Al-toxicity studies in yeast using gallium as an aluminum analogue

Ritchie, Raymond J.; Raghupathi, Shyam Sundar

doi:10.1007/s10534-007-9127-2

Cited by 9 publications

(4 citation statements)

References 48 publications

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“…There was also evidence that Ga did not affect the fertility of the snails to the same extent as Al. Similarly, Al is more toxic than Ga to the giant alga Chara coralline (Reid et al 1996), whilst Al and Ga exhibit similar levels of toxicity in yeast (Ritchie and Raghupathi 2008). There are few comparative data regarding the toxicity of Al and Ga in animals, but the observations from our study, as well as those above, indicate that the toxicity of Ga is at least no higher than that of Al and so would not differentially affect snail behaviour in any metal tracing experiment.…”

Section: Discussionsupporting

confidence: 56%

The suitability of gallium as a substitute for aluminum in tracing experiments

et al. 2009

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Aluminum is a toxic metal whose complex aquatic chemistry, mechanisms of toxicity and trophic transfer are not fully understood. The only isotope of Al suitable for tracing experiments in organisms-(26)Al-is a rare, costly radioisotope with a low emission energy, making its use difficult. Gallium shares a similar chemistry with Al and was therefore investigated as a potential substitute for Al for use in aquatic organisms. The freshwater snail, Lymnaea stagnalis was exposed to either Al or Ga (0.0135 mM) under identical conditions for up to 40 days. Behavioural toxicity, metal accumulation in the tissues, and sub-cellular partitioning of the metals were determined. Al was more toxic than Ga and accumulated to significantly higher levels in the soft tissues (P < 0.05). The proportion of Al in the digestive gland (DG; detoxificatory organ) relative to other tissues was significantly lower than that of Ga (P < 0.05) from day 14 onwards. There were also differences in the proportions of Al and Ga associated with heat stable proteins (HSPs) in the digestive gland, with significantly more HSP present in the DGs of snails exposed to Al, but significantly less Al than Ga associated with the HSP per unit mass protein present. From this evidence, we conclude that Ga may be of limited use as a tracer for Al in animal systems.

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Section: Discussionsupporting

confidence: 56%

The suitability of gallium as a substitute for aluminum in tracing experiments

et al. 2009

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“…The growth conditions of yeast at acidic pH (B4.0) are ideal for Al 3+ ] precipitates out. 9,10 Secondly, the organismal nature and genetically-modified resources of S. cerevisiae have been greatly explored for investigating a broad array of biological problems, such as oxidative stress and aluminium toxicity, carried out in our laboratory. 4,11 In this study, we aimed to identify Al 3+ transport-related genes by a detailed screening of the Al 3+ tolerant phenotype from the complete collection of yeast deletion mutants.…”

Section: Introductionmentioning

confidence: 99%

Identification of aluminium transport-related genes via genome-wide phenotypic screening of Saccharomyces cerevisiae

et al. 2014

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Genome-wide screening using gene deletion mutants has been widely carried out with numerous toxicants including oxidants and metal ions. The focus of such studies usually centres on identifying sensitive phenotypes against a given toxicant. Here, we screened the complete collection of yeast gene deletion mutants (5047) with increasing concentrations of aluminium sulphate (0.4, 0.8, 1.6 and 3.2 mM) in order to discover aluminium (Al(3+)) tolerant phenotypes. Fifteen genes were found to be associated with Al(3+) transport because their deletion mutants exhibited Al(3+) tolerance, including lem3Δ, hal5Δ and cka2Δ. Deletion of CKA2, a catalytic subunit of tetrameric protein kinase CK2, gives rise to the most pronounced resistance to Al(3+) by showing significantly higher growth compared to the wild type. Functional analysis revealed that both molecular regulation and endocytosis are involved in Al(3+) transport for yeast. Further investigations were extended to all the four subunits of CK2 (CKA1, CKA2, CKB1 and CKB2) and the other 14 identified mutants under a spectrum of metal ions, including Al(3+), Zn(2+), Mn(2+), Fe(2+), Fe(3+), Co(3+), Ga(3+), Cd(2+), In(3+), Ni(2+) and Cu(2+), as well as hydrogen peroxide and diamide, in order to unravel cross-tolerance amongst metal ions and the effect of the oxidants. Finally, the implication of the findings in Al(3+) transport for the other species like plants and humans is discussed.

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“…Particularly, during the hydrolysis stage, yeast can accelerate the reaction rates as hydrolysis often takes a longer time [45]. The spread of yeast is also possible because anaerobic digester media is usually enriched with nutrients from the hydrolysis and breakdown of degradable biomass [46]. The yeast aids in converting the degradable waste to neutral ethanol instead of propionic or butyric acid during the anaerobic digestion process [47][48][49][50][51].…”

Section: Introductionmentioning

confidence: 99%

Modeling and simulation of biomass anaerobic digestion for high biogas yield and CO2 mineralization

Mokraoui

Halilu

Hashim

et al. 2023

Mater Renew Sustain Energy

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Bioenergy is one of several renewable energy options derived from biomass that can help satisfy our energy needs. Anaerobic digestion is a viable method for producing bioenergy in the form of biogas from biomass. The anaerobic digestion process is challenged with low biogas recovery, and low-quality effluent or CO2 emission, which contribute to environmental pollution and the carbon footprint in the atmosphere. Computational process modelling and simulation can provide realistic information for dealing with the technological challenges involved with anaerobic digestion. In this study, modeling and simulation of the simplified anaerobic digestion process were done using SuperPro Designer software fed with biomass feedstock containing carbohydrates, proteins, and fats, as well as yeast, at 37 °C mesophilic temperature. The anaerobic digestion process yielded 89.655% of CH4 and 10.345% of CO2 and confirmed that the carbohydrate feedstock produces more CH4 composition in the biogas. Mineralization of CO2 using MgO yielded 0.23% MgCO3, consuming > 99% of the CO2 produced during the anaerobic digestion process. Environmental impact assessment of the effluent discharge yielded 0.142 kg Slds/L volatile solid with 6.01% COD reduction per batch of the anaerobic digestion process in an anaerobic digester with 90% (1.925 kg/batch) feedstock dosage. The data indicate that single-batch effluent cannot be discharged into the environment, hence indicating the possible recycling for multiple anaerobic digestion processing. The results are a significant guide for the realistic scalable production of high-quality biogas for bioenergy application, CO2 mineralization, and environmental remediation.

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Al-toxicity studies in yeast using gallium as an aluminum analogue

Cited by 9 publications

References 48 publications

The suitability of gallium as a substitute for aluminum in tracing experiments

The suitability of gallium as a substitute for aluminum in tracing experiments

Identification of aluminium transport-related genes via genome-wide phenotypic screening of Saccharomyces cerevisiae

Modeling and simulation of biomass anaerobic digestion for high biogas yield and CO2 mineralization

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