AhFRDL1-mediated citrate secretion contributes to adaptation to iron deficiency and aluminum stress in peanuts.

Although citrate transporters are involved in iron (Fe) translocation and aluminum (Al) tolerance in plants, to date none of them have been shown to confer both biological functions in plant species that utilize Fe-absorption Strategy I. In this study, we demonstrated that AhFRDL1, a citrate transporter gene from peanut (Arachis hypogaea) that is induced by both Fe-deficiency and Al-stress, participates in both root-to-shoot Fe translocation and Al tolerance. Expression of AhFRDL1 induced by Fe deficiency was located in the root stele, but under Al-stress expression was observed across the entire root-tip cross-section. Overexpression of AhFRDL1 restored efficient Fe translocation in Atfrd3 mutants and Al resistance in AtMATE-knockout mutants. Knocking down AhFRDL1 in the roots resulted in reduced xylem citrate and reduced concentrations of active Fe in young leaves. Furthermore, AhFRDL1-knockdown lines had reduced root citrate exudation and were more sensitive to Al toxicity. Compared to an Al-sensitive variety, enhanced AhFRDL1 expression in an Fe-efficient variety contributed to higher levels of Al tolerance and Fe translocation by promoting citrate secretion. These results indicate that AhFRDL1 plays a significant role in Fe translocation and Al tolerance in Fe-efficient peanut varieties under different soil-stress conditions. Given its dual biological functions, AhFRDL1 may serve as a useful genetic marker for breeding for high Fe efficiency and Al tolerance.

Evidence for participation of aluminum in neurofibrillary tangle formation and growth in Alzheimer's disease.

This study examines hippocampal CA1 cells from brains of aged humans, with and without Alzheimer's disease, for hyperphosphorylated tau and aluminum during early neurofibrillary tangle (NFT) formation and growth. A very small proportion of hippocampal pyramidal cells contain cytoplasmic pools within their soma that either appear homogeneous or contain short filaments (i.e., early NFTs). The cytoplasmic pools are aggregates of an aluminum/hyperphosphorylated tau complex similar to that found in mature NFTs. The photographic evidence presented combines with existing evidence to support a role for aluminum in the formation and growth of NFTs in neurons of humans with Alzheimer's disease.

Physiological functions of beneficial elements.

Aluminum (Al), cobalt (Co), sodium (Na), selenium (Se), and silicon (Si) are considered beneficial elements for plants: they are not required by all plants but can promote plant growth and may be essential for particular taxa. These beneficial elements have been reported to enhance resistance to biotic stresses such as pathogens and herbivory, and to abiotic stresses such as drought, salinity, and nutrient toxicity or deficiency. The beneficial effects of low doses of Al, Co, Na and Se have received little attention compared to toxic effects that typically occur at higher concentrations. Better understanding of the effects of beneficial elements is important to improve crop productivity and enhance plant nutritional value for a growing world population.

[The role of calcium, calcitriol and their receptors in parathyroid regulation]. / Papel de calcio, calcitriol y sus receptores en la regulación de la paratiroides.

The mechanism of regulation of Parathyroid hormone (PTH) is complex, and diverse factors are involved: the fundamental ones are calcium, calcitriol and phosphorus. Calcium and calcitriol's mechanism of action takes place through its specific receptors, the calcium-sensing receptor (CaR) and the Vitamin D Receptor (VDR). These two factors have an effect not only on its specific receptors, but also they can modify the other receptor in a positive manner, promoting its actions and demonstrating a cooperative effect between the two. Along with calcium and calcitriol, drugs used in the treatment of Chronic Kidney Disease Mineral Bone Disorders (CKD-MBD) also act directly or indirectly on CaR and VDR and therefore are also responsible for the regulation of the parathyroid gland.

The influence of aluminium availability on phosphate uptake in Phaseolus vulgaris L. and Phaseolus lunatus L.

