Probing the Fate of Different Structures of Beta-Lactam Antibiotics: Hydrolysis, Mineral Capture, and Influence of Organic Matter

Klein, Annaleise R.; Sarri, Eirini; Kelch, Sabrina E.; Basinski, Jade J.; Vaidya, Shreya; Aristilde, Ludmilla

doi:10.1021/acsearthspacechem.1c00064

Cited by 20 publications

(19 citation statements)

References 89 publications

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“…Furthermore, at the targeted circumneutral pH for both of our experiments and modeling, Damonte et al (2007) and Khoury et al (2010) reported that glyphosate adsorption on montmorillonite or bentonite (an adsorbent clay composed primarily of montmorillonite) was about fourfold less compared with adsorption conducted at low pH (pH 4); this difference was attributable to interlayer adsorption, which was proposed to be minimal at neutral or high pH. This pH-dependent adsorption whereby adsorption and intercalation were significantly decreased at circumneutral and high pH values was also reported for other ionizable contaminants, such as tetracycline antibiotics (Aristilde & Sposito, 2010; Aristilde et al, 2016), fluoroquinolone antibiotics (Okaikue-Woodi et al, 2018), and β-lactam antibiotics (Klein et al, 2021). According to Khoury et al, 2010, pH values greater than the point-of-zero charge would result in deprotonated clay edges, which can thus repel negatively charged adsorptives, the point-of-zero charge of montmorillonite was reported to be 3.4 ± 0.2 (Ijagbemi et al, 2009).…”

Section: Construction Of Model Quartz and Montmorillonite Surfacesmentioning

confidence: 80%

Phosphonate herbicide interactions with quartz, montmorillonite, and quartz‐enriched agricultural soil

Glaser

Richards

Steenhius

et al. 2022

Soil Science Soc of Amer J

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Phosphonate‐based herbicides are extensively used in agriculture. Glyphosate was long considered immobile in soils due to strong complexation with metal oxides, but detection in agricultural effluents and surface waters points to glyphosate mobilization and transport. In particular, mechanisms of glyphosate adsorption and subsequent mobility from runoff‐prone soils enriched in quartz have not been fully elucidated. Here we used theoretical and experimental approaches to gain new insights on the soil mobility of glyphosate and two other phosphonate herbicides, glufosinate and fosamine. Molecular modeling simulations of optimized adsorbate complexes of the phosphonate herbicides with quartz and montmorillonite revealed Ca‐enhanced interactions for all three herbicides at both mineral interfaces, weak binding of Na‐complexed phosphonate herbicides on quartz, and more favorable interactions for glufosinate and fosamine with Na‐montmorillonite than for glyphosate. We conducted adsorption and desorption experiments to evaluate the mobility of glyphosate on quartz‐enriched agricultural soils. Consistent with our theoretical findings, adsorption experiments conducted with CaCl2 resulted in greater than a twofold increase in glyphosate retention compared with experiments with NaCl. The desorption experiments revealed release of about 30–90% of the initially bound glyphosate into solution, whereby Ca in the desorption solution promoted glyphosate mobility compared with Na. Furthermore, in all conditions, the relative initial wetness of the agricultural soil was correlated positively with the enhanced glyphosate mobilization, consistent with field‐scale reports that herbicide applied to soils following rain events were prone to runoff.

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Section: Construction Of Model Quartz and Montmorillonite Surfacesmentioning

confidence: 80%

Phosphonate herbicide interactions with quartz, montmorillonite, and quartz‐enriched agricultural soil

Glaser

Richards

Steenhius

et al. 2022

Soil Science Soc of Amer J

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“…The HPLC‐UV analysis shows, as a matter of fact, the formation of only one degradation product (Figure S12), which has been identified by HPLC‐ESI‐HRMS as the ion at m/z 414.0535 (Figure S13). This compound is produced by the hydrolysis of ceftriaxone at the sulfur atom of the carbamimidothioate group, previously characterized after hydrolysis at pH=5 after 12 days [43] …”

Section: Resultsmentioning

confidence: 99%

“…In turn, MOF 1 is also capable to degrade ceftriaxone, but following a different mechanism. Indeed, 1 is capable to efficiently hydrolyze ceftriaxone into thiotriazinone and 3-desacetyl cefotaxime, a reaction that without catalyst only occurs after 12 h. at pH = 5, [43] while leaving unchanged its four-membered β-lactam ring. Moreover, we have been capable to isolate and characterize, by single-crystal X-ray diffraction (SCXRD), a host guest aggregate containing MOF 1 and amoxicillin (see below, Figure 3), aiming at achieving unique snapshots of the hostguest interactions, ultimately responsible for the β-lactamase activity.…”

