Metabolic Labeling Strategy Research Articles

Site-Specific Location of Black Phosphorus Quantum Dot Cluster-Based Nanocomplexes for Synergistic Ion Channel Therapy and Hypoxic Microenvironment Activated Chemotherapy.

The spatiotemporal regulation of ion transport in living cell membrane channels has immense potential for providing novel therapeutic approaches for the treatment of currently intractable diseases. So far, most strategies suffer from uncontrolled ion transport and limited tumor therapy effects. On the premise of low toxicity to healthy tissues, enhancing the degree of ion overloading and the effect of tumor treatment still remains a challenging concern. Herein, an innovative strategy for synergistic ion channel therapy and hypoxic microenvironment activated chemotherapy is proposed. Biocompatible AQ4N/black phosphorus quantum dot clusters@liposomes (AQ4N/BPCs@Lip) nanocomplexes are site-specifically immobilized on the living cell membrane by a metabolic labeling strategy, eliminating the need for modifying or genetically encoding channel structures. Ascribing to the localized temperature increase of BPCs under NIR light irradiation, Ca2+ overinflux can be remotely controlled and the overloading degree was increased; moreover, the local released AQ4N can only be activated in the tumor cell, while it has no toxicity to normal cells. Compared with single intracellular Ca2+ overloading, the tumor cell viabilities decrease 2-fold with synergetic Ca2+ overloading-induced ion channel therapy and hypoxic microenvironment activated chemotherapeutics. Our study demonstrates the example of a remote-controlled ion influx and drug delivery system for tumor therapy.

Cyclopropenes as Chemical Reporters for Dual Bioorthogonal and Orthogonal Metabolic Labeling of DNA.

Dual bioorthogonal labeling enables the investigation and understanding of interactions in the biological environment that are not accessible by a single label. However, applying two bioorthogonal reactions in the same environment remains challenging due to cross-reactivity. We developed a pair of differently modified 2'-deoxynucleosides that solved this issue for dual and orthogonal labeling of DNA. Inverse-electron demand Diels-Alder and photoclick reactions were combined to attach two different fluorogenic labels to genomic DNA in cells. Using a small synthetic library of 1- and 3-methylcyclopropenyl-modified 2'-deoxynucleosides, two 2'-deoxyuridines were identified to be the fastest-reacting ones for each of the two bioorthogonal reactions. Their orthogonal reactivity could be evidenced in vitro. Primer extension experiments were performed with both 2'-deoxyuridines investigating their replication properties as substitutes for thymidine and evaluating subsequent labeling reactions on the DNA level. Finally, dual, orthogonal and metabolic fluorescent labeling of genomic DNA was demonstrated in HeLa cells. An experimental procedure was developed combining intracellular transport and metabolic DNA incorporation of the two 2'-deoxyuridines with the subsequent dual bioorthogonal labeling using a fluorogenic cyanine-styryl tetrazine and a fluorogenic pyrene-tetrazole. These results are fundamental for advanced metabolic labeling strategies for nucleic acids in the future, especially for live cell experiments.

Cyclopropene als Chemische Reporter für die Duale Bioorthogonale und Orthogonale Metabolische Markierung von DNA