Aluminium toxicity is one of the major limiting factors of crop productivity on acid soils. High levels of available aluminium in soil may induce phosphorus deficiency in plants. This study investigates the influence of Aluminium (Al) on the phosphate (P(i)) uptake of two Phaseolus species, Phaseolus vulgaris L. var. Red Kidney and Phaseolus lunatus L. The two bean species were treated first with solutions of Al at different concentrations (0, 25, 50 and 100microM, pH 4.50) and second with solutions of P(i) (150microM) at pH 4.50. The higher the Al concentration the higher the Al concentration sorbed but P. vulgaris L var. Red Kidney adsorbed significantly more Al than P. lunatus L. Both species released organic acids: P. vulgaris L var. Red Kidney released fumaric acid and P. lunatus L. fumaric and oxalic acids which could have hindered further Al uptake. The two bean species showed a sigmoid P(i) uptake trend but with two different mechanisms. P. vulgaris L var. Red Kidney showed a starting point of 3h whereas P. lunatus L. adsorbed P(i) immediately within the first minutes. In addition, P. vulgaris L var. Red Kidney presented significantly higher P(i) uptake (higher uptake rate 'k' and higher maximum adsorption 'a' of the kinetic uptake model). The Al treatments did not significantly influence P(i) uptake. Results suggest that P. lunatus L. might adopt an external Al detoxification mechanism by the release of oxalic acid. P. vulgaris L var. Red Kidney on the other hand seemed to adopt an internal detoxification mechanism even if the Al sorbed is poorly translocated into the shoots. More detailed studies will be necessary to better define Al tolerance and/or resistance of Phaseolus spp.

Thermodynamics of the interaction of aluminum ions with DNA: implications for the biological function of aluminum.

Aluminum is a known neurotoxic agent and its neurotoxic effects may be due to its binding to DNA. However, the mechanism for the interaction of aluminum ions with DNA is not well understood. Here, we report the application of isothermal titration calorimetry (ITC), fluorescence spectroscopy, and UV spectroscopy to investigate the thermodynamics of the binding of aluminum ions to calf thymus DNA (CT DNA) under various pH and temperature conditions. The binding reaction is driven entirely by a large favorable entropy increase but with an unfavorable enthalpy increase in the pH range of 3.5-5.5 and at all temperatures examined. Aluminum ions show a strong and pH-dependent binding affinity to CT DNA, and a large positive molar heat capacity change for the binding, 1.57 kcal mol(-1) K(-1), demonstrates the burial of the polar surface of CT DNA upon groove binding. The fluorescence of ethidium bromide bound to CT DNA is quenched by aluminum ions in a dynamic way. Both Stern-Volmer quenching constant and the binding constant increase with the increase of the pH values, reaching a maximum at pH 4.5, and decline with further increasing the pH to 5.5. At pH 6.0 and 7.0, aluminum ions precipitate CT DNA completely and no binding of aluminum ions to CT DNA is observed by ITC. Combining the results from these three methods, we conclude that aluminum ions bind to CT DNA with high affinity through groove binding under aluminum toxicity pH conditions and precipitate CT DNA under physiological conditions.

Accretion, partitioning and sequestration of calcium and aluminum in red spruce foliage: implications for tree health.

Calcium (Ca) is an essential macronutrient in plants and is an important component of many cellular structures and physiological processes as well as overall forest function. Aluminum (Al) in soil solution can inhibit Ca uptake by plants and disrupt many Ca-dependent metabolic and physiological processes of plants. The ratio of Ca to Al in soil solution can be an important indicator of forest health, especially on acid soils. We used sequential chemical extractions (water, acetic acid and hydrochloric acid) to assess the chemical availability of Ca and Al in foliage from mature red spruce (Picea rubens Sarg.) trees growing under ambient environmental conditions. In plants deficient in Ca and with intermediate total foliar Ca concentration ([Ca]), Ca preferentially accrued in labile and physiologically available forms (water- and acetic acid-extractable). In plants with total foliar [Ca] above a "sufficiency" threshold, Ca also accrued in a chemically sequestered form with low solubility (HCl-extractable), suggesting that Ca sequestration is an inducible process in response to excess foliar Ca. Because it has low solubility, it is likely that sequestered Ca is unavailable for Ca-dependent physiological processes. Immobilization of Al in foliage was related to Ca sequestration, suggesting that Ca sequestration may provide a passive mechanism for Al tolerance in the foliage of these trees. Aluminum immobilization was evident based on the ratio of HCl-extractable Al to the more labile (water- and acetic acid-extractable) forms of Al. Sufficient labile Ca combined with Al sequestration was associated with plant health, including enhanced foliar accretion of Mg and Mn, greater tree growth, enhanced foliar cold hardiness and reduced winter injury. These findings demonstrate that not all chemical forms of foliar Ca and Al are of equal physiological significance and underscore the importance of assessing the biologically significant element forms in biogeochemical research.

Growth and nutrient uptake of ectomycorrhizal Pinus sylvestris seedlings in a natural substrate treated with elevated Al concentrations.

