High-Affinity Uranyl-Specific Antibodies Suitable for Cellular Imaging

Reisser-Rubrecht, Laetitia; Torne-Celer, Caroline; Rénier, Wendy; Averseng, Olivier; Plantevin, Sophie; Quéméneur, Éric; Bellanger, Laurent; Vidaud, Claude

doi:10.1021/tx700215e

Cited by 20 publications

(18 citation statements)

References 35 publications

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“…The weak interaction between Mab U08S and Cu-DCP, as observed using DFS, has also been observed from surface plasmon resonance experiments (5). However, no detectable interaction by surface plasmon resonance was observed for divalent metals complexed with Mab U04S, in agreement with our DFS results that show unbinding events between Mab U04S and Ni-DCP occurring rarely (,0.3% of total events; see Fig.…”

Section: The Uranyl Bonding Is Involved In a Single Unbinding Force Rsupporting

confidence: 91%

“…The very high apparent affinity of Mabs U04S and U08S toward UO 2 -DCP as measured in bulk solution (5), led us to postulate that such high affinity was gained from an enhanced association rate constant, probably driven by strong Coulombic interactions between uranyl and antibodies.…”

Section: The Energy Landscape Of Chelated-metal Complexed With Antibodymentioning

confidence: 99%

“…In aqueous solution, chelated uranyl ion (UO 21 2 ) is the most common species of uranium (2,3). To study biological targets of UO 21 2 ; such as proteins or DNA, the approach that at least two teams have adopted was to raise antibodies against the uranyl chelates (4,5) where UO 21 2 was attached to a dicarboxy-phenanthroline chelator (DCP) coupled to a protein carrier. Using this approach, our group has selected a set of monoclonal antibodies (Mabs) specific for binding with UO 2 -DCP (5), including U04S, U08S and PHE03S; Mab PHE03S was chosen also for its strong cross-reactivity with the chelator DCP.…”

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confidence: 99%

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Deciphering the Energy Landscape of the Interaction Uranyl-DCP with Antibodies Using Dynamic Force Spectroscopy

Teulon

Parot

Odorico

et al. 2008

Biophysical Journal

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Previous studies on molecular recognition of uranyl-DCP (dicarboxy-phenanthroline chelator) compound by two distinct monoclonal antibodies (Mabs U04S and U08S) clearly showed the presence of a biphasic shape in Bell-Evans' plots and an accentuated difference in slopes at the high loading rates. To further explore the basis in the slope difference, we have performed complementary experiments using antibody PHE03S, raised against uranyl-DCP but, presenting a strong cross-reactivity toward the DCP chelator. This work allowed us to obtain a reallocation of the respective contributions of the metal ion itself and that of the chelator. Results led us to propose a 2D schematic model representing two energy barriers observed in the systems Mabs U04S- and U08S-[UO(2)-DCP] where the outer barrier characterizes the interaction between UO(2) and Mab whereas the inner barrier characterizes the interaction between DCP and Mab. Using dynamic force spectroscopy, it is thus possible to dissect molecular interactions during the unbinding between proteins and ligands.

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Section: The Uranyl Bonding Is Involved In a Single Unbinding Force Rsupporting

confidence: 91%

Section: The Energy Landscape Of Chelated-metal Complexed With Antibodymentioning

confidence: 99%

mentioning

confidence: 99%

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Deciphering the Energy Landscape of the Interaction Uranyl-DCP with Antibodies Using Dynamic Force Spectroscopy

Teulon

Parot

Odorico

et al. 2008

Biophysical Journal

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“…Uranyl is expected to be coordinated by the side chains of two aspartates and two histidines at this site, while in the metal binding loop of calmodulin site 1, uranyl ligands may be provided by oxygen atoms from aspartate and/or peptide carbonyl groups. Although we cannot directly compare our results with those obtained by other measuring approaches, it is interesting to note that dissociation constants in the 10 −9 M to 10 −10 M range were reported for the interaction of monoclonal antibodies with uranyl complexed to dicarboxylic-phenanthroline derivatives [18], [22].…”

