Transport and metabolism of l-lactate occur in mitochondria from cerebellar granule cells and are modified in cells undergoing low potassium dependent apoptosis

Having confirmed that externally added l-lactate can enter cerebellar granule cells, we investigated whether and how l-lactate is metabolized by mitochondria from these cells under normal or apoptotic conditions.

(1)

l-lactate enters mitochondria, perhaps via an l-lactate/H⁺ symporter, and is oxidized in a manner stimulated by ADP. The existence of an l-lactate dehydrogenase, located in the inner mitochondrial compartment, was shown by immunological analysis. Neither the protein level nor the K_m and V_max values changed en route to apoptosis.

(2)

In both normal and apoptotic cell homogenates, externally added l-lactate caused reduction of the intramitochondrial pyridine cofactors, inhibited by phenylsuccinate. This process mirrored l-lactate uptake by mitochondria and occurred with a hyperbolic dependence on l-lactate concentrations. Pyruvate appeared outside mitochondria as a result of external addition of l-lactate. The rate of the process depended on l-lactate concentration and showed saturation characteristics. This shows the occurrence of an intracellular l-lactate/pyruvate shuttle, whose activity was limited by the putative l-lactate/pyruvate antiporter. Both the carriers were different from the monocarboxylate carrier.

(3)

l-lactate transport changed en route to apoptosis. Uptake increased in the early phase of apoptosis, but decreased in the late phase with characteristics of a non-competitive like inhibition. In contrast, the putative l-lactate/pyruvate antiport decreased en route to apoptosis with characteristics of a competitive like inhibition in early apoptosis, and a mixed non-competitive like inhibition in late apoptosis.

     

Oxidation of arsenite to arsenate by a bacterium isolated from an aquatic environment

Arsenic is ubiquitous in the biosphere and frequently reported to be an environmental pollutant. Global cycling of arsenic is affected by microorganisms. This paper describes a new bacterial strain which is able to efficiently oxidize arsenite (As[III]) into arsenate (As[V]) in liquid medium. The rate of the transformation depends on the cell density. Arsenic species were separated by high performance liquid chromatography (HPLC) and quantified by inductively coupled plasma-atomic emission spectrometry (ICP-AES). The strain also exhibits high minimum inhibitory concentrations (MICs) for As[III] (6.65 mM (500 mg L^-1)) and other heavy metals, such as cadmium (1.42 mM (160 mg L^-1)) or lead (1.20 mM (250 mg L^-1)). Partial identification of the strain revealed a chemoorganotrophic, Gram-negative and motile rod. The results presented here demonstrate that this strain could represent a good candidate for arsenic remediation in heavily polluted sites.     

Role of conserved histidine residues in metalloactivation of the ArsA ATPase

The ArsA ATPase is the catalytic subunit of a pump that is responsible for resistance to arsenicals and antimonials in Escherichia coli. Arsenite or antimonite allosterically activates the ArsA ATPase activity. ArsA homologues from eubacteria, archaea and eukarya have a signature sequence (DTAPTGHT) that includes a conserved histidine. The ArsA ATPase has two such conserved motifs, one in the NH₂-terminal (A1) half and the other in the COOH-terminal (A2) half of the protein. These sequences have been proposed to be signal transduction domains that transmit the information of metal occupancy at the allosteric to the catalytic site to activate ATP hydrolysis. The role of the conserved residues His148 and His453, which reside in the A1 and A2 signal transduction domains respectively, was investigated by mutagenesis to create H148A, H453A or H148A/H453A ArsAs. Each altered protein exhibited a decrease in the V _max of metalloid-activated ATP hydrolysis, in the order wild type ArsA>H148A>H453A>H148A/H453A. These results suggest that the histidine residues play a role in transmission of the signal between the catalytic and allosteric sites.     