Section: Introductionmentioning

confidence: 99%

Degradation of Penicillinic Antibiotics and β‐Lactamase Enzymatic Catalysis in a Biomimetic Zn‐Based Metal–Organic Framework

Escamilla

Bartella

Sanz-Navarro

et al. 2023

Chemistry A European J

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β-Lactam antibiotics are one of the most commonly prescribed drugs to treat bacterial infections. However, their use has been somehow limited given the emergence of bacteria with resistance mechanisms, such as β-lactamases, which inactivate them by degrading their four-membered βlactam rings. So, a total knowledge of the mechanisms governing the catalytic activity of β-lactamases is required.Here, we report a novel Zn-based metal-organic framework (MOF, 1), possessing functional channels capable to accommodate and interact with antibiotics, which catalyze the selective hydrolysis of the penicillinic antibiotics amoxicillin and ceftriaxone. In particular, MOF 1 degrades, very efficiently, the four-membered β-lactam ring of amoxicillin, acting as a β-lactamase mimic, and expands the very limited number of MOFs capable to mimic catalytic enzymatic processes. Combined single-crystal X-ray diffraction (SCXRD) studies and density functional (DFT) calculations offer unique snapshots on the host-guest interactions established between amoxicillin and the functional channels of 1. This allows to propose a degradation mechanism based on the activation of a water molecule, promoted by a Zn-bridging hydroxyl group, concertedly to the nucleophilic attack to the carbonyl moiety and the cleaving of CÀ N bond of the lactam ring.

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“…This force field has been shown to model appropriately the hydration of metal cations and interaction of MONT with organic and inorganic adsorptives. − Four interlayer nanopore environments with different Na + populations were modeled: a fully hydrated Na-MONTat 1.55 nm d 001 with 4 Na + and 40 waters, and two partially hydrated Na-MONT at with 4 Na + and 20 waters or at 1.24 nm d 001 with 4 Na + and 10 waters, and dry Na-MONT at 0.96 nm d 001 with 4 Na + . Each of these four systems were generated using the adsorption locator module in Materials Studio as previously described …”

Section: Methodsmentioning

confidence: 99%

“…Each of these four systems were generated using the adsorption locator module in Materials Studio as previously described. 72 The CASTEP NMR module of Materials Studio was employed to calculate the chemical shielding tensor and electric field gradient for the Na + in systems mentioned above. 73,74 Periodic cells were generated from the prepared fully hydrated Na + and Na + -MONT systems using the crystal building function in Materials Studio.…”

Section: The Journal Of Physical Chemistry Cmentioning

confidence: 99%

Quantitative Spectroscopic Analysis of Water Populations in the Hydrated Nanopore Environments of a Natural Montmorillonite

et al. 2021

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Smectite clays are implicated in solute trapping in natural and engineered processes. Here we evaluated 23Na solid-state nuclear magnetic resonance (NMR) and thermogravimetric analysis-coupled mass spectrometry (TGA–MS) for quantitative analysis of a hydrated natural Na-montmorillonite equilibrated at different relative humidity (RH). Using X-ray diffraction, we determined predominantly large-sized (∼1.55 nm) interlayers at 93% and 75% RH, 2:1 ratio of medium-sized (∼1.23 nm) to large-sized interlayers at 55% RH, and 2:1 ratio of small-sized (<0.96 nm) to medium-sized interlayers at 11% RH. Informed by simulated NMR of differently hydrated model Na-MONT systems, the experimental 23Na NMR data revealed only fully hydrated Na+ populations at 93% RH, a 2:1 ratio of partially hydrated (outer-sphere) to mineral-bound (inner-sphere) Na+ populations at 55% RH and, remarkably, a near-equal proportion of these latter two Na+ populations at 11% RH. Between 93% and 11% RH, the TGA–MS data captured a 57% increase in tightly bound waters (water loss at 100–300 °C) but only a 22% decrease in freely exchangeable waters (water loss below 40 °C). The addition of exogenous NaCl altered the aforementioned hydration behaviors, particularly at low RH. Our findings of persisting hydrated environments despite interlayer collapse implied water populations incongruent with predictions from smectite interlayer nanopore size distributions.

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Probing the Fate of Different Structures of Beta-Lactam Antibiotics: Hydrolysis, Mineral Capture, and Influence of Organic Matter

Cited by 20 publications

References 89 publications

Phosphonate herbicide interactions with quartz, montmorillonite, and quartz‐enriched agricultural soil

Phosphonate herbicide interactions with quartz, montmorillonite, and quartz‐enriched agricultural soil

Degradation of Penicillinic Antibiotics and β‐Lactamase Enzymatic Catalysis in a Biomimetic Zn‐Based Metal–Organic Framework

Quantitative Spectroscopic Analysis of Water Populations in the Hydrated Nanopore Environments of a Natural Montmorillonite

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