Models of the effects of elevated concentrations of aluminum (Al) on growth and nutrient uptake of forest trees frequently ignore the effects of mycorrhizal fungi. In this study, we present novel data indicating that ectomycorrhizal mycelia may prevent leaching of base cations and Al. Mycorrhizal and non-mycorrhizal Pinus sylvestris L. seedlings were grown in sand obtained from the B-horizon of a local forest. In Experiment 1, non-mycorrhizal seedlings and seedlings inoculated with Hebeloma cf. longicaudum (Pers.: Fr.) Kumm. ss. Lange or Laccaria bicolor (Maire) Orton were provided with nutrient solution containing 2.5 mM Al. Aluminum did not affect growth of non-mycorrhizal seedlings or seedlings inoculated with L. bicolor. Seedlings colonized by H. cf. longicaudum had the highest biomass production of all seedlings grown without added Al, but the fungus did not tolerate Al. Shoots of seedlings colonized by L. bicolor had the lowest nitrogen (N) concentrations but the highest phosphorus (P) concentrations of all seedlings. The treatments had small but significant effects on shoot and root Al concentrations. In Experiment 2, inoculation with L. bicolor was factorially combined with the addition of a complete nutrient solution, or a solution lacking the base cations K, Ca and Mg, and solutions containing 0 or 0.74 mM Al. Seedling growth decreased in response to 0.74 mM Al, but the effect was significant only for non-mycorrhizal seedlings. Mycorrhizal seedlings generally had higher P concentrations than non-mycorrhizal seedlings. Aluminum reduced P uptake in non-mycorrhizal plants but had no effect on P uptake in mycorrhizal plants. Mycorrhizal colonization increased the pH of the soil solution by about 0.5 units and addition of Al decreased the pH by the same amount. We conclude that the presence of ectomycorrhizal mycelia decreased leaching of base cations and Al from the soil.

Aluminum induced oxidative events and its relation to inflammation: a role for the metal in Alzheimer's disease.

Aluminum (Al) is a simple trivalent cation incapable of redox changes. The toxicity of the metal has been the subject of much controversy in the past few decades. Although it has been generally believed that the metal is innocuous to human health, a causal role for Al has been established in dialysis dementia (Alfrey et al., 1976), osteomalacia (Bushinsky et al., 1995) and microcytic anemia without iron deficiency (Touam et al., 1983). Aluminum has also been implicated in Alzheimer's disease (AD) although a direct causal role has not been determined. The exact mechanism of Al toxicity is not known. However, there are several lines of evidence that show the metal's capacity to exacerbate oxidative events. The present review is intended to propose a coherent pathway linking Al-induced oxidative events to Alzheimer's disease. The preliminary segment is an introduction to reactive oxygen species and their potential involvement in the pathogenesis of AD and the generation of an inflammatory response. Evidence on the relation between AD and inflammatory processes is also presented. The epidemiological and clinical evidence of Al neurotoxicity is summarized in the second section of the review. Finally, a hypothesis indicating that aluminum can exacerbate AD by activating ROS generation and initiation of an inflammatory cascade is presented.

Aluminum decreases the magnesium concentration of spinal cord and trabecular bone in rats fed a low calcium, high aluminum diet.

Current epidemiological surveys in the Western Pacific (Guam, and Kii Peninsula and West New Guinea) have suggested that low calcium (Ca), magnesium (Mg) and high aluminum (Al) and manganese (Mn) in river, soil and drinking water may be implicated in the pathogenetic process of foci of amyotrophic lateral sclerosis (ALS) and parkinsonism-dementia (PD). The condition of unbalanced minerals was experimentally mimicked in this study using rats. Male Wistar rats, weighing 200 g, were maintained for 60 days on the following diets: (A) standard diet, (B) low Ca diet, (C) low Ca diet plus high Al. Magnesium concentrations were determined in spinal cord and trabecular bone using inductively coupled plasma emission spectrometry (ICP). In the experimental group maintained on a low Ca, high Al diet, magnesium concentration of the spinal cord was lower than the group fed a standard diet. Also, magnesium concentration of lumbar vertebra showed lower values in the experimental group fed a low Ca, high Al diet than did those on a standard diet or low Ca diet without supplemental aluminum. Our data indicate that low Ca, high Al diet influences Mg concentration in bone and central nervous system (CNS) tissues and that a low Ca, high Al diet diminishes Mg in bone and CNS tissues, thereby inducing loss of calcification in bone and degeneration of CNS tissue due to alteration of the normal biological effects of Mg.

[Aluminum and the human body]. / Hliník a lidský organismus.

Aluminium is one of the trace elements in the human organism the presence of which is described as contamination. The authors describe the toxic action in subjects working in an environment contaminated with powdered aluminium or its compounds. Non-professional exposure is observed in subjects with renal failure as aluminium is retained, in particular in case of concurrent antacid therapy on the basis of aluminium salts. Dialyzation encephalopathy may develop, aluminium osteopathy and microcytic anaemia. The most effective prevention is dialysis using a dialyzation solution with a low aluminium content and elimination of aluminium binding phosphates. The results of hitherto accomplished studies call for further research into the action of this element on the human organism.

