Loss of YggS (COG0325) impacts aspartate metabolism in Salmonella enterica

Systems metabolic engineering and process optimization for efficient l-tyrosine production from high-purity glucose syrup in Escherichia coli

l-tyrosine (l-tyr) is a valuable aromatic amino acid that can be produced via microbial fermentation, providing a sustainable alternative to costly and polluting chemical synthesis. However, industrial production is limited by poor strain performance and inefficient resource utilization. In this study, a high-performance Escherichia coli strain was engineered to address key fermentation bottlenecks for efficient l-tyr synthesis from high-purity glucose syrup. Initially, a "rapid channel" for l-tyr biosynthesis was established by overexpressing aroGfbr and tyrAfbr genes, introducing the pyridoxal 5'-phosphate synthesis pathway, and strengthening tyrosine efflux. Precursor pools of phosphoenolpyruvate and erythrose-4-phosphate were enriched using modular metabolic engineering and dynamic regulation strategies. Co-metabolism of glucose, maltose, and isomaltose was achieved by integrating Bacillus subtilis-derived membrane permease and maltose-6'-phosphate glucosidase, alongside Bifidobacterium adolescentis-derived oligo-1,6-glucosidase, and by employing a suboptimal glucose supplementation feeding strategy. To overcome oxygen limitation, Vitreoscilla hemoglobin was localized to the periplasm via the twin-arginine translocation pathway. Systematic fermentation optimization further improved strain performance, achieving an l-tyr titer, yield, and productivity of 109.2 g/L, 0.292 g/g, and 2.18 g/L/h, respectively-the highest reported to date. This research demonstrates a promising strategy for enhancing l-tyrosine biosynthesis, providing a scalable approach for industrial production and broader applications in microbial metabolic engineering.

Purine limitation prevents the exogenous pyridoxal 5'-phosphate accumulation of Salmonella enterica yggS mutants

YggS belongs to the highly conserved pyridoxal 5'-phosphate (PLP) binding protein family (COG0325) that is found in all domains of life. Though no precise biochemical activity or molecular mechanism has been determined for this protein, an involvement in vitamin B6 homeostasis has been demonstrated in multiple organisms. In Salmonella enterica, loss of YggS results in altered B6 vitamer pools, including an accumulation of PLP in the growth medium. Transposon mutagenesis identified an insertion upstream of purC (encoding 5'-phosphoribosyl-5-aminoimidazole-4-N-succinocarboxamide synthetase, EC 6.3.2.6) that eliminated accumulation of PLP in the spent medium. Genetic characterization of the insertion showed the causative effect was reduced expression of purC, which limited purine biosynthesis. Data herein shows that purine limitation decreased the exogenous accumulation of B6 vitamers of a yggS mutant but did not suppress other yggS mutant phenotypes. Neither limitation for ATP, regulation by PurR, or decreased growth rate, all of which are direct consequences of purine limitation, prevented exogenous B6 vitamer accumulation of a yggS mutant. This work establishes a relationship between the status of purine biosynthesis and the impact of a yggS mutation. It lays the foundation for continued efforts to identify the physiological role of YggS and its homologs.

IMPORTANCE

Pyridoxal 5'-phosphate is the active form of vitamin B6 and is an essential cofactor in all domains of life. PLP can be synthesized de novo or salvaged from the environment from one of the six B6 vitamers. B6 vitamer levels appear to be tightly regulated, and alterations in their levels can have deleterious effects, most notably being the development of B6-dependent epilepsy in humans. YggS homologs are broadly conserved across multiple organisms and considered to be involved in maintaining B6 homeostasis, though no specific mechanism has been defined. The current study showed that the exogenous accumulation of PLP caused by a lack of YggS can be prevented by purine limitation. The demonstration that purine limitation impacts exogenous PLP accumulation separates one consequence of a yggS mutation for further study and contributes to continuing efforts to define the biochemical and physiological roles of the COG0325 family of proteins.