AbstractDie duale bioorthogonale Markierung ermöglicht die Untersuchung und das Verständnis von Wechselwirkungen in der biologischen Umgebung, die mit einer einzigen Markierung nicht zugänglich sind. Eine Herausforderung bleibt jedoch die Anwendung von zwei bioorthogonalen Reaktionen in der gleichen Umgebung aufgrund von Kreuzreaktivität. Um dieses Problem für die duale und orthogonale Markierung von DNA zu lösen, haben wir zwei unterschiedlich modifizierte 2′‐Desoxynukleoside entwickelt. Mit Hilfe der Diels‐Alder‐Reaktion mit inversem Elektronenbedarf und Photoklick‐Reaktion wurde genomische DNA in Zellen mit zwei verschiedenen fluorogenen Markern verknüpft. Aus einer kleinen synthetischen Bibliothek aus 1‐ und 3‐methylcyclopropenyl‐modifizierten 2′‐Desoxynukleosiden wurden zwei 2′‐Desoxyuridine identifiziert, die am schnellsten in jeweils einer der beiden bioorthogonalen Reaktionen reagieren. Ihre orthogonale Reaktivität konnte in vitro nachgewiesen werden. Ihre Replikationseigenschaften als Ersatz für Thymidin wurden in Primerverlängerungsexperimenten untersucht, um die anschließenden Markierungsreaktionen an DNA abzuschätzen. Schließlich wurde eine duale, orthogonale und metabolische Fluoreszenzmarkierung von genomischer DNA in HeLa‐Zellen nachgewiesen. Es wurde ein experimentelles Protokoll entwickelt, das den intrazellulären Transport und den metabolischen DNA‐Einbau der beiden 2′‐Desoxyuridine mit der anschließenden dualen bioorthogonalen Markierung unter Verwendung eines fluorogenen Cyanin‐Styryl‐Tetrazins und eines fluorogenen Pyren‐Tetrazols kombiniert. Diese Ergebnisse sind von grundlegender Bedeutung für fortgeschrittene metabolische Markierungsstrategien für Nukleinsäuren in der Zukunft, insbesondere in lebenden Zellen.

ZDHHC20-driven S-palmitoylation of CD80 is required for its costimulatory function.

CD80 is a transmembrane glycoprotein belonging to the B7 family, which has emerged as a crucial molecule in T cell modulation via the CD28 or CTLA4 axes. CD80-involved regulation of immune balance is a finely tuned process and it is important to elucidate the underlying mechanism for regulating CD80 function. In this study we investigated the post-translational modification of CD80 and its biological relevance. By using a metabolic labeling strategy, we found that CD80 was S-palmitoylated on multiple cysteine residues (Cys261/262/266/271) in both the transmembrane and the cytoplasmic regions. We further identified zDHHC20 as a bona fide palmitoyl-transferase determining the S-palmitoylation level of CD80. We demonstrated that S-palmitoylation protected CD80 protein from ubiquitination degradation, regulating the protein stability, and ensured its accurate plasma membrane localization. The palmitoylation-deficient mutant (4CS) CD80 disrupted these functions, ultimately resulting in the loss of its costimulatory function upon T cell activation. Taken together, our results describe a new post-translational modification of CD80 by S-palmitoylation as a novel mechanism for the regulation of CD80 upon T cell activation.

Bioorthogonal Metabolic Labeling of the Virulence Factor Phenolic Glycolipid in Mycobacteria.

Surface lipids on pathogenic mycobacteria modulate infection outcomes by regulating host immune responses. Phenolic glycolipid (PGL) is a host-modulating surface lipid that varies among clinical Mycobacterium tuberculosis strains. PGL is also found in Mycobacterium marinum, where it promotes infection of zebrafish through effects on the innate immune system. Given the important role this lipid plays in the host-pathogen relationship, tools for profiling its abundance, spatial distribution, and dynamics are needed. Here, we report a strategy for imaging PGL in live mycobacteria using bioorthogonal metabolic labeling. We functionalized the PGL precursor p-hydroxybenzoic acid (pHB) with an azide group (3-azido pHB). When fed to mycobacteria, 3-azido pHB was incorporated into the cell surface, which could then be visualized via the bioorthogonal conjugation of a fluorescent probe. We confirmed that 3-azido pHB incorporates into PGL using mass spectrometry methods and demonstrated selectivity for PGL-producing M. marinum and M. tuberculosis strains. Finally, we applied this metabolic labeling strategy to study the dynamics of PGL within the mycobacterial membrane. This new tool enables visualization of PGL that may facilitate studies of mycobacterial pathogenesis.

Development and Applications of D-Amino Acid Derivatives-based Metabolic Labeling of Bacterial Peptidoglycan.

