Spatially resolved detection of small molecules from press-dried plant tissue using MALDI imaging.

Premise: Matrix-assisted laser desorption/ionization mass spectrometry imaging (MALDI-MSI) is a chemical imaging method that can visualize spatial distributions of particular molecules. Plant tissue imaging has so far mostly used cryosectioning, which can be impractical for the preparation of large-area imaging samples, such as full flower petals. Imaging unsectioned plant tissue presents its own difficulties in extracting metabolites to the surface due to the waxy cuticle. Methods: We address this by using established delipidation techniques combined with a solvent vapor extraction prior to applying the matrix with many low-concentration sprays. Results: Using this procedure, we imaged tissue from three different plant species (two flowers and one carnivorous plant leaf). Material factorization analysis of the resulting data reveals a wide range of plant-specific small molecules with varying degrees of localization to specific portions of the tissue samples, while facilitating detection and removal of signal from background sources. Conclusions: This work demonstrates applicability of MALDI-MSI to press-dried plant samples without freezing or cryosectioning, setting the stage for spatially resolved molecule identification. Increased mass resolution and inclusion of tandem mass spectrometry are necessary next steps to allow more specific and reliable compound identification.

Premisa: Matrix­assisted laser desorption/ionization mass spectrometry imaging (MALDI­MSI) es un método de imagen química que puede visualizar distribuciones espaciales de moléculas particulares. Hasta ahora, las imágenes de tejido vegetal han utilizado principalmente la criosección, lo cual puede ser poco práctico para la preparación de muestras de imágenes con áreas grandes, tales como los pétalos completos de una flor. La obtención de imágenes de tejido vegetal no seccionado presenta sus propias dificultades durante la extracción de metabolitos a la superficie, debido a la cutícula cerosa de la planta. Métodos: Abordamos esto usando técnicas establecidas de deslipidación combinados con una extracción de vapor por solvente antes de aplicar por aspersión la matriz en bajas concentraciones. Resultados: Usando este procedimiento, obtuvimos imágenes de tejido de tres especies de plantas diferentes (dos flores y una hoja de planta carnívora). Análisis de factorización material de los datos obtenidos revelaron una amplia gama de pequeñas moléculas específicas en plantas con diversos grados de localización en porciones específicas de las muestras de tejido, al igual que facilitó la detección y remoción de las señales de fondo. Conclusión: Nuestro trabajo demuestra la aplicabilidad de MALDI­MSI hacía muestras de plantas secadas a presión sin congelación o criosección, creando el marco para la identificación de moléculas resueltas espacialmente. Aumento de la resolución de masas e inclusión de la espectrometría de masas en tándem son pasos necesarios para obtener identificación de compuestos más específica y confiable.

Alternative pathway for dopamine production by acetogenic gut bacteria that O-Demethylate 3-Methoxytyramine, a metabolite of catechol O-Methyltransferase.

AIMS: The gut microbiota modulates dopamine levels in vivo, but the bacteria and biochemical processes responsible remain incompletely characterized. A potential precursor of bacterial dopamine production is 3-methoxytyramine (3MT); 3MT is produced when dopamine is O-methylated by host catechol O-methyltransferase (COMT), thereby attenuating dopamine levels. This study aimed to identify whether gut bacteria are capable of reverting 3MT to dopamine. METHODS AND RESULTS: Human faecal bacterial communities O-demethylated 3MT and yielded dopamine. Gut bacteria that mediate this transformation were identified as acetogens Eubacterium limosum and Blautia producta. Upon exposing these acetogens to propyl iodide, a known inhibitor of cobalamin-dependent O-demethylases, 3MT O-demethylation was inhibited. Culturing E. limosum and B. producta with 3MT afforded increased acetate levels as compared with vehicle controls. CONCLUSIONS: Gut bacterial acetogens E. limosum and B. producta synthesized dopamine from 3MT. This O-demethylation of 3MT was likely performed by cobalamin-dependent O-demethylases implicated in reductive acetogenesis. SIGNIFICANCE AND IMPACT OF THE STUDY: This is the first report that gut bacteria can synthesize dopamine by O-demethylation of 3MT. Owing to 3MT being the product of host COMT attenuating dopamine levels, gut bacteria that reverse this transformation-converting 3MT to dopamine-may act as a counterbalance for dopamine regulation by COMT.

Butenolide Synthesis from Functionalized Cyclopropenones.

A general method to synthesize substituted butenolides from hydroxymethylcyclopropenones is reported. Functionalized cyclopropenones undergo ring-opening reactions with catalytic amounts of phosphine, forming reactive ketene ylides. These intermediates can be trapped by pendant hydroxy groups to afford target butenolide scaffolds. The reaction proceeds efficiently in diverse solvents and with low catalyst loadings. Importantly, the cyclization is tolerant of a broad range of functional groups, yielding a variety of α- and γ-substituted butenolides.

Isomeric triazines exhibit unique profiles of bioorthogonal reactivity.

Expanding the scope of bioorthogonal reactivity requires access to new and mutually compatible reagents. We report here that 1,2,4-triazines can be tuned to exhibit unique reaction profiles with biocompatible strained alkenes and alkynes. Computational analyses were used to identify candidate orthogonal reactions, and the predictions were experimentally verified. Notably, 5-substituted triazines, unlike their 6-substituted counterparts, undergo rapid [4 + 2] cycloadditions with a sterically encumbered strained alkyne. This unique, sterically controlled reactivity was exploited for dual bioorthogonal labeling. Mutually orthogonal triazines and cycloaddition chemistries will enable new multi-component imaging applications.