In Vivo Analysis of NH4+ Transport and Central Nitrogen Metabolism in Saccharomyces cerevisiae during Aerobic Nitrogen-Limited Growth

Imbalanced metabolism induced NH4+ accumulation and its effect on the central metabolism of Methylomonas sp. ZR1

Nitrogen and carbon are the two most essential nutrient elements, and their metabolism is tightly coupled in single carbon metabolic microorganisms. However, the nitrogen metabolism and the nitrogen/carbon (N/C) metabolic balance in single-carbon metabolism is poorly studied. In this study, the nitrogen metabolism pattern of the fast growing methanotrophs Methylomonas sp. ZR1 grown in methane and methanol was studied. Effect study of different nitrogen sources on the cell growth of ZR1 indicates that nitrate salts are the best nitrogen source supporting the growth of ZR1 using methane and methanol as carbon source. However, its metabolic intermediate ammonium was found to accumulate with high N/C ratio in the medium and consequently inhibit the growth of ZR1. Studies of carbon and nitrogen metabolic kinetic under different N/C ratio conditions indicate that the accumulation of NH4+ is caused by the imbalanced nitrogen and carbon metabolism in ZR1. Feeding carbon skeleton α-ketoglutaric acid could effectively relieve the inhibition effect of NH4+ on the growth of ZR1, which further confirms this assumption. qPCR analysis of the expression level of the central metabolic key enzyme gene indicates that the nitrogen metabolic intermediate ammonium has strong regulation effect on the central nitrogen and carbon metabolism in ZR1. qPCR-combined genomic analysis confirms that a third ammonium assimilation pathway glycine synthesis system is operated in ZR1 to balance the nitrogen and carbon metabolism. Based on the qPCR result, it was also found that ZR1 employs two strategies to relieve ammonium stress in the presence of ammonium: assimilating excess ammonium or cutting off the nitrogen reduction reactions according to the available C1 substrate. Validating the connections between single-carbon and nitrogen metabolism and studying the accumulation and assimilation mechanism of ammonium will contribute to understand how nitrogen regulates cellular growth in single-carbon metabolic microorganisms.

An energetic profile of Corynebacterium glutamicum underpinned by measured biomass yield on ATP

The supply and usage of energetic cofactors in metabolism is a central concern for systems metabolic engineering, particularly in case of energy intensive products. One of the most important parameters for systems wide balancing of energetic cofactors is the ATP requirement for biomass formation Y_ATP/Biomass. Despite its fundamental importance, Y_ATP/Biomass values for non-fermentative organisms are still rough estimates deduced from theoretical considerations. For the first time, we present an approach for the experimental determination of Y_ATP/Biomass using comparative ¹³C metabolic flux analysis (¹³C MFA) of a wild type strain and an ATP synthase knockout mutant. We show that the energetic profile of a cell can then be deduced from a genome wide stoichiometric model and experimental maintenance data. Particularly, the contributions of substrate level phosphorylation (SLP) and electron transport phosphorylation (ETP) to ATP generation become available which enables the overall energetic efficiency of a cell to be characterized. As a model organism, the industrial platform organism Corynebacterium glutamicum is used. C. glutamicum uses a respiratory type of energy metabolism, implying that ATP can be synthesized either by SLP or by ETP with the membrane-bound F₁F_O-ATP synthase using the proton motive force (pmf) as driving force. The presence of two terminal oxidases, which differ in their proton translocation efficiency by a factor of three, further complicates energy balancing for this organism. By integration of experimental data and network models, we show that in the wild type SLP and ETP contribute equally to ATP generation. Thus, the role of ETP in respiring bacteria may have been overrated in the past. Remarkably, in the genome wide setting 65% of the pmf is actually not used for ATP synthesis. However, it turns out that, compared to other organisms C. glutamicum still uses its energy budget rather efficiently.

Widespread effect of N-acetyl-D-glucosamine assimilation on the metabolisms of amino acids, purines, and pyrimidines in Scheffersomyces stipitis

BACKGROUND

Following cellulose, chitin is the most abundant renewable resource and is composed of the monomeric amino sugar N-acetyl-D-glucosamine (GlcNAc). Although many yeasts, including Saccharomyces cerevisiae, have lost their ability to utilize GlcNAc, some yeasts are able to use GlcNAc as a carbon source. However, our understanding of the effects of GlcNAc on the intracellular metabolism of nitrogen-containing compounds in these yeast species is limited.

RESULTS

In the present study, we quantitatively investigated the metabolic responses to GlcNAc in the GlcNAc-assimilating yeast Scheffersomyces stipitis (formerly known as Pichia stipitis) using capillary electrophoresis time-of-flight mass spectrometry (CE-TOFMS). The comprehensive analysis of the metabolites extracted from S. stipitis cells grown in glucose, xylose, or GlcNAc revealed increased intracellular accumulation of a wide range of nitrogen-containing compounds during GlcNAc assimilation in this yeast. The levels of aromatic, branched-chain, and sulfur-containing amino acids and adenine, guanine, and cytosine nucleotides were the highest in GlcNAc-grown cells.

CONCLUSIONS

The CE-TOFMS analysis revealed a positive effect for GlcNAc on the intracellular concentration of a wide range of nitrogen-containing compounds. The metabolomic data gathered in this study will be useful for designing effective genetic engineering strategies to develop novel S. stipitis strains for the production of valuable nitrogen-containing compounds from GlcNAc.