Identification of YigL as a PLP/PNP phosphatase in Escherichia coli

In various organisms, the coenzyme form of vitamin B6, pyridoxal phosphate (PLP), is synthesized from pyridoxine phosphate (PNP). Control of PNP levels is crucial for metabolic homeostasis because PNP has the potential to inhibit PLP-dependent enzymes and proteins. Although the only known pathway for PNP metabolism in Escherichia coli involves oxidation by PNP oxidase, we detected a strong PNP phosphatase activity in E. coli cell lysate. To identify the unknown PNP phosphatase(s), we performed a multicopy suppressor screening using the E. coli serA pdxH strain, which displays PNP-dependent conditional lethality. The results showed that overexpression of the yigL gene, encoding a putative sugar phosphatase, effectively alleviated the PNP toxicity. Biochemical analysis revealed that YigL has strong phosphatase activity against PNP. A yigL mutant exhibited decreased PNP phosphatase activity, elevated intracellular PNP concentrations, and increased PNP sensitivity, highlighting the important role of YigL in PNP homeostasis. YigL also shows reactivity with PLP. The phosphatase activity of PLP in E. coli cell lysate was significantly reduced by mutation of yigL and nearly abolished by additional mutation of ybhA, which encodes putative PLP phosphatase. These results underscore the important contribution of YigL, in combination with YbhA, as a primary enzyme in the dephosphorylation of both PNP and PLP in E. coli.IMPORTANCEPyridoxine phosphate (PNP) metabolism is critical for both vitamin B6 homeostasis and cellular metabolism. In Escherichia coli, oxidation of PNP was the only known mechanism for controlling PNP levels. This study uncovered a novel phosphatase-mediated mechanism for PNP homeostasis. Multicopy suppressor screening, kinetic analysis of the enzyme, and knockout/overexpression studies identified YigL as a key PNP phosphatase that contributes to PNP homeostasis when facing elevated PNP concentrations in E. coli. This study also revealed a significant contribution of YigL, in combination with YbhA, to PLP metabolism, shedding light on the mechanisms of vitamin B6 regulation in bacteria.

Two pyridoxal phosphate homeostasis proteins are essential for management of the coenzyme pyridoxal 5'-phosphate in Arabidopsis

Coenzyme management is important for homeostasis of the pool of active metabolic enzymes. The coenzyme pyridoxal 5'-phosphate (PLP) is involved in diverse enzyme reactions including amino acid and hormone metabolism. Regulatory proteins that contribute to PLP homeostasis remain to be explored in plants. Here, we demonstrate the importance of proteins annotated as PLP homeostasis proteins (PLPHPs) for controlling PLP in Arabidopsis (Arabidopsis thaliana). A systematic analysis indicates that while most organisms across kingdoms have a single PLPHP homolog, Angiosperms have two. PLPHPs from Arabidopsis bind PLP and exist as monomers, in contrast to reported PLP-dependent enzymes, which exist as multimers. Disrupting the function of both PLPHP homologs perturbs vitamin B6 (pyridoxine) content, inducing a PLP deficit accompanied by light hypersensitive root growth, unlike PLP biosynthesis mutants. Micrografting studies show that the PLP deficit can be relieved distally between shoots and roots. Chemical treatments probing PLP-dependent reactions, notably those for auxin and ethylene, provide evidence that PLPHPs function in the dynamic management of PLP. Assays in vitro show that Arabidopsis PLPHP can coordinate PLP transfer and withdrawal from other enzymes. This study thus expands our knowledge of vitamin B6 biology and highlights the importance of PLP coenzyme homeostasis in plants.

