Validation of the Eclipse Farm 4G & COMET for Detection of Antibiotics in Raw Bovine Milk: AOAC Performance Tested MethodSM 022101.

BACKGROUND: The Eclipse Farm 4G test coupled to the COMET device allows for automatic and easy screening of a broad range of antimicrobials in raw bovine milk. All results obtained with this system are available in real-time through a smartphone application (App) and in the Test4all cloud platform. OBJECTIVE: The objective of this study was to validate Eclipse Farm 4G & COMET for the screening of antimicrobials in raw bovine milk according to AOAC Performance Tested MethodSM procedures. METHOD: The test is based on the inhibition of microbial growth of Geobacillus stearothermophilus in the presence of antimicrobials. When sample tubes are incubated in the absence of antibiotics, spores germinate and cells grow, changing the medium color from purple to yellow (negative result). The presence of antimicrobials in the milk sample hinders bacterial growth, preventing the tubes from changing color from purple to yellow (positive result). The COMET device automatically integrates all assay steps (incubation, time control, and results interpretation) and communications between the device, smartphone, and cloud. RESULTS: LODs and detection capabilities were confirmed to be at or below the European Union (EU) maximum residue limit (MRL) for most of the evaluated molecules representing the main families of antimicrobials (penicillins, cephalosporins, tetracyclines, sulfonamides, macrolides, and aminoglycosides). False-positive rates and the effect of potentially interfering substances showed sufficient selectivity/specificity. The Eclipse Farm 4G & COMET system was shown to be robust, consistent, and stable during shelf life. CONCLUSIONS: The Eclipse Farm 4G & COMET system has been shown to be suitable for screening antibiotics in raw bovine milk. HIGHLIGHTS: The assay is an automatic and easy system for the detection of a broad range of antibiotics in raw bovine milk consistent with EU MRLs and can provide results any time and anywhere through a smartphone App and a cloud platform.

Protein profile of Lupinus texensis phloem sap exudates: searching for Fe- and Zn-containing proteins.

The aim of this study was to obtain a comprehensive overview of the phloem sap protein profile of Lupinus texensis, with a special focus on proteins binding Fe and Zn. L. texensis was chosen as model plant given the simplicity to obtain exudates from sieve elements. Protein profiling by 2DE revealed 249 spots, and 54 of them were unambiguously identified by MALDI-MS and ESI-MS/MS. The largest number of identified protein species belongs to protein modification/turnover and general metabolism (19-21%), followed by redox homeostasis (9%) and defense and cell structural components (7%). This protein profile is similar to that reported in other plant species, suggesting that the phloem sap proteome is quite conserved. Staining of 2DE gels for Fe-containing proteins and affinity chromatography experiments revealed the presence of two low molecular weight Fe-binding proteins in phloem sap: a metallothionein-like protein type 2B identified in the Fe-affinity chromatography, and a second protein identified with both Fe staining methods. This protein species had a molecular weight of 13.5 kDa, a pI of 5.6 and 51% homology to a phloem-specific protein from Medicago truncatula. Zinc affinity chromatography revealed four Zn-binding proteins in phloem sap, one belonging to the dehydrin family and three Zn finger proteins.

Effects of cadmium on cork oak (Quercus suber L.) plants grown in hydroponics.

Cork oak (Quercus suber L.) is an autochthonous tree species that is being used for reforestation in heavy-metal-contaminated areas in Spain. A hydroponics experiment was carried out to characterize the effects of Cd on several morphological and physiological parameters in this species, including shoot length, nutrient concentrations and allocation in different organs, leaf pigment concentrations, photosynthetic efficiency, root ferric chelate reductase (FCR) activity and organic acid concentrations in xylem sap. Four different Cd treatments were applied, adding Cd chelated with EDTA or as chloride salt at two different concentrations (10 and 50 µM Cd). After 1 month of Cd treatment, plant growth was significantly inhibited in all treatments. Results indicate that Cd accumulates in all organs 7- to 500-fold when compared with control plants. The highest Cd concentration was found in the 50 µM CdCl(2) treatment, which led to concentrations of ~30, 123 and 1153 µg Cd g(-1) dry weight in leaves, stems and roots, respectively. In the strongest Cd treatments the concentrations of P and Ca decreased in some plant parts, whereas the Mn leaf concentrations decreased with three of the four Cd treatments applied. The concentrations of chlorophyll and carotenoids on an area basis decreased, whereas the (zeaxanthin plus antheraxanthin)/(total violaxanthin cycle carotenoids) ratio and the non-photochemical quenching increased significantly in all Cd treatments. Cadmium treatments caused significant increases in the activity of the enzyme FCR in roots and in the concentrations of organic acids in xylem sap. Some of the physiological changes found support the fact that Cd induces a deficiency of Fe in cork oak, although the plant Fe concentrations were not reduced significantly. At higher concentrations the effects of Cd were more pronounced, and were more marked when Cd was in the free ion form than when present in the form of Cd-EDTA.

