High-density CRISPRi screens reveal adaptive transcriptional gradients in cyanobacteria

Abstract

ABSTRACTCyanobacteria are the oldest form of photosynthetic life on Earth and contribute to primary production in nearly every habitat, from permafrost to hot springs. Despite longstanding interest in the biochemical basis of environmental adaptation in these microbes, it remains poorly understood and challenging to re-wire. This study uses a high-density, genome-wide CRISPR interference (CRISPRi) screen to examine the influence of gene-specific transcriptional variation on the growth ofSynechococcussp. PCC 7002 under environmental extrema. Surprisingly, many partial knockdowns enhanced fitness under cold monochromatic conditions. Notably, transcriptional repression of a gene for a core subunit of the NDH-1 complex, which is important for photosynthesis and carbon uptake, improved growth rates under both red and blue light but at distinct, color-specific optima. In general, most genes with fitness-improving knockdowns were distinct to each light color, evidencing unique stress responses and alleviation mechanisms. Multi-target transcriptional repression produced nonadditive effects. Findings reveal diverse mechanisms of environmental adaptation in cyanobacteria and provide a new approach for using gradients in sgRNA activity to pinpoint biochemically influential transcriptional changes in cells.SIGNIFICANCE STATEMENTCyanobacteria are the most abundant photosynthetic organisms on Earth, where they endure a striking variety of environmental fluctuations. This study examines the biochemical basis of environmental adaptation inSynechococcussp. PCC 7002, an important model strain, by modulating the expression of every gene in its genome. Results show that partial, but not complete, reduction in the expression of a subset of influential genes can improve growth under cold monochromatic conditions. Optimal expression levels differ between red and blue light and shift with multi-gene adjustments. Findings show how minor transcriptional adjustments can yield major improvements in growth under environmental extrema and provide a powerful systems-level approach for studying—and fine-tuning—the adaptive capacity of microbes.