Peptidoglycan, an essential component within the cell walls of virtually all bacteria, is composed of glycan strands linked by stem peptides that contain D-amino acids. The peptidoglycan biosynthesis machinery exhibits high tolerance to various D-amino acid derivatives. D-amino acid derivatives with different functionalities can thus be specifically incorporated into and label the peptidoglycan of bacteria, but not the host mammalian cells. This metabolic labeling strategy is highly selective, highly biocompatible, and broadly applicable, which has been utilized in various fields. This review introduces the metabolic labeling strategies of peptidoglycan by using D-amino acid derivatives, including one-step and two-step strategies. In addition, we emphasize the various applications of D-amino acid derivative-based metabolic labeling, including bacterial peptidoglycan visualization (existence, biosynthesis, and dynamics, etc.), bacterial visualization (including bacterial imaging and visualization of growth and division, metabolic activity, antibiotic susceptibility, etc.), pathogenic bacteria-targeted diagnostics and treatment (positron emission tomography (PET) imaging, photodynamic therapy, photothermal therapy, gas therapy, immunotherapy, etc.), and live bacteria-based therapy. Finally, a summary of this metabolic labeling and an outlook is provided.

Intestinal Translocation of Live Porphyromonas gingivalis Drives Insulin Resistance.

Periodontitis has been emphasized as a risk factor of insulin resistance-related systemic diseases. Accumulating evidence has suggested a possible "oral-gut axis" linking oral infection and extraoral diseases, but it remains unclear whether periodontal pathogens can survive the barriers of the digestive tract and how they play their pathogenic roles. The present study established a periodontitis mouse model through oral ligature plus Porphyromonas gingivalis inoculation and demonstrated that periodontitis aggravated diet-induced obesity and insulin resistance, while also causing P. gingivalis enrichment in the intestine. Metabolic labeling strategy validated that P. gingivalis could translocate to the gastrointestinal tract in a viable state. Oral administration of living P. gingivalis elicited insulin resistance, while administration of pasteurized P. gingivalis had no such effect. Combination analysis of metagenome sequencing and nontargeted metabolomics suggested that the tryptophan metabolism pathway, specifically indole and its derivatives, was involved in the pathogenesis of insulin resistance caused by oral administration of living P. gingivalis. Moreover, liquid chromatography-high-resolution mass spectrometry analysis confirmed that the aryl hydrocarbon receptor (AhR) ligands, mainly indole acetic acid, tryptamine, and indole-3-aldehyde, were reduced in diet-induced obese mice with periodontitis, leading to inactivation of AhR signaling. Supplementation with Ficz (6-formylindolo (3,2-b) carbazole), an AhR agonist, alleviated periodontitis-associated insulin resistance, in which the restoration of gut barrier function might play an important role. Collectively, these findings reveal that the oral-gut translocation of viable P. gingivalis works as a fuel linking periodontitis and insulin resistance, in which reduction of AhR ligands and inactivation of AhR signaling are involved. This study provides novel insight into the role of the oral-gut axis in the pathogenesis of periodontitis-associated comorbidities.

Metabolic labeling of peptidoglycan enabled optical analysis of probiotic vitality.

The growing awareness of the health benefits associated with probiotics has led to an increasing interest in probiotic products. To develop probiotic functional foods that deliver health benefits, it is essential to characterize both probiotic viability (the ability to survive) and vitality (the ability to remain active and effective). However, traditional probiotic assays only provide limited information about their survival state. To gain a comprehensive understanding of probiotic states, a D-amino-acid-based metabolic labeling strategy was applied to quantitatively depict probiotic vitality. In this approach, probiotics were first metabolically incorporated with azido-modified D-lysine and then labeled with dibenzocyclooctyne-sulfo-Cy5 through click chemistry. This two-step labeling process provides a visual representation of the metabolic levels of probiotics as well as the bacterial membrane integrity. Besides, this method is capable of characterizing the influence of various environmental conditions, from manufacturing to oral administration, on probiotic vitality. With its rapid detection process and general applicability, this strategy has the potential to be widely implemented in the food industry for probiotic vitality evaluation.

Glycan/Protein-Stable Isotope Labeling in Cell Culture for Enabling Concurrent Quantitative Glycomics/Proteomics/Glycoproteomics.