Sodium fluoride stimulates exocytosis at a late site of calcium interaction in stimulus-secretion coupling: studies with the RINm5F beta cell line.

In the insulin-secreting beta cell line RINm5F, sodium fluoride stimulated exocytosis in a concentration (5-15 mM)- and temperature-dependent manner. Depletion of aluminum with the chelator deferoxamine or addition of aluminum to the buffer failed to affect the NaF-stimulated insulin release. This suggests that stimulation of heterotrimeric G proteins or inhibition of phosphatases or other enzymes by fluoroaluminate, an analog of the phosphate moiety, is not involved in the insulinotropic action of NaF. Removal of extracellular Ca2+ suppressed the NaF-stimulated insulin release. However, nitrendipine, a blocker of L-type voltage-dependent Ca2+ channels, did not inhibit the NaF-stimulated insulin release and NaF did not cause any changes in the cytosolic free calcium concentration ([Ca2+]i). Decreasing [Ca2+]i with thapsigargin or increasing [Ca2+]i with ionomycin or a depolarizing concentration of KCl resulted in suppression or enhancement of NaF-stimulated insulin release, respectively. Furthermore, NaF enhanced Ca(2+)-induced insulin release in electrically permeabilized RINm5F cells. These findings indicate that the effect of NaF on exocytosis is dependent on [Ca2+]i, although NaF itself does not change [Ca2+]i. Inhibitors of protein kinase C, such as staurosporine and bisindolylmaleimide, in concentrations sufficient to block the effects of phorbol esters, did not attenuate the NaF-stimulated insulin release. Neither cellular cAMP content nor [3H]arachidonic acid release was increased by NaF. NaF-stimulated insulin release was synergistically enhanced by the activation of protein kinases A and C. Finally, trifluoperazine, an inhibitor of calmodulin and other Ca(2+)-binding proteins, inhibited the insulinotropic action of NaF in a concentration-dependent manner. Trifluoperazine (50 microM) and W-7 (100 microM) nullified the 10 mM NaF-stimulated insulin release. It is concluded that NaF evokes exocytosis by a novel mechanism of sensitization to Ca2+, possibly on a Ca(2+)-responsive protein that is sensitive to trifluoperazine and W-7, leading to exocytosis. Protein kinases A and C also act at this site or at a more distal point.

In vivo effect of beta 2-microglobulin on bone resorption.

beta 2-Microglobulin (beta 2-M) deposits have been found in the destructive bone lesions associated with dialysis-related amyloidosis. To examine whether beta 2-M can cause bone resorption in vivo, doses of beta 2-M alone were compared with parathyroid hormone (PTH), aluminum, and vehicle alone. Eleven injections of 10 micrograms each were made over a period of 56 hours into the subcutaneous tissue overlying the occipital region of mice. Using a computerized image analysis system we measured (1) periosteal and inner bone length, (2) bone marrow interface length, and (3) the extent of resorption along these surfaces expressed as percentage of total length. Injections of either beta 2-M or PTH were associated with 22% +/- 4% and 25% +/- 4% resorption of periosteal surface, respectively, and 15.9% +/- 2% and 19.9% +/- 5% resorption of marrow bone surfaces, respectively, compared with control. In contrast, aluminum did not increase bone resorption over controls. The simultaneous injection of calcitonin, an osteoclast inhibitor, with beta 2-M or PTH did not increase periosteal resorption over controls. The resorption of inner bone surface was similar in all groups. These studies show that beta 2-M and PTH cause bone resorption in the bone surfaces proximate to the site of injection. This suggests that beta 2-M may contribute to the development of the bone cysts in dialysis-related amyloidosis.

Total parenteral nutrition and its effects on bone metabolism.

Total parenteral nutrition (TPN) may affect bone metabolism in a variety of ways. These may include potential indirect effects such as on gastrointestinal hormone secretion, liver function, especially cytochrome P450 isoenzymes, metabolic biorhythms where established, and the continuous compared with the intermittent supply of nutrients. More substantial evidence exists for the reduction of bone formation, parathyroid hormone secretion, and calcitriol production in TPN patients along with high urinary calcium excretion. This review considers both aluminum loading and vitamin D sensitivity as etiologic factors and suggests that aluminum may have played a primary role in the pathogenesis of these abnormalities in bone and mineral metabolism, but that vitamin D may have potentiated the deleterious actions of aluminum. While the sources of aluminum contamination of TPN solutions have been identified and efforts are under way to reduce its contamination of TPN solutions, the persistence of low bone mass measurement in TPN patients is a problem that has been identified repeatedly, does not have a current explanation, and requires further study.

