Douglas M. Templeton

Guidelines for terms related to chemical speciation and fractionation of elements. Definitions, structural aspects, and methodological approaches (IUPAC Recommendations 2000)

This paper presents definitions of concepts related to speciation of elements, more particularly speciation analysis and chemical species. Fractionation is distinguished from speciation analysis, and a general outline of fractionation procedures is given. We propose a categorization of species according to isotopic composition of the element, its oxidation and electronic states, and its complex and molecular structure. Examples are given of methodological approaches used for speciation analysis. A synopsis of the methodology of dynamic speciation analysis is also presented.

Iron-chelation therapy with oral deferiprone in patients with thalassemia major

BACKGROUND To determine whether the orally active iron chelator deferiprone (1,2-dimethyl-3-hydroxy-pyridin-4-one) is efficacious in the treatment of iron overload in patients with thalassemia major, we conducted a prospective trial of deferiprone in 21 patients unable or unwilling to use standard chelation therapy with parenteral deferoxamine. METHODS Hepatic iron stores were determined yearly by chemical analysis of liver-biopsy specimens or magnetic-susceptibility measurements. Detailed clinical and laboratory studies were used to monitor safety and compliance. RESULTS The patients received deferiprone therapy for a mean (+/-SE) of 3.1 +/- 0.3 years. Ten patients in whom previous chelation therapy with deferoxamine had been ineffective had initial hepatic iron concentrations of at least 80 mumol per gram of liver, wet weight -- values associated with complications of iron overload. Hepatic iron concentrations decreased in all 10 patients, from 125.3 +/- 11.5 to 60.3 +/- 9.6 mumol per gram (P < 0.005), with values that were less than 80 mumol per gram in 8 of the 10 patients (P < 0.005). In all 11 patients in whom deferoxamine therapy had previously been effective, deferiprone maintained hepatic iron concentrations below 80 mumol of iron per gram. CONCLUSIONS Oral deferiprone induces sustained decreases in body iron to concentrations compatible with the avoidance of complications from iron overload. The risk of agranulocytosis associated with deferiprone may restrict its administration to patients who are unable or unwilling to use deferoxamine.

Multiple roles of cadmium in cell death and survival.

Cadmium is a toxic metal with no known biological function. It is increasingly important as an environmental hazard to both humans and wildlife, and it exemplifies the double edged nature of many toxic substances. Thus, on the one hand cadmium can act as a mitogen, stimulate cell proliferation, inhibit apoptosis, inhibit DNA repair, and promote cancer in a number of tissues. On the other hand, it causes tissue damage, notably in the kidney, by inducing cell death. At low and moderate concentrations in cell culture systems (e.g., 0.1-10μM) cadmium primarily causes apoptosis, and at higher concentrations (>50μM) necrosis becomes evident. This generalization appears to hold in vivo. There is also evidence of cadmium-induced autophagy, although whether this is a direct cause of cell death remains uncertain. After discussing these generalities, this review considers the details of apoptotic death, and its inhibition, in renal mesangial cells. We also present evidence for the effect of environmental exposure to cadmium in affecting renal function, and in particular review the evidence for the role of the mesangial cell in cadmium nephrotoxicity.

Molecular and Cellular Iron Transport

Molecular and cellular iron transport , Molecular and cellular iron transport , کتابخانه دیجیتال دانشگاه آزاد اسلامی خوراسگان

Growth failure and bony changes induced by deferoxamine.

We reviewed the linear growth and growth plate morphology in all children with homozygous beta thalassemia followed in Toronto, for whom monthly height percentiles were available before, and for a 36-month period after, the initiation of nightly subcutaneous deferoxamine therapy. All patients were less than 7 years of age when begun on deferoxamine, and had received nightly deferoxamine for a minimum of 36 months. Marked abnormalities of the metaphyseal growth plate were readily observed in the distal ulnar, radial, and tibial metaphyses in 11 of 37 patients in whom a significant decline in mean height percentile was also noted. (In 10 of these 11 patients, height was less than the 15th percentile after 36 months.) These 11 patients had received a significantly greater (p less than 0.025) initial and average daily dose of deferoxamine, and had maintained a significantly lower (p less than 0.025) mean serum ferritin concentration over the 36 months, than the remainder of the cohort. To determine whether deferoxamine played a causative role in growth failure, growth in patients who began deferoxamine before the age 2 years was compared to that of patients who began after age 5 years, for the period between 2 and 5 years of age. Only patients begun on deferoxamine prior to age 2 years demonstrated a significant (p less than 0.01) decline in height percentile by the third year, implicating deferoxamine therapy as the cause of growth failure. We conclude that both the decline in height percentile and the bony changes observed in well-chelated patients are directly related to deferoxamine therapy.(ABSTRACT TRUNCATED AT 250 WORDS)

Induction of c-fos proto-oncogene in mesangial cells by cadmium.