The complexity and heterogeneity of protein glycosylation present an analytical challenge to the studies of characterization and quantitation. Various LC-MS-based quantitation strategies have emerged in recent decades. Metabolic stable isotope labeling has been developed to enhance the accurate LC/MS-based quantitation between different cell lines. Stable isotope labeling by amino acids in a cell culture (SILAC) is the most widely used metabolic labeling method in proteomic analysis. However, it can only label the peptide backbone and is thus limited in glycomic studies. Here, we present a metabolic isotope labeling strategy, named GlyProSILC (Glycan Protein Stable Isotope Labeling in Cell Culture), that can label both the glycan motif and peptide backbone from the same batch of cells. It was performed by feeding cells with a heavy medium containing amide-15N-glutamine, 13C6-arginine (Arg6), and 13C6-15N2-lysine (Lys8). No significant change of cell line metabolism after GlyProSILC labeling was observed based on transcriptomic, glycomic, and proteomic data. The labeling conditions, labeling efficiency, and quantitation accuracy were investigated. After quantitation correction, we simultaneously quantified 62 N-glycans, 574 proteins, and 344 glycopeptides using the same batch of mixed 231BR/231 cell lines. So far, GlyProSILC provides an accurate and effective quantitation approach for glycomics, proteomics, and glycoproteomics in a cell culture system.

Chemoproteomic Approaches to Studying RNA Modification-Associated Proteins.

The function of cellular RNA is modulated by a host of post-transcriptional chemical modifications installed by dedicated RNA-modifying enzymes. RNA modifications are widespread in biology, occurring in all kingdoms of life and in all classes of RNA molecules. They regulate RNA structure, folding, and protein-RNA interactions, and have important roles in fundamental gene expression processes involving mRNA, tRNA, rRNA, and other types of RNA species. Our understanding of RNA modifications has advanced considerably; however, there are still many outstanding questions regarding the distribution of modifications across all RNA transcripts and their biological function. One of the major challenges in the study of RNA modifications is the lack of sequencing methods for the transcriptome-wide mapping of different RNA-modification structures. Furthermore, we lack general strategies to characterize RNA-modifying enzymes and RNA-modification reader proteins. Therefore, there is a need for new approaches to enable integrated studies of RNA-modification chemistry and biology.In this Account, we describe our development and application of chemoproteomic strategies for the study of RNA-modification-associated proteins. We present two orthogonal methods based on nucleoside and oligonucleotide chemical probes: 1) RNA-mediated activity-based protein profiling (RNABPP), a metabolic labeling strategy based on reactive modified nucleoside probes to profile RNA-modifying enzymes in cells and 2) photo-cross-linkable diazirine-containing synthetic oligonucleotide probes for identifying RNA-modification reader proteins.We use RNABPP with C5-modified cytidine and uridine nucleosides to capture diverse RNA-pyrimidine-modifying enzymes including methyltransferases, dihydrouridine synthases, and RNA dioxygenase enzymes. Metabolic labeling facilitates the mechanism-based cross-linking of RNA-modifying enzymes with their native RNA substrates in cells. Covalent RNA-protein complexes are then isolated by denaturing oligo(dT) pulldown, and cross-linked proteins are identified by quantitative proteomics. Once suitable modified nucleosides have been identified as mechanism-based proteomic probes, they can be further deployed in transcriptome-wide sequencing experiments to profile the substrates of RNA-modifying enzymes at nucleotide resolution. Using 5-fluorouridine-mediated RNA-protein cross-linking and sequencing, we analyzed the substrates of human dihydrouridine synthase DUS3L. 5-Ethynylcytidine-mediated cross-linking enabled the investigation of ALKBH1 substrates. We also characterized the functions of these RNA-modifying enzymes in human cells by using genetic knockouts and protein translation reporters.We profiled RNA readers for N6-methyladenosine (m6A) and N1-methyladenosine (m1A) using a comparative proteomic workflow based on diazirine-containing modified oligonucleotide probes. Our approach enables quantitative proteome-wide analysis of the preference of RNA-binding proteins for modified nucleotides across a range of affinities. Interestingly, we found that YTH-domain proteins YTHDF1/2 can bind to both m6A and m1A to mediate transcript destabilization. Furthermore, m6A also inhibits stress granule proteins from binding to RNA.Taken together, we demonstrate the application of chemical probing strategies, together with proteomic and transcriptomic workflows, to reveal new insights into the biological roles of RNA modifications and their associated proteins.