Changes in the proteomic and metabolic profiles of Beta vulgaris root tips in response to iron deficiency and resupply.

BACKGROUND: Plants grown under iron deficiency show different morphological, biochemical and physiological changes. These changes include, among others, the elicitation of different strategies to improve the acquisition of Fe from the rhizosphere, the adjustment of Fe homeostasis processes and a reorganization of carbohydrate metabolism. The application of modern techniques that allow the simultaneous and untargeted analysis of multiple proteins and metabolites can provide insight into multiple processes taking place in plants under Fe deficiency. The objective of this study was to characterize the changes induced in the root tip proteome and metabolome of sugar beet plants in response to Fe deficiency and resupply. RESULTS: Root tip extract proteome maps were obtained by 2-D isoelectric focusing polyacrylamide gel electrophoresis, and approximately 140 spots were detected. Iron deficiency resulted in changes in the relative amounts of 61 polypeptides, and 22 of them were identified by mass spectrometry (MS). Metabolites in root tip extracts were analyzed by gas chromatography-MS, and more than 300 metabolites were resolved. Out of 77 identified metabolites, 26 changed significantly with Fe deficiency. Iron deficiency induced increases in the relative amounts of proteins and metabolites associated to glycolysis, tri-carboxylic acid cycle and anaerobic respiration, confirming previous studies. Furthermore, a protein not present in Fe-sufficient roots, dimethyl-8-ribityllumazine (DMRL) synthase, was present in high amounts in root tips from Fe-deficient sugar beet plants and gene transcript levels were higher in Fe-deficient root tips. Also, a marked increase in the relative amounts of the raffinose family of oligosaccharides (RFOs) was observed in Fe-deficient plants, and a further increase in these compounds occurred upon short term Fe resupply. CONCLUSIONS: The increases in DMRL synthase and in RFO sugars were the major changes induced by Fe deficiency and resupply in root tips of sugar beet plants. Flavin synthesis could be involved in Fe uptake, whereas RFO sugars could be involved in the alleviation of oxidative stress, C trafficking or cell signalling. Our data also confirm the increase in proteins and metabolites related to carbohydrate metabolism and TCA cycle pathways.

Time course induction of several key enzymes in Medicago truncatula roots in response to Fe deficiency.

Medicago truncatula constitutes a good model for Strategy I plants, since when this plant is challenged with Fe shortage the most important root physiological responses induced by Fe deficiency are developed, including the yellowing of root tips. A better understanding of the mechanisms involved in root adaptation to Fe deficiency in M. truncatula may strengthen our ability to enhance Fe efficiency responses in other plant species, especially in different agronomically relevant legumes. Riboflavin concentration, phosphoenolpyruvate carboxylase (EC 4.1.1.31) and Fe reductase activities, and acidification capacity have been determined in M. truncatula roots at different time points after imposing Fe deficiency. Root riboflavin concentrations increased with Fe deficiency and concomitantly MtDMRL was upregulated at the transcriptional level, supporting a role for flavins in the Fe deficiency response. Root Fe reductase and phosphoenolpyruvate carboxylase activities as well as acidification capacity were higher in roots of Fe-deficient than in control plants, and the corresponding genes, MtFRO1, MtPEPC1 and MtHA1 were also upregulated by Fe deficiency. Expression of these genes and their corresponding physiological activities followed different patterns over time, suggesting the existence of both transcriptional and post-transcriptional regulation.

Proteomic profiles of thylakoid membranes and changes in response to iron deficiency.

The proteomic profile of thylakoid membranes and the changes induced in that proteome by iron deficiency have been studied by using thylakoid preparations from Beta vulgaris plants grown in hydroponics. Two different 2-D electrophoresis approaches have been used to study these proteomes: isoelectrical focusing followed by SDS PAGE (IEF-SDS PAGE) and blue-native polyacrylamide gel electrophoresis followed by SDS PAGE (BN-SDS PAGE). These techniques resolved approximately 110-140 and 40 polypeptides, respectively. Iron deficiency induced significant changes in the thylakoid sugar beet proteome profiles: the relative amounts of electron transfer protein complexes were reduced, whereas those of proteins participating in leaf carbon fixation-linked reactions were increased. A set of polypeptides, which includes several enzymes related to metabolism, was detected in thylakoid preparations from Fe-deficient Beta vulgaris leaves by using BN-SDS PAGE, suggesting that they may be associated with these thylakoids in vivo. The BN-SDS PAGE technique has been proven to be a better method than IEF-SDS PAGE to resolve highly hydrophobic integral membrane proteins from thylakoid preparations, allowing for the identification of complexes and determination of their polypeptidic components.