Multiple signaling pathways for Cl(-)-dependent depolarization of mesangial cells: role of Ca2+, PKC, and G proteins.

We have previously reported that vasopressin activates chloride channels, leading to depolarization of glomerular mesangial cells via both calcium-dependent and calcium-independent pathways (S.G. Kremer, W.V. Breuer, and K. L. Skorecki, J. Cell. Physiol. 138: 97-105, 1989). However, the calcium-independent pathways were not defined. Using fluorescent probes, we now demonstrate that activation of protein kinase C (PKC) results in cellular depolarization in the absence of a calcium signal. This depolarization is also mediated by an enhanced conductance to chloride. Downregulation of PKC partially attenuated but did not abolish the depolarization response to vasopressin. Depolarization persisted when, in addition, calcium responses were also abolished and prostaglandin production was eliminated, suggesting an additional pathway for depolarization. G protein activation by aluminum fluoride also resulted in cellular depolarization mediated by an enhanced conductance to chloride, which persisted when calcium and PKC-signaling pathways were eliminated. This suggests the presence of a calcium- and PKC-independent pathway for G protein-mediated chloride-dependent depolarization. These findings point to the presence of at least three separate signaling pathways available for the activation of mesangial cell chloride channels, i.e., calcium, PKC, and a G protein.

The role of aluminium and parathyroid hormone in erythropoietin resistance in haemodialysis patients.

Recombinant human erythropoietin (rHuEpo) is an effective therapy for anaemia in most patients with end-stage renal disease (ESRD). However, there remain a minority of patients with ESRD who are resistant to the effects of rHuEpo. The present study examined the role of aluminium overload and hyperparathyroidism of the biological effects of rHuEpo. Twenty-two patients aged 26-74 (mean 53 +/- SD 15.5) received rHuEpo 50-200 U/kg per week for 16.5 +/- 8.0 months (range 3-27). Haemoglobin was maintained at 11.5-13.0 g/dl by appropriate dose adjustment. Iron supplements were provided to maintain serum ferritin greater than 200 ng/ml. The mean time to rHuEpo response (Hb greater than 2 g/dl over baseline) was 6.1 +/- 2.6 weeks. Mean pretreatment serum aluminium correlated with time to Hb response (r = 0.48; P less than 0.05) and pretreatment mean corpuscular volume (r = 0.43; P less than 0.05) but not with eventual rHuEpo maintenance dose. PTH did not correlate with either Hb response or eventual maintenance rHuEpo dose. In summary, elevated serum aluminium concentrations were associated with an initial resistance to the biological effects of rHuEpo but had no effect on long-term dose requirements. In contrast, no impact of PTH on either immediate or long-term rHuEpo dose was evident.

Mechanisms of inhibition of calcification.

Mineralization processes in the body are controlled by physicochemical and cellular regulation of hydroxyapatite (HA) nucleators and inhibitors. The chemical mechanism of action of HA inhibitors has been studied in vitro using solution pH-stat techniques or Types I and II collagen gel diffusion systems. Three biologically relevant systems are used with these methodologies: (1) transformation of amorphous calcium phosphate (ACP) to crystalline HA; (2) direct formation of HA; and (3) growth of HA crystals. Several different mechanisms have been identified for HA inhibition. Condensed phosphates (containing P-O-P linkages) and diphosphonates (containing P-C-P linkages) bind strongly to the surface of forming HA nuclei and crystals and poison growth sites at concentrations as low as 10(-6) M, blocking HA formation. From this in vitro work, diphosphonates have been developed for the treatment of Paget's disease. Proteoglycans, found in cartilage, delay HA formation by a steric effect whereby large volumes of solution become unavailable for HA formation and growth as these enormous macromolecules tumble about. Mg ions enter the structure of forming HA nuclei by replacing Ca, resulting in a distorted atomic structure that slows subsequent growth to HA. Al ions delay HA formation, not by entering the structure of forming HA nuclei, but by adsorbing on the surface of growing HA crystals. Serum proteins slow the transformation of ACP to HA by adsorbing on the ACP surface, which decreases its dissolution rate. Metal-citrate complexes can inhibit HA formation and growth at concentrations as low as 10(-5) to 10(-6) M. Phosphorylated molecules such as acidic proline-rich phosphoproteins and statherins found in saliva suppress HA crystal growth on tooth surfaces by adsorbing on active surface sites. Future research in this field lies in the study of interactions of HA inhibitors found together in calcifying tissues.