A pathogen-specific isotope tracing approach reveals metabolic activities and fluxes of intracellular Salmonella.

Pathogenic bacteria proliferating inside mammalian host cells need to rapidly adapt to the intracellular environment. How they achieve this and scavenge essential nutrients from the host has been an open question due to the difficulties in distinguishing between bacterial and host metabolites in situ. Here, we capitalized on the inability of mammalian cells to metabolize mannitol to develop a stable isotopic labeling approach to track Salmonella enterica metabolites during intracellular proliferation in host macrophage and epithelial cells. By measuring label incorporation into Salmonella metabolites with liquid chromatography-mass spectrometry (LC-MS), and combining it with metabolic modeling, we identify relevant carbon sources used by Salmonella, uncover routes of their metabolization, and quantify relative reaction rates in central carbon metabolism. Our results underline the importance of the Entner-Doudoroff pathway (EDP) and the phosphoenolpyruvate carboxylase for intracellularly proliferating Salmonella. More broadly, our metabolic labeling strategy opens novel avenues for understanding the metabolism of pathogens inside host cells.

Skeletal muscle-enriched miRNAs are highly unstable in vivo and may be regulated in a Dicer-independent manner.

MicroRNAs (miRNAs) are small noncoding RNAs that control essential cellular processes. For several decades, the molecular mechanisms underlying the functions and biogenesis of miRNAs have been clarified, whereas the molecular dynamics of miRNAs are poorly understood. We recently found that muscle-enriched miRNAs were reduced by only 20 ~ 50% in the skeletal muscles even 4 weeks after the suppression of miRNA processing through an inducible depletion of Dicer1 gene. These data suggest that miRNAs are stably expressed in skeletal muscle. In this study, we investigated the half-lives of those miRNAs in adult skeletal muscle with an in vivo metabolic labeling strategy and a genetic mouse model. In contrast to the hypothesis, in vivo metabolic labeling revealed that the half-lives of skeletal-muscle-enriched miRNAs were approximately 11-20 h. Furthermore, the levels of mature miR-23a decreased rapidly in the skeletal muscle of mice lacking miR-23 clusters in a tamoxifen-inducible manner. These data suggest that skeletal-muscle-enriched miRNAs are not highly stable in vivo. We also observed that the transfer of miR-150 into Dicer1-deficient muscle increased the miR-150 level to the same as that in control muscle. Taken together, our data demonstrate that miRNAs are degraded within a few days in adult skeletal muscle and that a Dicer-independent biogenetic pathway may produce mature miRNAs.

Heavy Methyl SILAC Metabolic Labeling of Human Cell Lines for High-Confidence Identification of R/K-Methylated Peptides by High-Resolution Mass Spectrometry.

Protein methylation is a widespread post-translational modification (PTM) involved in several important biological processes including, but not limited to, RNA splicing, signal transduction, translation, and DNA repair. Liquid chromatography-tandem mass spectrometry (LC-MS/MS) is considered today the most versatile and accurate technique to profile PTMs with high precision and proteome-wide depth; however, the identification of protein methylations by MS is still prone to high false discovery rates. In this chapter, we describe the heavy methyl SILAC metabolic labeling strategy that allows high-confidence identification of in vivo methyl-peptides by MS-based proteomics. We provide a general protocol that covers the steps of heavy methyl labeling of cultured cells, protein sample preparation, LC-MS/MS analysis, and downstream computational analysis of the acquired MS data.

Metabolic Labeling Strategy Boosted Antibacterial Efficiency for Photothermal and Photodynamic Synergistic Bacteria-Infected Wound Therapy.

