Escherichia coli YgiC and YjfC Possess Peptide─Spermidine Ligase Activity.

Polyamines and polyamine-containing metabolites are involved in many cellular processes related to bacterial cell growth and survival. In Escherichia coli, the bifunctional enzyme glutathionylspermidine synthetase/amidase (GspSA) controls the production of glutathionylspermidine, which has a protective role against oxidative stress. E. coli also encodes two enzymes with homology to the synthetase domain of GspSA, YgiC, and YjfC; however, these do not catalyze the formation of glutathionylspermidine, and their catalytic function remained unknown. Here, we detail the structural and functional characterization of YgiC and YjfC. Using X-ray crystallography, the high-resolution crystal structures of YgiC and YjfC were obtained. This revealed that YgiC and YjfC possess multiple substitutions in key residues required for binding of glutathione in GspSA. Despite this difference, these enzymes share a similar active site structure to GspSA, suggesting that they catalyze the formation of an alternate peptide─spermidine conjugate. As the physiological substrates of YgiC and YjfC are unknown, this was probed using the peptide triglycine as a model substrate. A combination of enzyme activity assays and mass spectrometry revealed that YgiC and YjfC can function as peptide-spermidine ligases, forming a triglycine-spermidine conjugate. For both enzymes, conjugate formation was only observed in the presence of spermidine, but not other common polyamines, supporting that spermidine or a spermidine derivative is the physiological substrate. Importantly, since YgiC and YjfC are widely distributed in Gram-negative bacterial species, this suggests that these enzymes function in a conserved cellular process, representing a currently unknown aspect of bacterial polyamine metabolism.

Discovery of an ʟ-amino acid ligase implicated in Staphylococcal sulfur amino acid metabolism.

Enzymes involved in Staphylococcus aureus amino acid metabolism have recently gained traction as promising targets for the development of new antibiotics, however, not all aspects of this process are understood. The ATP-grasp superfamily includes enzymes that predominantly catalyze the ATP-dependent ligation of various carboxylate and amine substrates. One subset, ʟ-amino acid ligases (LALs), primarily catalyze the formation of dipeptide products in Gram-positive bacteria, however, their involvement in S. aureus amino acid metabolism has not been investigated. Here, we present the characterization of the putative ATP-grasp enzyme (SAOUHSC_02373) from S. aureus NCTC 8325 and its identification as a novel LAL. First, we interrogated the activity of SAOUHSC_02373 against a panel of ʟ-amino acid substrates. As a result, we identified SAOUHSC_02373 as an LAL with high selectivity for ʟ-aspartate and ʟ-methionine substrates, specifically forming an ʟ-aspartyl-ʟ-methionine dipeptide. Thus, we propose that SAOUHSC_02373 be assigned as ʟ-aspartate-ʟ-methionine ligase (LdmS). To further understand this unique activity, we investigated the mechanism of LdmS by X-ray crystallography, molecular modeling, and site-directed mutagenesis. Our results suggest that LdmS shares a similar mechanism to other ATP-grasp enzymes but possesses a distinctive active site architecture that confers selectivity for the ʟ-Asp and ʟ-Met substrates. Phylogenetic analysis revealed LdmS homologs are highly conserved in Staphylococcus and closely related Gram-positive Firmicutes. Subsequent genetic analysis upstream of the ldmS operon revealed several trans-acting regulatory elements associated with control of Met and Cys metabolism. Together, these findings support a role for LdmS in Staphylococcal sulfur amino acid metabolism.

Unraveling DNA Triplex Assembly: Mass Spectrometric Investigation of Modified Triplex Forming Oligonucleotides for Enhanced Gene Targeting.

Deoxyribonucleic acid triplexes have potential roles in a range of biological processes involving gene and transcriptional regulation. A major challenge in exploiting the formation of these higher-order structures to target genes in vivo is their low stability, which is dependent on many factors including the length and composition of bases in the sequence. Here, different DNA base modifications have been explored, primarily using native mass spectrometry, in efforts to enable stronger binding between the triplex forming oligonucleotide (TFO) and duplex target sites. These modifications can also be used to overcome pyrimidine interruptions in the duplex sequence in promoter regions of genomes, to expand triplex target sequences for antigene therapies. Using model sequences with a single pyrimidine interruption, triplex forming oligonucleotides containing locked nucleic acid base modifications were shown to have a higher triplex binding propensity than DNA-only and dSpacer-containing TFOs. However, the triplex forming ability of these systems was limited by the competitive formation of multiple higher order assemblies. Triplex forming sequences that correspond to specific gene targets from the Pseudomonas aeruginosa genome were also investigated, with LNA-containing TFOs the only variant able to form triplex using these sequences. This work indicates the advantages of utilizing synthetically modified TFOs to form triplex assemblies in vivo for potential therapeutic applications and highlights the advantages of native mass spectrometry for the study of their formation.

Native Mass Spectrometric Insights into the Formation and Stability of DNA Triplexes.

Deoxyribonucleic acid is a genetic biomacromolecule that contains the inherited information required to build and maintain a living organism. While the canonical duplex DNA structure is rigorously characterized, the structure and function of higher order DNA structures such as DNA triplexes are comparatively poorly understood. Previous literature has shown that these triplexes can form under physiological conditions, and native mass spectrometry offers a useful platform to study their formation and stability. However, experimental conditions including buffer salt concentration, pH, and instrumentation parameters such as ion mode can confound analysis by impacting the amount of triplex observed by mass spectrometry. Using model 30mer Y-type triplex sequences, we demonstrate the influence a range of experimental variables have on the detection of DNA triplex structures, informing suitable conditions for the study. When carefully considered conditions are used, mass spectrometry offers a powerful complementary tool for the analysis of higher order DNA assemblies.