bThe consequences of cellular heterogeneity, such as biocide persistence, can only be tackled by studying each individual in a cell population. Fluorescent tags provide tools for the high-throughput analysis of genomes, RNA transcripts, or proteins on the single-cell level. However, the analysis of lower-molecular-weight compounds that elude tagging is still a great challenge. Here, we describe a novel high-throughput microscale sample preparation technique for single cells that allows a mass spectrum to be obtained for each individual cell within a microbial population. The approach presented includes spotting Chlamydomonas reinhardtii cells, using a noncontact microarrayer, onto a specialized slide and controlled lysis of cells separated on the slide. Throughout the sample preparation, analytes were traced and individual steps optimized using autofluorescence detection of chlorophyll. The lysates of isolated cells are subjected to a direct, label-free analysis using matrix-assisted laser desorption ionization mass spectrometry. Thus, we were able to differentiate individual cells of two Chlamydomonas reinhardtii strains based on single-cell mass spectra. Furthermore, we showed that only population profiles with real single-cell resolution render a nondistorted picture of the phenotypes contained in a population.
Heterogeneity plays a pivotal role in the emergence of tolerance, persistence, and resistance toward biocides in microbial populations (1, 2). Also, microbial populations show highly complex interactions, e.g., in the competition for nutrients or in the colonization of new habitats (3). In recent years, newly developed tools for single-cell analysis have greatly extended our understanding of biological variation in microbial populations and its underlying mechanisms (4). These tools allow genome sequencing (5) or follow transcription as well as protein synthesis on the single-cell level (6). Since these techniques give a much higher resolution when observing processes in given cell populations, they permit insight into inter-and intracellular processes and the underlying mechanisms. However, when it comes to highthroughput measurements of small molecules, very few methods are currently known (7).The singular qualities of individual cells can only be fully appreciated within the context of the population. Therefore, one of the most important features for single-cell methods to be useful in biological applications is high-throughput capability. One of the most successful high-throughput approaches to characterize heterogeneities in microbial populations is flow cytometry (8). It has the benefits of high sensitivity and a high linear dynamic range of fluorescence tagging and optical detection. However, the method is strongly limited in parallelization, since excitation and emission bands overlap. Mass cytometry, on the other hand, which is a new approach that can be coupled to flow cytometry, uses antibodies tagged with rare earth metals (9). With mass spectrometric detection, over 40 features can be meas...
