To facilitate scalable profiling of single cells, we developed split-pool ligation-based transcriptome sequencing (SPLiT-seq), a single-cell RNA-seq (scRNA-seq) method that labels the cellular origin of RNA through combinatorial barcoding. SPLiT-seq is compatible with fixed cells or nuclei, allows efficient sample multiplexing, and requires no customized equipment. We used SPLiT-seq to analyze 156,049 single-nucleus transcriptomes from postnatal day 2 and 11 mouse brains and spinal cords. More than 100 cell types were identified, with gene expression patterns corresponding to cellular function, regional specificity, and stage of differentiation. Pseudotime analysis revealed transcriptional programs driving four developmental lineages, providing a snapshot of early postnatal development in the murine central nervous system. SPLiT-seq provides a path toward comprehensive single-cell transcriptomic analysis of other similarly complex multicellular systems.
Our ability to predict protein expression from DNA sequence alone remains poor, reflecting our limited understanding of -regulatory grammar and hampering the design of engineered genes for synthetic biology applications. Here, we generate a model that predicts the protein expression of the 5' untranslated region (UTR) of mRNAs in the yeast We constructed a library of half a million 50-nucleotide-long random 5' UTRs and assayed their activity in a massively parallel growth selection experiment. The resulting data allow us to quantify the impact on protein expression of Kozak sequence composition, upstream open reading frames (uORFs), and secondary structure. We trained a convolutional neural network (CNN) on the random library and showed that it performs well at predicting the protein expression of both a held-out set of the random 5' UTRs as well as native 5' UTRs. The model additionally was used to computationally evolve highly active 5' UTRs. We confirmed experimentally that the great majority of the evolved sequences led to higher protein expression rates than the starting sequences, demonstrating the predictive power of this model.
Single-cell RNA sequencing (scRNA-seq) has become an essential tool for
characterizing gene expression in eukaryotes, but current methods are incompatible
with bacteria. Here, we introduce microSPLiT (microbial split-pool ligation
transcriptomics), a high-throughput scRNA-seq method for Gram-negative and
Gram-positive bacteria that can resolve heterogeneous transcriptional states. We
applied microSPLiT to >25,000 Bacillus subtilis
cells sampled at different growth stages, creating an atlas of changes in
metabolism and lifestyle. We retrieved detailed gene expression profiles
associated with known, but rare, states such as competence and prophage induction
and also identified unexpected gene expression states, including the heterogeneous
activation of a niche metabolic pathway in a subpopulation of cells. MicroSPLiT
paves the way to high-throughput analysis of gene expression in bacterial
communities that are otherwise not amenable to single-cell analysis, such as
natural microbiota.
Summary
Genes encoding proteins in a common regulatory network are frequently located close to one another on the chromosome to facilitate co-regulation or couple gene expression to growth rate. Contrasting with these observations, here we demonstrate a functional role for the arrangement of Bacillus subtilis sporulation network genes on opposite sides of the chromosome. We show that the arrangement of two sporulation network genes, one located close to the origin, the other close to the terminus leads to a transient gene dosage imbalance during chromosome replication. This imbalance is detected by the sporulation network to produce cell-cycle coordinated pulses of the sporulation master regulator Spo0A~P. This pulsed response allows cells to decide between sporulation and continued vegetative growth during each cell-cycle spent in starvation. The simplicity of this coordination mechanism suggests that it may be widely applicable in a variety of gene regulatory and stress-response settings.
An important cell fate decision in Bacillus subtilis is shown to be the result of a ‘molecular race' between competing differentiation programs. The programs controlling competence initiation and spore formation progress independently, and without cross-talk, before cell fate choice.
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