) can be used to visualize and quantify the tissue, cellular, and subcellular topography of Se. We applied this technique to characterize the role of Se in spermatogenesis and identified a dramatic Se enrichment specifically in late spermatids, a pattern that was not seen in any other elemental maps. This enrichment was due to elevated levels of the mitochondrial form of glutathione peroxidase 4 and was fully dependent on the supplies of Se by selenoprotein P. High-resolution scans revealed that Se concentrated near the lumen side of elongating spermatids, where structural components of sperm are formed. During spermatogenesis, maximal Se associated with decreased phosphorus, whereas Zn did not change. In sperm, Se was primarily in the midpiece and colocalized with Cu and Fe. XFM allowed quantification of Se in the midpiece (0.8 fg) and head (0.2 fg) of individual sperm cells, revealing the ability of sperm cells to handle the amounts of this element well above its toxic levels. Overall, the use of XFM allowed visualization of tissue and cellular Se and provided important insights in the role of this and other trace elements in spermatogenesis.     

Chemical form of selenium greatly affects metal uptake and responses by cultured human lymphocytes

In this work, possible interference with functional activities of human lymphocytes after in vitro treatment with selenium was examined. Sodium selenite and selenomethionine compounds were tested in parallel, and their capability to inhibit or to increase the antibody production by lymphocytes was investigated. Furthermore, after incubation for 7 d, total cell-associated Se was measured by a fluorimetric method. The in vitro doses of Se employed in this study mainly reflect those measured in blood of individuals with different Se intake. Low doses of Se (0.5–2.0μM) added either as sodium selenite or selenomethionine did not alter the secretion of antibodies. When Se was added at higher levels, instead, an inhibitory effect was found using selenite, whereas a progressive increase in immunoglobulin production was observed after exposure to selenomethionine. In both cases, modifications were detected at 5 μM (395 μg Se/L), and were significant at 10 μM (789 μg Se/L). A different trend between the two chemical forms was also observed with regard to Se uptake by cells. Interestingly, both Se uptake and cell sensitivity were influenced by the density of the cells in culture. Our data suggest that the biological effects of Se in mammalian systems are strongly influenced by its chemical form, and caution should be exerted to avoid toxic effects of selenium.     

Selenium–Mercury Interactions in Man and Animals

Selenium–mercury interactions were most extensively studied in relation to alleviation of Hg toxicity by added selenium. This presentation considers the influence of mercury on endogenous selenium, on its tissue and cellular “status” after lifelong or acute exposure to mercury vapor (Hg^o). Discussed are data obtained from (1) humans living near or working in a mercury mine, and (2) rats experimentally exposed in the mine. Mercury vapor is unique—or similar to methylmercury—because of its ability to penetrate cell membranes and so invade all cells, where it is oxidized in the biologically active form (Hg⁺⁺) by catalase. Such in situ-generated ions can react with endogenously generated highly reactive Se metabolites, like HSe−, and render a part of the selenium unavailable for selenoprotein synthesis. Data on human populations indicate that in moderate Hg exposure combined with an adequate selenium supply through diet, Se bioavailability can be preserved. On the other hand, the results of an acute exposure study emphasize the dual role of selenium in mercury detoxification. Besides the well-known Se coaccumulation through formation of nontoxic Hg–Se complexes, we observed noticeable Se (co)excretion, at least at the beginning of exposure. The higher Hg accumulation rate in the group of animals with lower basal selenium levels can also point to selenium involvement in mercury excretion. In such conditions there is a higher probability for decreased selenoprotein levels (synthesis) in some tissues or organs, depending on the synthesis hierarchy.     

Chemical forms of selenium in selenium containing proteins from human plasma

The chemical forms of selenium (Se) were determined in human plasma fractions. Human plasma was subjected to gel filtration using Sephadex G-150, and the first Se peak from this column was subsequently chromatographed on DEAE-Sephacel. The form of Se in the Se peak which eluted from this column was shown to be selenocysteine (SeCys). In a second approach human plasma was again subjected to gel filtration and the first Se peak was chromatographed on Affigel blue. SeCys was shown to be the form of Se in both the retained and unretained Se on this column. The second gel filtration Se peak was also chromatographed on Reactive Blue 2-Sepharose CL-6B and the form of Se which was not retained was also shown to be SeCys. However, the form which was retained was shown to be selenomethionine. Evidence is presented that there are three Se containing proteins in human plasma, which are selenoprotein P, glutathione peroxidase, and albumin.     

Chemical forms of selenium for cancer prevention.