Arsenic toxicity: a heart-breaking saga of a freshwater mollusc

The freshwater wetland systems of India is a complex habitat that supports a broad range of diverse species including molluscs, which play an important role in supplementing third world countries. In the arsenic affected flood plains of West Bengal, a huge amount of arsenic laden groundwater is raised for the purpose of irrigation. Agricultural runoffs and flood water movement during monsoon may cause accumulation of arsenic in the adjacent freshwater aquifers, the common habitat of Lamellidens marginalis (Mollusca; Bivalvia; Eulamellibranchiata), a filter feeder, sensitive to altered environmental conditions. To examine the nature of toxicity induced by inorganic arsenic on both the haemocytes and tissues of the invertebrate heart, the animals were exposed to five different sublethal concentrations of sodium arsenite for a maximum time span of 30 days in vitro. Significant differences were recorded in the total haemocyte count, biochemical and histopathological parameters of the heart of L. marginalis under the arsenic induced stress. Our observations indicate the development of profound haematopoietic and cardiac stress under the sublethal inorganic arsenite exposure and it also implies the nature of risk imposed on the freshwater aquatic ecosystem under potential arsenic contamination.     

构建一种检测水中As3+的敏感型大肠杆菌

为构建一种敏感性强、特异性好的检测砷离子的大肠杆菌荧光报告菌株,本研究利用基因敲除技术,敲除了大肠杆菌中负责向胞外转运砷离子的ars B基因,构建对As~(3+)敏感的菌株;利用egfp基因作为报告基因,构建融合检测载体p ET28b-Pars-ars R-egfp。然后将检测载体p ET28b-Pars-ars R-egfp转化至ars B基因敲除菌中完成敏感型As~(3+)检测菌株的构建。接着对此微生物传感器进行了检测条件的优化,以及线性检测范围、最低检出限、特异性等性能的确定。研究结果表明,与利用野生大肠杆菌作为检测宿主相比,此敏感型砷检测菌株对检测As~(3+)的灵敏度有显著提高,最适检测As~(3+)浓度范围为0.013-42.71μmol/L,最低检出下限为5.13 nmol/L。因此,本研究利用基因敲除技术对大肠杆菌进行改造,成功地提高了砷检测微生物传感器的灵敏度,为重金属微生物传感器的优化研究工作提供了有用方案。     

Arsenate reduction: thiol cascade chemistry with convergent evolution

The frequent abundance of arsenic in the environment has guided the evolution of enzymes for the reduction of arsenate. The arsenate reductases (ArsC) from different sources have unrelated sequences and structural folds, and can be divided into different classes on the basis of their structures, reduction mechanisms and the locations of catalytic cysteine residues. The thioredoxin-coupled arsenate reductase class is represented by Staphylococcus aureus pI258 ArsC and Bacillus subtilis ArsC. The ArsC from Escherichia coli plasmid R773 and the eukaryotic ACR2p reductase from Saccharomyces cerevisiae represent two distinct glutaredoxin-linked ArsC classes. All are small cytoplasmic redox enzymes that reduce arsenate to arsenite by the sequential involvement of three different thiolate nucleophiles that function as a redox cascade. In contrast, the ArrAB complex is a bacterial heterodimeric periplasmic or a surface-anchored arsenate reductase that functions as a terminal electron acceptor and transfers electrons from the membrane respiratory chain to arsenate. Finally, the less well documented arsenate reductase activity of the monomeric arsenic(III) methylase, which is an S-adenosylmethionine (AdoMet)-dependent methyltransferase. After each oxidative methylation cycle and before the next methylation step, As(V) is reduced to As(III). Methylation by this enzyme is also considered an arsenic-resistance mechanism for bacteria, fungi and mammals.     

