Antiviral activity of a purine synthesis enzyme reveals a key role of deamidation in regulating protein nuclear import.

Protein nuclear translocation is highly regulated and crucial for diverse biological processes. However, our understanding concerning protein nuclear import is incomplete. Here we report that a cellular purine synthesis enzyme inhibits protein nuclear import via deamidation. Employing human Kaposi's sarcoma-associated herpesvirus (KSHV) to probe the role of protein deamidation, we identified a purine synthesis enzyme, phosphoribosylformylglycinamidine synthetase (PFAS) that inhibits KSHV transcriptional activation. PFAS deamidates the replication transactivator (RTA), a transcription factor crucial for KSHV lytic replication. Mechanistically, deamidation of two asparagines flanking a positively charged nuclear localization signal impaired the binding of RTA to an importin ß subunit, thus diminishing RTA nuclear localization and transcriptional activation. Finally, RTA proteins of all gamma herpesviruses appear to be regulated by PFAS-mediated deamidation. These findings uncover an unexpected function of a metabolic enzyme in restricting viral replication and a key role of deamidation in regulating protein nuclear import.

The landscape of cancer cell line metabolism.

Despite considerable efforts to identify cancer metabolic alterations that might unveil druggable vulnerabilities, systematic characterizations of metabolism as it relates to functional genomic features and associated dependencies remain uncommon. To further understand the metabolic diversity of cancer, we profiled 225 metabolites in 928 cell lines from more than 20 cancer types in the Cancer Cell Line Encyclopedia (CCLE) using liquid chromatography-mass spectrometry (LC-MS). This resource enables unbiased association analysis linking the cancer metabolome to genetic alterations, epigenetic features and gene dependencies. Additionally, by screening barcoded cell lines, we demonstrated that aberrant ASNS hypermethylation sensitizes subsets of gastric and hepatic cancers to asparaginase therapy. Finally, our analysis revealed distinct synthesis and secretion patterns of kynurenine, an immune-suppressive metabolite, in model cancer cell lines. Together, these findings and related methodology provide comprehensive resources that will help clarify the landscape of cancer metabolism.

Optimized CGenFF force-field parameters for acylphosphate and N-phosphonosulfonimidoyl functional groups.

We report an optimized set of CGenFF parameters that can be used to model small molecules containing acylphosphate and N-phosphonosulfonimidoyl functional groups in combination with the CHARMM force field. Standard CGenFF procedures were followed to obtain bonded interaction parameters, which were validated by geometry optimizations, comparison to the results of calculations at the MP2/6-31+G(d) level of theory, and molecular dynamics simulations. In addition, partial atomic charges were assigned so that the energy of hydrogen bonding of the model compounds with water was correctly reproduced. The availability of these parameters will facilitate computational studies of enzymes that generate acyladenylate intermediates during catalytic turnover. In addition, given that the N-phosphonosulfonimidoyl moiety is a stable transition state analog for the reaction of ammonia with an acyladenylate, the parameters developed in this study should find use in efforts to develop novel and potent inhibitors of various glutamine-dependent amidotransferases that have been validated as drug targets. Topology and parameter files for the model compounds used in this study, which can be combined with other CGenFF parameters in computational studies of more complicated acylphosphates and N-phosphonosulfonimidates are made available.

Characterization of inhibitors acting at the synthetase site of Escherichia coli asparagine synthetase B.

Asparagine synthetase catalyzes the ATP-dependent formation of L-asparagine from L-aspartate and L-glutamine, via a beta-aspartyl-AMP intermediate. Since interfering with this enzyme activity might be useful for treating leukemia and solid tumors, we have sought small-molecule inhibitors of Escherichia coli asparagine synthetase B (AS-B) as a model system for the human enzyme. Prior work showed that L-cysteine sulfinic acid competitively inhibits this enzyme by interfering with L-aspartate binding. Here, we demonstrate that cysteine sulfinic acid is also a partial substrate for E. coli asparagine synthetase, acting as a nucleophile to form the sulfur analogue of beta-aspartyl-AMP, which is subsequently hydrolyzed back to cysteine sulfinic acid and AMP in a futile cycle. While cysteine sulfinic acid did not itself constitute a clinically useful inhibitor of asparagine synthetase B, these results suggested that replacing this linkage by a more stable analogue might lead to a more potent inhibitor. A sulfoximine reported recently by Koizumi et al. as a competitive inhibitor of the ammonia-dependent E. coli asparagine synthetase A (AS-A) [Koizumi, M., Hiratake, J., Nakatsu, T., Kato, H., and Oda, J. (1999) J. Am. Chem. Soc. 121, 5799-5800] can be regarded as such a species. We found that this sulfoximine also inhibited AS-B, effectively irreversibly. Unlike either the cysteine sulfinic acid interaction with AS-B or the sulfoximine interaction with AS-A, only AS-B productively engaged in asparagine synthesis could be inactivated by the sulfoximine; free enzyme was unaffected even after extended incubation with the sulfoximine. Taken together, these results support the notion that sulfur-containing analogues of aspartate can serve as platforms for developing useful inhibitors of AS-B.

Mechanism for acivicin inactivation of triad glutamine amidotransferases.

