Salmonella FraE, an Asparaginase Homolog, Contributes to Fructose-Asparagine but Not Asparagine Utilization

ABSTRACT Salmonella enterica can utilize fructose-asparagine (F-Asn) as a source of carbon and nitrogen. This capability has been attributed to five genes in the fra locus. Previously, we determined that mutations in fraB (deglycase), fraD (kinase), or fraA (transporter) eliminated the ability of Salmonella to grow on F-Asn, while a mutation in fraE allowed partial growth. We hypothesized that FraE, a putative periplasmic fructose-asparaginase, converts F-Asn to NH4+ and fructose-aspartate (F-Asp). FraA could then transport F-Asp into the cytoplasm for subsequent catabolism. Here, we report that growth of the fraE mutant on F-Asn is caused by a partially redundant activity provided by AnsB, a periplasmic asparaginase. Indeed, a fraE ansB double mutant is unable to grow on F-Asn. Moreover, biochemical assays using periplasmic extracts of mutants that express only FraE or AnsB confirmed that each of these enzymes converts F-Asn to F-Asp and NH4+. However, FraE does not contribute to growth on asparagine. We tested and confirmed the hypothesis that a fraE ansB mutant can grow on F-Asp, while mutants lacking fraA, fraD, or fraB cannot. This finding provides strong evidence that FraA transports F-Asp but not F-Asn from the periplasm to the cytoplasm. Previously, we determined that F-Asn is toxic to a fraB mutant due to the accumulation of the FraB substrate, 6-phosphofructose-aspartate (6-P-F-Asp). Here, we found that, as expected, a fraB mutant is also inhibited by F-Asp. Collectively, these findings contribute to a better understanding of F-Asn utilization by Salmonella. IMPORTANCE Salmonella is able to utilize fructose-asparagine (F-Asn) as a nutrient. We recently reported that the disruption of a deglycase enzyme in the F-Asn utilization pathway inhibits the growth of Salmonella in mice and recognized this pathway as a novel and specific drug target. Here, we characterize the first step in the pathway wherein FraE hydrolyzes F-Asn to release NH4+ and F-Asp in the periplasm of the cell. A fraE mutant continues to grow slowly on F-Asn due to asparaginase activity encoded by ansB.

[1]  V. Gopalan,et al.  Characterization of a Salmonella sugar kinase essential for the utilization of fructose-asparagine. , 2017, Biochemistry and cell biology = Biochimie et biologie cellulaire.

[2]  S. Porwollik,et al.  Contribution of Asparagine Catabolism to Salmonella Virulence , 2016, Infection and Immunity.

[3]  E. Behrman,et al.  Synthesis of 6-phosphofructose aspartic acid and some related Amadori compounds. , 2016, Carbohydrate research.

[4]  B. Ahmer,et al.  A metabolic intermediate of the fructose-asparagine utilization pathway inhibits growth of a Salmonella fraB mutant , 2016, Scientific Reports.

[5]  E. Chen,et al.  Asparagine deprivation mediated by Salmonella asparaginase causes suppression of activation‐induced T cell metabolic reprogramming , 2016, Journal of leukocyte biology.

[6]  R. Black,et al.  Aetiology-Specific Estimates of the Global and Regional Incidence and Mortality of Diarrhoeal Diseases Commonly Transmitted through Food , 2015, PloS one.

[7]  Tine Hald,et al.  World Health Organization Estimates of the Global and Regional Disease Burden of 22 Foodborne Bacterial, Protozoal, and Viral Diseases, 2010: A Data Synthesis , 2015, PLoS medicine.

[8]  R. Arsenescu,et al.  Fructose-Asparagine Is a Primary Nutrient during Growth of Salmonella in the Inflamed Intestine , 2014, PLoS pathogens.

[9]  Inacio Mandomando,et al.  Burden and aetiology of diarrhoeal disease in infants and young children in developing countries (the Global Enteric Multicenter Study, GEMS): a prospective, case-control study , 2013, The Lancet.

[10]  S. Porwollik,et al.  L-asparaginase II produced by Salmonella typhimurium inhibits T cell responses and mediates virulence. , 2012, Cell host & microbe.

[11]  B. Mahon,et al.  Estimates of Illnesses, Hospitalizations and Deaths Caused by Major Bacterial Enteric Pathogens in Young Children in the United States , 2012, The Pediatric infectious disease journal.

[12]  Richard D. Smith,et al.  A Comprehensive Subcellular Proteomic Survey of Salmonella Grown under Phagosome-Mimicking versus Standard Laboratory Conditions , 2012, International journal of proteomics.

[13]  T. Bobik,et al.  The Alternative Electron Acceptor Tetrathionate Supports B12-Dependent Anaerobic Growth ofSalmonella enterica Serovar Typhimurium on Ethanolamine or 1,2-Propanediol , 2001, Journal of bacteriology.

[14]  B. Wanner,et al.  One-step inactivation of chromosomal genes in Escherichia coli K-12 using PCR products. , 2000, Proceedings of the National Academy of Sciences of the United States of America.

[15]  M. M. Bradford A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. , 1976, Analytical biochemistry.

[16]  J. H. Schwartz,et al.  Production of l-Asparaginase II by Escherichia coli , 1968, Journal of bacteriology.

[17]  L. Old,et al.  Two L-asparaginases from Escherichia coli B. Their separation, purification, and antitumor activity. , 1967, Biochemistry.

[18]  W. Wackernagel,et al.  Gene disruption in Escherichia coli: TcR and KmR cassettes with the option of Flp-catalyzed excision of the antibiotic-resistance determinant. , 1995, Gene.

[19]  Jeffrey H. Miller Experiments in molecular genetics , 1972 .