An insect model for assessing oxidative stress related to arsenic toxicity

The potential usefulness of an insect model to evaluate oxidative stress induced by environmental pollutants was examined with trivalent arsenic (As³⁺, NaAsO₂) and pentavalent arsenic (As⁵⁺, Na₂HAsO₄) in adult female house flies, Musca domestica, and fourth-instar cabbage loopers, Trichoplusia ni. M. domestica was highly susceptible to both forms of arsenic following 48 h exposure in the drinking water with LC₅₀s of 0.008 and 0.011% w/v for As³⁺ and As⁵⁺, respectively. T. ni larvae were susceptible to dietary As³⁺ with an LC₅₀ of 0.032% w/w but seem to tolerate As⁵⁺ well with an LC₅₀ of 0.794% concentration after 48 h exposure. The minimally acute LC₅ dose of both As³⁺ and As⁵⁺ varied considerably but averaged 0.005% for both insects. The potential of both valencies of arsenic for inducing oxidative stress in the insects exposed ad libitum to approximately LC₅ levels was assessed. The parameters examined were the alterations of the antioxidant enzyme activities of superoxide dismutase (SOD), catalase (CAT), glutathione transferase (GST), the peroxidase activity of glutathione transferase (GSTPX), and glutathione reductase (GR), and increases in lipid peroxidation and protein oxidation. SOD (1.3-fold), GST (1.6-fold), and GR (1.5-fold) were induced by As³⁺ in M. domestica but CAT and GSTPX were not affected. As⁵⁺ had no effect on M. domestica. In T. ni, the antioxidant enzyme activities were not affected by As³⁺ except for SOD which was suppressed by 29.4% and GST which was induced by 1.4-fold. As⁵⁺ had no effect except the suppression of SOD by 41.2%. Lipid peroxidation and protein oxidation, which represent stronger indices of oxidative stress, were elevated in both insects by up to 2.9-fold. However, based on the antioxidant enzyme response to the arsenic anions, the mode of action of arsenic induced oxidative stress may differ between the two insects. Until this aspect is further clarified, evidence at this time favors the prospect of As³⁺ as a pro-oxidant, especially for M. domestica. © 1995 Wiley-Liss, Inc.     

Expression of tobacco cDNA encoding phytochelatin synthase promotes tolerance to and accumulation of Cd and As inSaccharomyces cerevisiae

The first tobacco cDNA encoding phytochelatin synthase (NtPCS1) has been cloned by complementing the YCF1 (vacuolar ABC type transporter)-depleting yeast mutant DTY167 with an expression library fromNicotiana tabacum. When NtPCSI was over-expressed in DTY165 (WT) and DTY167 (mutant), tolerance to and the accumulation of cadmium (Cd) were enhanced. Interestingly, its expression promoted these responses as well to arsenic (As), but only in DTY167. We conclude thatNtPCS1 plays a role in tolerance to and the accumulation of both toxic metals inSaccharomyces cerevisiae. These authors contributed equally to the work.     

Restoration of p53 tumor suppressor pathway in human cervical carcinoma cells by sodium arsenite

In most cervical cancer cells, p53 and Rb are disrupted by human papillomaviruses (HPVs) E6 and E7, respectively. Restoration of p53 or Rb function by blocking E6/p53 or E7/Rb pathway might be a potential therapeutic purpose for these cancer cells. Treatment with sodium arsenite (SA) resulted in significant repression of E6 and E7 mRNA levels in SiHa cells. After E6 and E7 repression, p53 was dramatically induced and accumulated in cellular nuclei and Rb was also induced. Two p53-responsive genes, p21(waf1/cip1) and mdm2, were induced after SA treatment. Furthermore, SA also reduced the expressions of Cdc25A and cyclin B, blocked cell cycle progression at G2/M phase, and induced apoptosis in SiHa cells. SA-induced apoptosis was greatly reduced by expression of a dominant-negative mutated p53. In this study, we have first demonstrated that SA did repress E6 and E7 oncogenes, restore the p53 tumor suppressor pathway and induce apoptosis in SiHa cells. Therefore, it would be a potential strategy to promote SA as therapeutic purpose for HPV-positive cancer cells.