Acivicin [(alphaS,5S)-alpha-amino-3-chloro-4,5-dihydro-5-isoxazoleacetic acid] was investigated as an inhibitor of the triad glutamine amidotransferases, IGP synthase and GMP synthetase. Nucleophilic substitution of the chlorine atom in acivicin results in the formation of an imine-thioether adduct at the active site cysteine. Cys 77 was identified as the site of modification in the heterodimeric IGPS from Escherichia coli (HisHF) by tryptic digest and FABMS. Distinctions in the glutaminase domains of IGPS from E. coli, the bifunctional protein from Saccharomyces cerevisiae (HIS7), and E. coli GMPS were revealed by the differential rates of inactivation. While the ammonia-dependent turnover was unaffected by acivicin, the glutamine-dependent reaction was inhibited with unit stoichiometry. In analogy to the conditional glutaminase activity seen in IGPS and GMPS, the rates of inactivation were accelerated > or =25-fold when a nucleotide substrate (or analogue) was present. The specificity (k(inact)/K(i)app) for acivicin is on the same order of magnitude as the natural substrate glutamine in all three enzymes. The (alphaS,5R) diastereomer of acivicin was tested under identical conditions as acivicin and showed little inhibitory effect on the enzymes indicating that acivicin binds in the glutamine reactive site in a specific conformation. The data indicate that acivicin undergoes a glutamine amidotransferase mechanism-based covalent bond formation in the presence of nucleotide substrates or products. Acivicin and its (alphaS,5R) diastereomer were modeled in the glutaminase active site of GMPS and CPS to confirm that the binding orientation of the dihydroisoxazole ring is identical in all three triad glutamine amidotransferases. Stabilization of the imine-thioether intermediate by the oxyanion hole in triad glutamine amidotransferases appears to confer the high degree of specificity for acivicin inhibition and relates to a common mechanism for inactivation.

Photoaffinity labeling with the activator IMP and site-directed mutagenesis of histidine 995 of carbamoyl phosphate synthetase from Escherichia coli demonstrate that the binding site for IMP overlaps with that for the inhibitor UMP.

Photoaffinity labeling with IMP was used to attach covalently this activator to its binding site of Escherichia coli carbamoyl phosphate synthetase. We now identify histidine 995 of the large enzyme subunit as the amino acid that is cross-linked with IMP. The identification was carried out by comparative peptide mapping in two chromatographic systems of peptides differentially labeled with [3H]IMP and with the labeled inhibitor [14C]UMP, followed by automated Edman degradation and radiosequence analysis. Site-directed substitution of His995 by alanine confirmed His995 to be the only amino acid in the protein forming a covalent adduct with IMP. The His995Ala mutant protein was soluble and active and exhibited normal kinetics for the activator ornithine and for the substrates in the presence of ornithine. However, the mutation selectively induced changes in the activation by IMP and the inhibition by UMP, and it abolished the photolabeling of the enzyme by IMP without affecting the photolabeling by the inhibitor UMP. Since UMP is cross-linked to Lys993 [Cervera, J., et al. (1996) Biochemistry 35, 7247-7255] only two residues upstream of the site of IMP labeling, the results provide structural evidence for earlier proposals which suggested that UMP and IMP bind in a single or overlapping site. The two residues are within the region previously proposed as the binding fold for the nucleotide effectors. In the crystal structure of the enzyme, Lys993 and His995 are exposed and line a crevice where a Pi molecule was found [Thoden, J. B., et al. (1997) Biochemistry 36, 6305-6316]. UMP and IMP appear to bind in this crevice, possibly toward the C-side of the beta-sheet in a Rossman fold. Their binding in this site is consistent with the selectivity of adduct formation of UMP with Lys993 and of IMP with His995. It is also consistent with the nonessentiality of His995 for the binding, since the interactions with other residues that line the crevice must contribute a large part of the binding energy. The lack of an effect of the mutation on the activation by ornithine is consistent with the binding of this activator in a separate site in the protein.

N2-hydroxyguanosine 5'-monophosphate is a time-dependent inhibitor of Escherichia coli guanosine monophosphate synthetase.

In contrast to several other glutamine amidotransferases including asparagine synthetase, cytidine 5'-triphosphate (CTP) synthetase, carbamoyl phosphate synthetase, and phosphoribosyl pyrophosphate (PRPP) amidotransferase, guanosine monophosphate synthetase (GMPS) will not utilize hydroxylamine as an alternative nitrogen source. Instead, the enzyme is inhibited by an unknown mechanism. One untested hypothesis was that hydroxylamine serves as a substrate and intercepts a xanthosine 5'-monophosphate- (XMP-) adenylate intermediate in the enzyme active site. The nucleotide product of this substitution reaction would be N2-hydroxyguanosine 5'-monophosphate (N2-OH-GMP, 2). Here we describe the chemoenzymatic preparation of 2, via the nucleotide 2-fluoroinosine 5'-monophosphate (F-IMP, 5), and characterization of both these compounds as inhibitors of Escherichia coli GMPS. F-IMP was conceived as an electronic mimic of a reactive intermediate in the GMPS reaction but was found to bind weakly to the enzyme (IC50 > 2 mM). In contrast, N2-OH-GMP shows time-dependent inhibition and is competitive with respect to XMP (Ki = 92 nM), representing the first example of a compound that displays these kinetic properties with GMPS. The mechanism of inhibition is proposed to occur via formation of a ternary E.ATP.2 complex, followed by a rate-determining isomerization to a higher affinity complex that has a t1/2 =7.5 min. The contrast in inhibitory activity for 2-substituted purines with GMPS formulates a basis for future inhibitor design. In addition, these results complement recent structural studies of GMPS and implicate the formation of the XMP-adenylate intermediate inducing a probable conformational change that stimulates the hydrolysis of glutamine.