Maintenance of cellular vitamin B6 levels and mitochondrial oxidative function depend on pyridoxal 5'-phosphate homeostasis protein

Recently, biallelic variants in PLPBP coding for pyridoxal 5'-phosphate homeostasis protein (PLPHP) were identified as a novel cause of early-onset vitamin B6-dependent epilepsy. The molecular function and precise role of PLPHP in vitamin B6 metabolism are not well understood. To address these questions, we used PLPHP-deficient patient skin fibroblasts and HEK293 cells and YBL036C (PLPHP ortholog)-deficient yeast. We showed that independent of extracellular B6 vitamer type (pyridoxine, pyridoxamine, or pyridoxal), intracellular pyridoxal 5'-phosphate (PLP) was lower in PLPHP-deficient fibroblasts and HEK293 cells than controls. Culturing cells with pyridoxine or pyridoxamine led to the concentration-dependent accumulation of pyridoxine 5'-phosphate and pyridoxamine 5'-phosphate (PMP), respectively, suggesting insufficient pyridox(am)ine 5'-phosphate oxidase activity. Experiments utilizing 13C4-pyridoxine confirmed lower pyridox(am)ine 5'-phosphate oxidase activity and revealed increased fractional turnovers of PLP and pyridoxal, indicating increased PLP hydrolysis to pyridoxal in PLPHP-deficient cells. This effect could be partly counteracted by inactivation of pyridoxal phosphatase. PLPHP deficiency had a distinct effect on mitochondrial PLP and PMP, suggesting impaired activity of mitochondrial transaminases. Moreover, in YBL036C-deficient yeast, PLP was depleted and PMP accumulated only with carbon sources requiring mitochondrial metabolism. Lactate and pyruvate accumulation along with the decrease of tricarboxylic acid cycle intermediates downstream of α-ketoglutarate suggested impaired mitochondrial oxidative metabolism in PLPHP-deficient HEK293 cells. We hypothesize that impaired activity of mitochondrial transaminases may contribute to this depletion. Taken together, our study provides new insights into the pathomechanisms of PLPBP deficiency and reinforces the link between PLPHP function, vitamin B6 metabolism, and mitochondrial oxidative metabolism.

The Conserved Family of the Pyridoxal Phosphate-Binding Protein (PLPBP) and Its Cyanobacterial Paradigm PipY

The PLPBP family of pyridoxal phosphate-binding proteins has a high degree of sequence conservation and is represented in all three domains of life. PLPBP members, of which a few representatives have been studied in different contexts, are single-domain proteins with no known enzymatic activity that exhibit the fold type III of PLP-holoenzymes, consisting in an α/β barrel (TIM-barrel), where the PLP cofactor is solvent-exposed. Despite the constant presence of cofactor PLP (a key catalytic element in PLP enzymes), PLPBP family members appear to have purely regulatory functions affecting the homeostasis of vitamin B6 vitamers and amino/keto acids. Perturbation of these metabolites and pleiotropic phenotypes have been reported in bacteria and zebrafish after PLPBP gene inactivation as well as in patients with vitamin B6-dependent epilepsy that results from loss-of-function mutations at the PLPBP. Here, we review information gathered from diverse studies and biological systems, emphasizing the structural and functional conservation of the PLPBP members and discussing the informative nature of model systems and experimental approaches. In this context, the relatively high level of structural and functional characterization of PipY from Synechococcus elongatus PCC 7942 provides a unique opportunity to investigate the PLPBP roles in the context of a signaling pathway conserved in cyanobacteria.