Section: Discussionmentioning

confidence: 72%

Modulating Uranium Binding Affinity in Engineered Calmodulin EF-Hand Peptides: Effect of Phosphorylation

et al. 2012

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To improve our understanding of uranium toxicity, the determinants of uranyl affinity in proteins must be better characterized. In this work, we analyzed the contribution of a phosphoryl group on uranium binding affinity in a protein binding site, using the site 1 EF-hand motif of calmodulin. The recombinant domain 1 of calmodulin from A. thaliana was engineered to impair metal binding at site 2 and was used as a structured template. Threonine at position 9 of the loop was phosphorylated in vitro, using the recombinant catalytic subunit of protein kinase CK2. Hence, the T9TKE12 sequence was substituted by the CK2 recognition sequence TAAE. A tyrosine was introduced at position 7, so that uranyl and calcium binding affinities could be determined by following tyrosine fluorescence. Phosphorylation was characterized by ESI-MS spectrometry, and the phosphorylated peptide was purified to homogeneity using ion-exchange chromatography. The binding constants for uranyl were determined by competition experiments with iminodiacetate. At pH 6, phosphorylation increased the affinity for uranyl by a factor of ∼5, from Kd = 25±6 nM to Kd = 5±1 nM. The phosphorylated peptide exhibited a much larger affinity at pH 7, with a dissociation constant in the subnanomolar range (Kd = 0.25±0.06 nM). FTIR analyses showed that the phosphothreonine side chain is partly protonated at pH 6, while it is fully deprotonated at pH 7. Moreover, formation of the uranyl-peptide complex at pH 7 resulted in significant frequency shifts of the νas(P-O) and νs(P-O) IR modes of phosphothreonine, supporting its direct interaction with uranyl. Accordingly, a bathochromic shift in νas(UO2)2+ vibration (from 923 cm−1 to 908 cm−1) was observed upon uranyl coordination to the phosphorylated peptide. Together, our data demonstrate that the phosphoryl group plays a determining role in uranyl binding affinity to proteins at physiological pH.

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“…Heavy‐metal immunoassays utilized anti‐heavy‐metal antibodies that monitored binding environment pollutants, Pb(II) , Hg(II) , As(IV, V), Cd(II) , Cu(II) , U(VI) , and rare heavy metals Ru(II) and In(III) . Uranyl‐specific antibodies suitable for cellular imaging were developed based on these studies. Antibodies against Zn(II) were successfully prepared in previous investigations .…”

Section: Introductionmentioning

confidence: 99%

Rapid superparamagnetic‐beads‐based automated immunoseparation of Zn‐proteins from Staphylococcus aureus with nanogram yield

et al. 2012

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Pathogenic bacteria have become a serious socio-economic concern. Immunomagnetic separation-based methods create new possibilities for rapidly recognizing many of these pathogens. The aim of this study was to use superparamagnetic particles-based fully automated instrumentation to isolate pathogen Staphylococcus aureus and its Zn(II) containing proteins (Zn-proteins). The isolated bacteria were immediately purified and disintegrated prior to immunoextraction of Zn-proteins by superparamagnetic beads modified with chicken anti-Zn(II) antibody. S. aureus culture was treated with ZnCl(2). Optimal pathogen isolation and subsequent disintegration assay steps were carried out with minimal handling. (i) Optimization of bacteria capturing: Superparamagnetic microparticles composed of human IgG were used as the binding surface for acquiring live S. aureus. The effect of antibodies concentration, ionic strength, and incubation time was concurrently investigated. (ii) Optimization of zinc proteins isolation: pure and intact bacteria isolated by the optimized method were sonicated. The extracts obtained were subsequently analyzed using superparamagnetic particles modified with chicken antibody against zinc(II) ions. (iii) Moreover, various types of bacterial zinc(II) proteins precipitations from particle-surface interactions were tested and associated protein profiles were identified using SDS-PAGE. Use of a robotic pipetting system sped up sample preparation to less than 4 h. Cell lysis and Zn-protein extractions were obtained from a minimum of 100 cells with sufficient yield for SDS-PAGE (tens ng of proteins). Zn(II) content and cell count in the extracts increased exponentially. Furthermore, Zn(II) and proteins balances were determined in cell lysate, extract, and retentate.

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High-Affinity Uranyl-Specific Antibodies Suitable for Cellular Imaging

Cited by 20 publications

References 35 publications

Deciphering the Energy Landscape of the Interaction Uranyl-DCP with Antibodies Using Dynamic Force Spectroscopy

Deciphering the Energy Landscape of the Interaction Uranyl-DCP with Antibodies Using Dynamic Force Spectroscopy

Modulating Uranium Binding Affinity in Engineered Calmodulin EF-Hand Peptides: Effect of Phosphorylation

Rapid superparamagnetic‐beads‐based automated immunoseparation of Zn‐proteins from Staphylococcus aureus with nanogram yield

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