Cancer is becoming an increasingly significant disease worldwide. Currently, more than 7 million people die each year from cancer. With the existing knowledge, at least one-third of worldwide cancer cases could be prevented. Searching for naturally occurring agents in routinely consumed foods that may inhibit cancer development, although challenging, constitutes a valuable and plausible approach to the control and prevention of cancer. To date, the use of the micronutrient selenium (Se) in human clinical trials is limited, but the outcome indicates that Se is among the most promising agents. Although it is convenient to describe the effects of Se in terms of the element, it must always be kept in mind that the chemical form of Se and the dose are determinants of its biological activities. Hyphenated techniques based on coupling chromatographic separation with inductively coupled plasma mass spectrometric (ICP-MS) detection are now established as the most realistic and potent analytical tools available for real-life speciation analysis. These speciation investigations provide evidence that the Se compounds, which can generate monomethylated Se (e.g., Se-methylselenocysteine and methylseleninic acid), are more efficacious than other Se compounds because of their chemoprevention activity.     

Antioxidative flavonoid quercetin: implication of its intestinal absorption and metabolism

Quercetin is a typical flavonoid ubiquitously present in fruits and vegetables, and its antioxidant effect is implied to be helpful for human health. The bioavailability of quercetin glycosides should be clarified, because dietary quercetin is mostly present as its glycoside form. Although quercetin glycosides are subject to deglycosidation by enterobacteria for the absorption at large intestine, small intestine acts as an effective absorption site for glucose-bound glycosides (quercertin glucosides). This is because small intestinal cells possess a glucoside-hydrolyzing activity and their glucose transport system is capable of participating in the glucoside absorption. A study using a cultured cell model for intestinal absorption explains that the hydrolysis of the glucosides accelerates their absorption in the small intestine. Small intestine is also recognized as the site for metabolic conversion of quercetin and other flavonoids as it possesses enzymatic activity of glucuronidation and sulfation. Modulation of the intestinal absorption and metabolism may be beneficial for regulating the biological effects of dietary quercetin.     

Characterization of selenoprotein P as a selenium supply protein.

Selenium (Se) is well known to be essential for cell culture when using a serum-free medium, but not when a medium containing serum is used. This finding suggests that serum contains some usable form of Se. To identify the Se-supplier, T-lymphoma (Jurkat) cells were cultured for 3 days in the presence of human serum immunodepleted of Se-containing serum protein, selenoprotein P or extracellular glutathione peroxidase. The Se-dependent enzyme activities (glutathione peroxidases and thioredoxin reductase) and Se content within the cells markedly decreased only when cultured with selenoprotein P-depleted serum. Compared with other Se-containing proteins, the addition of purified selenoprotein P to the selenoprotein P-depleted serum or a serum-free medium was the most effective for the recovery of cellular glutathione peroxidase activity (index of Se status). These results suggest that selenoprotein P functions as a Se-supply protein, delivering Se to the cells.     

X-ray absorption spectroscopy study shows that the rapid selenium volatilizer, pickleweed (Salicornia bigelovii Torr.), reduces selenate to organic forms without the aid of microbes

In many plant species, selenium (Se) volatilization is limited by the reduction of selenate and its chemical conversion to organic Se compounds, a process that may be facilitated by rhizosphere microbes. This study was conducted to determine if pickleweed (Salicornia bigelovii Torr.), which is characterized by having high rates of Se volatilization from selenate, is able to reduce selenate into organic forms of Se axenically, or whether it requires the presence of microbes. X-ray absorption spectroscopy analysis showed that shoots and roots of pickleweed plants supplied with 50 microM selenate accumulated Se predominantly in organic Se forms (about 65-75% of the total accumulated Se), regardless of whether the plants were grown axenically or in the presence of microbes. The results suggest that, unlike other species for which selenate reduction appears to be rate limiting. e.g. Indian mustard (Brassica juncea L.) and broccoli (Brassica oleracea L.), pickleweed is unusual in that it has an enhanced capacity to reduce selenate to organic forms that is independent of the presence of rhizosphere microbes.     

A selenium-containing hydrogenase from Methanococcus vannielii. Identification of the selenium moiety as a selenocysteine residue

A 75Se-labeled hydrogenase was purified to near homogeneity from extracts of Methanococcus vannielii cells grown in the presence of [75Se]selenite. The molecular weight of the enzyme was estimated as 340,000 by gel filtration. The enzyme tends to aggregate and occurs also as a larger protein species (Mr = 1.3 x 10(6)). The same phenomenon was observed on native gel electrophoretic analysis. Hydrogenase activity exhibited by these two protein bands was proportional to protein and 75Se content. Both molecular species reduce the natural cofactor, 8-hydroxy-5-deazaflavin, and tetrazolium dyes with molecular hydrogen. Sodium dodecyl sulfate-gel electrophoresis of 75Se-labeled enzyme showed that 75Se is present exclusively in an Mr = 42,000 subunit. A value of 3.8 g atoms of selenium/mol of enzyme (Mr = 340,000) was determined by atomic absorption analysis. The chemical form of selenium in the enzyme was shown to be selenocysteine. This was identified as the [75Se]carboxymethyl and [75Se]carboxyethyl derivatives in acid hydrolysates of alkylated 75Se-labeled protein. The hydrogenase is extremely oxygen-sensitive but can be reactivated by incubation with molecular hydrogen and dithiothreitol.     