Pathogenic bacteria infections bring about a substantial risk to human health. Given the development of antibiotic-resistance bacteria, alternative antibacterial strategies with great inactivation efficiency and bacteria-binding ability are extremely attractive. In this work, a metabolic labeling photosensitizer, prepared by the coupling of commercial IR820 and d-propargylglycine (a type of d-amino acid, DAA) via a straightforward one-step incubation (IR820-DAA), could metabolically be incorporated into the bacterial wall via enzymatic reactions, thus enhancing antibacterial efficiency. The laser energy at 808 nm could make IR820-DAA a synergistic photothermal/photodynamic agent for efficient antibacterial therapy and wound healing. Furthermore, IR820-DAA exhibits good water solubility and biological safety for clinical translation and even possesses biofilm degradation activity toward methicillin-resistant Staphylococcus aureus (MRSA). Overall, the proposed IR820-DAA holds great promise as a nonantibiotic tool for the treatment of bacteria-related diseases and offers a blueprint for building the precise synergistic antibacterial therapeutic platform.

Metabolite-Responsive Liposomes Employing Synthetic Lipid Switches Driven by Molecular Recognition Principles.

The ability to exert control over lipid properties, including structure, charge, function, and self-assembly characteristics is a powerful tool that can be implemented to achieve a wide range of biomedical applications. Examples in this arena include the development of caged lipids for controlled activation of signaling properties, metabolic labeling strategies for tracking lipid biosynthesis, lipid activity probes for identifying cognate binding partners, approaches for in situ membrane assembly, and liposome triggered release strategies. In this Account, we describe recent advancements in the latter area entailing the development of stimuli-responsive liposomes through programmable changes to lipid self-assembly properties, which can be harnessed to drive the release of encapsulated contents toward applications including drug delivery. We will focus on an emerging paradigm involving liposomal platforms that are sensitized toward chemical agents ranging from metal cations to small organic molecules that exhibit dysregulation in disease states. This has been achieved by developing synthetic lipid switches that are designed to undergo programmed conformational changes upon the recognition of specific target analytes. These structural alterations are leveraged to perturb the packing of lipids within the membrane and thereby drive the release of encapsulated contents.We provide an overview of the inspiration, design, and characterization of liposomes that selectively respond to wide-ranging target analytes. This series of studies began with the development of calcium-responsive liposomes utilizing a lipid switch inspired by sensors including indo-1. Following this successful demonstration, we next showed that the selectivity of the lipid switch could be altered among different metal cations by producing a liposomal platform for which release is induced through zinc binding. Our next goal was to develop metabolite-responsive liposomes in which switching is driven by molecular recognition events involving phosphorylated small molecules. In this work, screening of lipid switches designed to interact with phosphorylated metabolites led to the identification of liposomal formulations that selectivity release contents in the presence of adenosine triphosphate (ATP). Finally, we were able to modulate the metabolite selectivity by rationally designing a modified lipid switch structure that is activated through complexation of inositol-(1,4,5)-trisphosphate (IP3). These projects show the progression of our approaches for liposome release triggered by molecular recognition principles, building from ion-responsive lipid switches to structures that are activated by small molecules. These "smart" liposomal platforms provide an important addition to the toolbox for controlled cargo release since they respond to ions or small molecules that are commonly overproduced by diseased cells.

A Photocaged Azidosugar for Light‐Controlled Metabolic Labeling of Cell‐Surface Sialoglycans

Comprehensive SummaryThe photocaging strategy has been widely used for activating biomolecules and hence regulating the underlying biological processes with high temporal and spatial resolution. Herein, we integrate this strategy into metabolic glycan labeling, which enables optically‐controlled metabolic labeling of cell‐surface sialoglycans with azides. N‐Azidoacetylmannosamine (ManNAz) is caged with a 4,5‐dimethoxy‐2‐nitrobenzyl (DMNB) group at the anomeric hydroxyl group to block its cellular metabolism. After feeding to the cells, irradiation with 365 nm UV light or 405 nm visible light cleaves the photocage and generates ManNAz within the cells. ManNAz is metabolically converted to azido sialic acid, which is then incorporated into cell‐surface sialoglycans. We demonstrated spatial and temporal control of this strategy by specifically labeling sialoglycans on a single cell and tracking the metabolism of ManNAz based on light‐triggered pulse‐chase labeling, respectively. The light‐controlled metabolic glycan labeling strategy should facilitate probing of glycosylation in complex biological systems with high spatiotemporal precision.

