Phosphoglycolate phosphatase (PGLP) dephosphorylates 2-phosphoglycolate to glycolate that can be further metabolized to glyoxylate by glycolate oxidase (GOX) via an oxidative reaction that uses O2 and releases H2O2. The oxidation of o-dianisidine by H2O2 catalyzed by a peroxidase can be followed in real time by an absorbance change at 440 nm. Based on these reactions, a spectrophotometric method for measuring PGLP activity using a coupled reaction with recombinant Arabidopsis thaliana GOX is described. This protocol has been used successfully with either purified PGLP or total soluble proteins extracted from Arabidopsis rosette leaves.

Domestication of CO2-fixation became a worldwide priority enhanced by the will to convert this greenhouse gas into fuels and valuable chemicals. Because of its high stability, CO2-activation/fixation represents a true challenge for chemists. Autotrophic microbial communities, however, perform these reactions under standard temperature and pressure. Recent discoveries shine light on autotrophic acetogenic bacteria and hydrogenotrophic methanogens, as these anaerobes use a particularly efficient CO2-capture system to fulfill their carbon and energy needs. While other autotrophs assimilate CO2 via carboxylation followed by a reduction, acetogens and methanogens do the opposite. They first generate formate and CO by CO2-reduction, which are subsequently fixed to funnel the carbon toward their central metabolism. Yet their CO2-reduction pathways, with acetate or methane as end-products, constrain them to thrive at the \"thermodynamic limits of Life\". Despite this energy restriction acetogens and methanogens are growing at unexpected fast rates. To overcome the thermodynamic barrier of CO2-reduction they apply different ingenious chemical tricks such as the use of flavin-based electron-bifurcation or coupled reactions. This mini-review summarizes the current knowledge gathered on the CO2-fixation strategies among acetogens. While extensive biochemical characterization of the acetogenic formate-generating machineries has been done, there is no structural data available. Based on their shared mechanistic similarities, we apply the structural information obtained from hydrogenotrophic methanogens to highlight common features, as well as the specific differences of their CO2-fixation systems. We discuss the consequences of their CO2-reduction strategies on the evolution of Life, their wide distribution and their impact in biotechnological applications.

The amino acid cysteine plays a major role in plant response to abiotic stress by being the donor of elemental sulfur for the sulfuration of the molybdenum cofactor, otherwise the last step of ABA biosynthesis, the oxidation of abscisic aldehyde, is inactivated. Additionally, cysteine serves as a precursor for the biosynthesis of glutathione, the reactive oxygen species scavenger essential for redox status homeostasis during stress. Cysteine is generated by the sulfate reductive pathway where sulfite oxidase (SO; EC 1.8.3.1) is an important enzyme in the homeostasis of sulfite levels (present either as a toxic intermediate in the pathway or as a toxic air pollutant that has penetrated the plant tissue via the stomata). SO is localized to the peroxisomes and detoxifies excess sulfite by catalyzing its oxidation to sulfate. Here we show a kinetic assay that relies on fuchsin colorimetric detection of sulfite, a substrate of SO activity. This SO assay is highly specific, technically simple, and readily performed in any laboratory.5\'-adenylylsulfate (APS) reductase (APR, E.C. 1.8.4.9) enzyme regulates a crucial step of sulfate assimilation in plants, algae and some human pathogens. The enzyme is upregulated in response to oxidative stress induced by abiotic stresses, such as salinity and hydrogen peroxide, to generate sulfite an intermediate for cysteine generation essential for the biosynthesis of glutathione, the hydrogen peroxide scavenger. Here we present two robust, sensitive, and simple colorimetric methods of APR activity based on sulfite determination by fuchsin.Sulfite reductase (SiR) is one of the key enzymes in the primary sulfur assimilation pathway. It has been shown that SiR is an important plant enzyme for protection plant against sulfite toxicity and premature senescence. Here we describe two methods for SiR activity determination: a kinetic assay using desalted extract and an in-gel assay using crude extract.Due to the energetically favorable equilibrium, sulfurtransferase (ST) activity measured as sulfite generation or consumption. Sulfite-generating ST activity is determined by colorimetric detection of SCN- formation at 460 nm as the red Fe(SCN)3 complex from cyanide and thiosulfate using acidic iron reagent. Sulfite-consuming (MST) activity is detected as sulfite disappearance in the presence of thiocyanate (SCN-) or as SCN- disappearance. To abrogate interfering SO activity, total ST activities is detected by inhibiting SO activity with tungstate.