B vitamin supply in plants and humans: the importance of vitamer homeostasis

B vitamins are a group of water-soluble micronutrients that are required in all life forms. With the lack of biosynthetic pathways, humans depend on dietary uptake of these compounds, either directly or indirectly, from plant sources. B vitamins are frequently given little consideration beyond their role as enzyme accessory factors and are assumed not to limit metabolism. However, it should be recognized that each individual B vitamin is a family of compounds (vitamers), the regulation of which has dedicated pathways. Moreover, it is becoming increasingly evident that individual family members have physiological relevance and should not be sidelined. Here, we elaborate on the known forms of vitamins B₁ , B₆ and B₉ , their distinct functions and importance to metabolism, in both human and plant health, and highlight the relevance of vitamer homeostasis. Research on B vitamin metabolism over the past several years indicates that not only the total level of vitamins but also the oft-neglected homeostasis of the various vitamers of each B vitamin is essential to human and plant health. We briefly discuss the potential of plant biology studies in supporting human health regarding these B vitamins as essential micronutrients. Based on the findings of the past few years we conclude that research should focus on the significance of vitamer homeostasis - at the organ, tissue and subcellular levels - which could improve the health of not only humans but also plants, benefiting from cross-disciplinary approaches and novel technologies.

Role of the conserved pyridoxal 5'-phosphate-binding protein YggS/PLPBP in vitamin B6 and amino acid homeostasis

The YggS/PLPBP protein (also called COG0325 or PLPHP) is a conserved pyridoxal 5'-phosphate (PLP)-binding protein present in all three domains of life. Recent studies have demonstrated that disruption or mutation of this protein has multifaceted effects in various organisms, including vitamin B6-dependent epilepsy in humans. In Escherichia coli, disruption of this protein-encoded by yggS-perturbs Thr-Ile/Val metabolism, one-carbon metabolism, coenzyme A synthesis, and vitamin B6 homeostasis. This protein is critical for maintaining low levels of pyridoxine 5'-phosphate (PNP) in various organisms. In the yggS-deficient E. coli strain, inhibition of PLP-dependent enzymes, such as the glycine cleavage system by PNP is the root cause of metabolic perturbation. Our data suggest that the YggS/PLPBP protein may be involved in the balancing of B6 vitamers by mediating efficient turnover of protein-bound B6 vitamers. This paper reviews recent findings on the function of the YggS/PLPBP protein.

Mechanism of pyridoxine 5'-phosphate accumulation in PLPBP protein-deficiency

The pyridoxal 5'-phosphate (PLP)-binding protein (PLPBP) plays an important role in vitamin B₆ homeostasis. Loss of this protein in organisms such as Escherichia coli and humans disrupts the vitamin B₆ pool and induces intracellular accumulation of pyridoxine 5'-phosphate (PNP), which is normally undetectable in wild-type cells. The accumulated PNP could affect diverse metabolic systems through inhibition of some PLP-dependent enzymes. In this study, we investigated the as yet unclear mechanism of intracellular accumulation of PNP by the loss of PLPBP protein encoded by yggS in E. coli. Genetic studies using several PLPBP-deficient strains of E. coli lacking known enzyme(s) in the de novo or salvage pathway of vitamin B₆, which includes pyridoxine (amine) 5'-phosphate oxidase (PNPO), PNP synthase, pyridoxal kinase, and pyridoxal reductase, demonstrated that neither the flux from the de novo pathway nor the salvage pathway solely contributed to the PNP accumulation caused by the PLPBP mutation. Studies with the strains lacking both PLPBP and PNPO suggested that PNP shares the same pool with PMP, and showed that PNP levels are impacted by PMP levels and vice versa. We show that disruption of PLPBP lead to perturb PMP homeostasis, which may result in PNP accumulation in the PLPBP-deficient strains. Importance A PLP-binding protein PLPBP from the conserved COG0325 family has recently been recognized as a key player in vitamin B₆ homeostasis in various organisms. Loss of PLPBP disrupts vitamin B₆ homeostasis and perturbs diverse metabolisms, including amino acid and α-keto acid metabolism. Accumulation of PNP is a characteristic phenotype of the PLPBP deficiency and is suggested to be a potential cause of the pleiotropic effects, but the mechanism of the PNP accumulation was poorly understood. In this study, we show that fluxes for PNP synthesis/metabolism are not responsible for the accumulation of PNP. Our results indicate that PLPBP is involved in the homeostasis of pyridoxamine 5'-phosphate, and its disruption may lead to the accumulation of PNP in PLPBP-deficiency.