Selenium uptake in Zea mays supplied with selenate or selenite under hydroponic conditions

Background and aims

Selenium is an essential micro-nutrient for animals, humans and microorganisms; it mainly enters food chains through plants. This study proposes to explore effect of inorganic Se forms on its uptake and accumulation in Zea mays.

Methods

Zea mays was grown in a controlled-atmosphere chamber for 2 weeks in a hydroponic solution of low-concentration selenium (10 μg/L (i.e.0.12 μM) or 50 μg/L (i.e. 0.63 μM) of Se). For each concentration, four treatments were defined: control (without selenium), selenite alone, selenate alone and selenite and selenate mixed.

Results

At low concentrations, selenium did not affect the biomass production of Zea mays. However, for both concentrations, Se accumulation following a selenite-only treatment was always higher than with selenate-only. Moreover, in the selenate-only treatment, Se mainly accumulated in shoots whereas in the selenite-only treatment, Se was stocked more in the roots. Interactions between selenate and selenite were observed only at the higher concentration (0.63 μM of selenium in the nutrient solution).

Conclusions

Se form and concentration in the nutrient solution strongly influenced the absorption, allocation and metabolism of Se in Zea mays. Selenate seems to inhibit selenite absorption by the roots.     

Toxicity and mutagenicity of selenium compounds in Saccharomyces cerevisiae

Selenium (Se) is an essential trace element for humans, animals and some bacteria which is important for many cellular processes. Se's bio-activity is mainly influenced by its chemical form and dose. The use of Se supplements in the human diet emphasizes the need to establish both the beneficial and detrimental doses of each Se compound. We have evaluated three different Se compounds, sodium selenite (SeL), selenomethionine (SeM) and Se-methylselenocysteine (SeMC), with respect to their potential DNA damaging effects. The budding yeast Saccharomyces cerevisiae was used as a model system to test the toxic and mutagenic effects as well as the DNA double-strand breakage potency of these Se compounds in both exponentially growing and stationary yeast cells. Only SeL manifested any significant toxic effects in the yeast which were more pronounced in the exponentially growing cells than in those cells in the stationary phase of growth. The toxic effects of SeL were however accompanied with the pro-mutagenic effects in the stationary cell phase of growth. The toxic and mutagenic effects of SeL are likely associated with the ability of this compound to generate DNA double-strand breaks (DSB). We also show that SeL significantly increased frame-shift mutations, especially 1-4 bp deletions, in the CAN1 mutational spectrum of the yeast genome when compared to untreated control. We propose that SeL is acting as an oxidizing agent in S. cerevisiae producing superoxide and oxidative damage to DNA accounting for the observed DSB and cell death.     

The disparity between human cell senescence in vitro and lifelong replication in vivo

Cultured human fibroblasts undergo senescence (a loss of replicative capacity) after a uniform, fixed number of approximately 50 population doublings, commonly termed the Hayflick limit. It has been long known from clonal and other quantitative studies, however, that cells decline in replicative capacity from the time of explantation and do so in a stochastic manner, with a half-life of only approximately 8 doublings. The apparent 50-cell doubling limit reflects the expansive propagation of the last surviving clone. The relevance of either figure to survival of cells in the body is questionable, given that stem cells in some renewing tissues undergo >1,000 divisions in a lifetime with no morphological sign of senescence. Oddly enough, these observations have had little if any effect on general acceptance of the Hayflick limit in its original form. The absence of telomerase in cultured human cells and the shortening of telomeres at each population doubling have suggested that telomere length acts as a mitotic clock that accounts for their limited lifespan. This concept assumed an iconic character with the report that ectopic expression of telomerase by a vector greatly extended the lifespan of human cells. That something similar might occur in vivo seemed consistent with initial reports that most human somatic tissues lack telomerase activity. More careful study, however, has revealed telomerase activity in stem cells and some dividing transit cells of many renewing tissues and even in dividing myocytes of repairing cardiac muscle. It now seems likely that telomerase is active in vivo where and when it is needed to maintain tissue integrity. Caution is recommended in applying telomerase inhibition to kill telomerase-expressing cancer cells, because it would probably damage stem cells in essential organs and even increase the likelihood of secondary cancers. The risk may be especially high in sun-exposed skin, where there are usually thousands of p53-mutant clones of keratinocytes predisposed to cancer.