Cadmium is mitogenic under some circumstances and has been shown to cause accumulation of transcripts for several proto-oncogenes in a variety of cells, but the mechanism(s) remain to be delineated. Here we show that CdCl2 causes an increase in c-fos mRNA within 30 min of exposure of mesangial cells. At 10 μm Cd2+, this increase persists for at least 8 h in both rat and human cells. The half-life of c-fos mRNA is the same whether it accumulates following 4 h of treatment with Cd2+ or is induced transiently by phorbol ester. Cycloheximide, which stabilizes the transcript, causes a synergistic increase when administered with CdCl2. Nuclear run-on analysis confirms that Cd2+ causes transcriptional activation of the c-fos gene. Calmodulin and Ca2+/calmodulin-dependent kinase, and classical protein kinase C (PKC) isoforms represent two Ca2+-dependent signaling pathways that can lead to induction of c-fos, and Cd2+ has been shown to activate both calmodulin and PKC in vitro, possibly by virtue of the similar ionic radii of Cd2+ and Ca2+. Therefore, we investigated the effect of Cd2+ on these pathways in vivo. 10 μm CdCl2 did not increase total PKC activity or Ca2+/calmodulin-dependent kinase II activity and inhibited the latter at higher concentrations, ruling out either pathway in the Cd2+-dependent induction of c-fos. However, Cd2+ did lead to a sustained activation of the Erk family mitogen-activated protein kinases (MAPK) that correlated with induction of c-fos. A specific inhibitor of the MAPK kinases, PD98059, partially inhibited the induction of c-fos by Cd2+. We conclude that Cd2+ induces c-fos at least in part by causing a sustained activation of MAPK independent of its ability to activate PKC and calmodulin in vitro.

Genetic regulation of cell function in response to iron overload or chelation

Iron influences many aspects of cell function on different biochemical levels. This review considers effects mediated through iron-dependent changes in gene expression in mammalian cells. Several classes of related genes are responsive to cellular iron levels, but no clear patterns readily account for the toxicity of iron overload or the consequences of removal of iron with chelating agents. Here we group some of the genes influenced by iron status into those related to iron metabolism, oxygen and oxidative stress, energy metabolism, cell cycle regulation, and tissue fibrosis. Iron excess and chelation do not generally result in a continuous or graded transcriptional response, but indicate operation of distinct mechanisms. An emerging concept is that iron signals through generation of reactive oxygen species to activate transcription factors such as NF-kappaB, whereas iron removal mimics hypoxia, perhaps by disrupting iron-based O(2) sensors and influencing gene expression through, e.g., the hypoxia-inducible factor, HIF-1. Heme and other metalloporphyrins have other distinct mechanisms for regulating transcription. Regulation of gene expression through iron-responsive elements in mRNAs coded by several genes is one of the best understood mechanisms of translational control.

Sample collection guidelines for trace elements in blood and urine.

This paper presents an organized system for element-specific sample collection and handling of human blood (whole blood, serum or plasma, packed cells or erythrocytes) and urine also indicating a proper definition of the subject and sample. Harmonized procedures for collection, preparation, analysis and quality control are suggested. The aim is to assist scientists worldwide to produce comparable data which will be useful on a regional, national and international scale. The guidelines are directed to the elements aluminium, arsenic, cadmium, chromium, cobalt, copper, lead, lithium, manganese, mercury, nickel, selenium and zinc. These include the most important elements measured for their occupational or clinical significance, and serve as examples of principles that will guide development of methods for other elements in the future.

Protective elevations of glutathione and metallothionein in cadmium-exposed mesangial cells

Exposure of cultured rat mesangial cells to CdCl2 caused a dose- and time-dependent increase in intracellular glutathione that was significant at 0.5 microM and maximal at 1 microM Cd2+. The effect depended on glutathione synthesis and was masked by inhibiting synthesis with buthionine sulfoximine. The cells responded to slightly higher concentrations of Cd with a marked decrease in DNA synthesis, and reversible depletion of glutathione enhanced this sensitivity. Pre-induction of the thiol-rich protein metallothionein with ZnCl2 afforded a degree of protection to the glutathione-depleted cells. We conclude that the Cd-dependent elevation of glutathione in these cells may be protective at concentrations of Cd that can arise during acute environmental and occupational exposures.

Mitochondrial involvement in genetically determined transition metal toxicity II. Copper toxicity.

Copper, like iron, is an essential transition metal ion in which its redox reactivity, whilst essential for the activity of mitochondrial enzymes, can also be a source of harmful reactive oxygen species if not chelated to biomolecules. Therefore, both metals are sequestered by protein chaperones and moved across membranes by protein transporters with the excess held in storage proteins for future use. In the case of copper, the storage proteins in the mitochondria are a distinct ceruloplasmin and metallothionein (MT). If the cell accumulates too much copper or copper is needed by other cells, then copper can be chaperoned to the trans-Golgi secretory compartment where it is transported into the Golgi by ATP-dependent pumps ATP7A/B. In liver, the copper is then incorporated into ceruloplasmin in vesicles that travel to the plasma membrane and release ceruloplasmin into the plasma. This paper reviews the genetic basis for diseases associated with copper deficit or excess, particularly those attributed to defective ATP7A/B transporters, with special emphasis on pathologies related to a loss of mitochondrial function.