PH-Responsive Water-Soluble Polymer Carriers for Cell-Selective Metabolic Sialylation Labeling.

Cell-surface sialic acids can be metabolically labeled and subsequently modified using bioorthogonal chemistry. The method has great potential for targeted therapy and imaging; however, distinguishing the sialylation of specific cells remains a major challenge. Here, we described a cell-selective metabolic sialylation labeling strategy based on water-soluble polymer carriers presented with pH-responsive N-azidoacetylmannosamine (ManNAz) release. 2-Methacryloyloxyethyl phosphorylcholine contributed to increased water solubility and reduced nonspecific attachment to cells. Lactobionic acid residues, used for cell selectivity, recognized overexpressed receptors on target hepatoma cells and mediated cellular internalization. ManNAz caged by acidic pH-responsive carbonated ester linkage on the polymer was released inside target cells and expressed as azido sialic acid. Additionally, longer copolymer carriers enhanced the metabolic labeling efficiency of sialylation. This approach provides a platform for cell-selective labeling of sialylation and can be applied to high-resolution bioimaging and targeted therapy.

Biodistributions of l,d-Transpeptidases in Gut Microbiota Revealed by In Vivo Labeling with Peptidoglycan Analogs.

By catalyzing a 3-3 cross-link in peptidoglycan, l,d-transpeptidases (Ldts) can cause resistance to β-lactams in some pathogens in vitro. However, the prevalence of Ldt and Ldt-mediated responses to different β-lactams in vivo have never been explored. Here, we apply an in vivo metabolic labeling strategy to study their biodistributions and Ldt-induced bacterial responses to β-lactams in the mouse gut microbiota. A tetrapeptide-based fluorescent probe that functions as a substrate for Ldts in Gram-positive bacteria efficiently labels ∼18% of total gut bacteria after gavage, suggesting Ldts' high prevalence in gut microbiota. The cellular distributions of 3-3 cross-links on three gut bacterial species were then identified with the aid of fluorescence in situ hybridization to identify the bacterial taxa. After oral administration of two β-lactams, ampicillin and meropenem, only the latter efficiently inhibits the tetrapeptide labeling, suggesting that Ldts may be able to cause resistance to some β-lactams in the mammalian gut.

From Differential Stains to Next Generation Physiology: Chemical Probes to Visualize Bacterial Cell Structure and Physiology.

Chemical probes have been instrumental in microbiology since its birth as a discipline in the 19th century when chemical dyes were used to visualize structural features of bacterial cells for the first time. In this review article we will illustrate the evolving design of chemical probes in modern chemical biology and their diverse applications in bacterial imaging and phenotypic analysis. We will introduce and discuss a variety of different probe types including fluorogenic substrates and activity-based probes that visualize metabolic and specific enzyme activities, metabolic labeling strategies to visualize structural features of bacterial cells, antibiotic-based probes as well as fluorescent conjugates to probe biomolecular uptake pathways.

Metabolic labeling of glycerophospholipids via clickable analogs derivatized at the lipid headgroup

Metabolic labeling, in which substrate analogs containing diminutive tags can infiltrate biosynthetic pathways and generate labeled products in cells, has led to dramatic advancements in the means by which complex biomolecules can be detected and biological processes can be elucidated. Within this realm, metabolic labeling of lipid products, particularly in a manner that is headgroup-specific, brings about a number of technical challenges including the complexity of lipid metabolic pathways as well as the simplicity of biosynthetic precursors to headgroup functionality. As such, only a handful of strategies for metabolic labeling of lipids have thus far been reported. However, these approaches provide enticing examples of how strategic modifications to substrate structures, particularly by introducing clickable moieties, can enable the hijacking of lipid biosynthesis. Furthermore, early work in this field has led to an explosion in diverse applications by which these techniques have been exploited to answer key biological questions or detect and track various lipid-containing biological entities. In this article, we review these efforts and emphasize recent advancements in the development and application of lipid metabolic labeling strategies.