Abstract
When starved for nitrogen, non-growing cells of the photosynthetic bacterium Rhodopseudomonas palustris continue to metabolize acetate and produce H2, an important industrial chemical and potential biofuel. The enzyme nitrogenase catalyzes H2 formation. The highest H2 yields are obtained when cells are deprived of N2 and thus use available electrons to synthesize H2 as the exclusive product of nitrogenase. To understand how R. palustris responds metabolically to increase H2 yields when it is starved for N2, and thus not growing, we tracked changes in biomass composition and global transcript levels. In addition to a 3.5-fold higher H2 yield by non-growing cells we also observed an accumulation of polyhydroxybutyrate to over 30% of the dry cell weight. The transcriptome of R. palustris showed down-regulation of biosynthetic processes and up-regulation of nitrogen scavenging mechanisms in response to N2 starvation but gene expression changes did not point to metabolic activities that could generate the reductant necessary to explain the high H2 yield. We therefore tracked (13)C-labeled acetate through central metabolic pathways. We found that non-growing cells shifted their metabolism to use the tricarboxylic acid cycle to metabolize acetate in contrast to growing cells, which used the glyoxylate cycle exclusively. This shift enabled cells to more fully oxidize acetate, providing the necessary reducing power to explain the high H2 yield.
Highlights
The metabolism of non-growing microbes is poorly understood
We found that nongrowing cells shifted their metabolism to use the tricarboxylic acid cycle to metabolize acetate in contrast to growing cells, which used the glyoxylate cycle exclusively
We determined that when R. palustris growth is prevented by nitrogen starvation, acetate is metabolized through the tricarboxylic acid (TCA) cycle rather than through the glyoxylate shunt
Summary
The metabolism of non-growing microbes is poorly understood. Results: In a nitrogen-starved and non-growing photoheterotrophic bacterium, metabolic flow was diverted to mobilize electrons for H2 production. When starved for nutrients like nitrogen but supplied with light and organic carbon, R. palustris can maintain a relatively high rate of metabolic activity in a non-growing state for months or longer [3]. Under these conditions, it is assumed that R. palustris repeatedly energizes and cycles electrons through a Hϩ-pumping electron transfer chain to generate ATP for cell maintenance in a process called cyclic photophosphorylation. R. palustris regulatory mutants have been constructed that synthesize active nitrogenase and make H2 while growing under an Ar atmosphere with NH4ϩ as the sole nitrogen source (2, 6 – 8) Under these growth conditions, the CO2-fixing Calvin cycle competes with nitrogenase for electrons [2, 6]. These data inform on microbial responses to nitrogen starvation and provide a basis for engineering strategies to improve H2 production traits
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