The Histidine Ammonia Lyase of Trypanosoma cruzi Is Involved in Acidocalcisome Alkalinization and Is Essential for Survival under Starvation Conditions.

Trypanosoma cruzi, the agent of Chagas disease, accumulates polyphosphate (polyP) and Ca2+ inside acidocalcisomes. The alkalinization of this organelle stimulates polyP hydrolysis and Ca2+ release. Here, we report that histidine ammonia lyase (HAL), an enzyme that catalyzes histidine deamination with production of ammonia (NH3) and urocanate, is responsible for acidocalcisome alkalinization. Histidine addition to live parasites expressing HAL fused to the pH-sensitive emission biosensor green fluorescent protein (GFP) variant pHluorin induced alkalinization of acidocalcisomes. PolyP decreased HAL activity of epimastigote lysates or the recombinant protein but did not cause its polyphosphorylation, as determined by the lack of HAL electrophoretic shift on NuPAGE gels using both in vitro and in vivo conditions. We demonstrate that HAL binds strongly to polyP and localizes to the acidocalcisomes and cytosol of the parasite. Four lysine residues localized in the HAL C-terminal region are instrumental for its polyP binding, its inhibition by polyP, its function inside acidocalcisomes, and parasite survival under starvation conditions. Expression of HAL in yeast deficient in polyP degradation decreased cell fitness. This effect was enhanced by histidine and decreased when the lysine-rich C-terminal region was deleted. In conclusion, this study highlights a mechanism for stimulation of acidocalcisome alkalinization linked to amino acid metabolism. IMPORTANCE Trypanosoma cruzi is the etiologic agent of Chagas disease and is characterized by the presence of acidocalcisomes, organelles rich in phosphate and calcium. Release of these molecules, which are necessary for growth and cell signaling, is induced by alkalinization, but a physiological mechanism for acidocalcisome alkalinization was unknown. In this work, we demonstrate that a histidine ammonia lyase localizes to acidocalcisomes and is responsible for their alkalinization.

Histidine protects against zinc and nickel toxicity in Caenorhabditis elegans.

Zinc is an essential trace element involved in a wide range of biological processes and human diseases. Zinc excess is deleterious, and animals require mechanisms to protect against zinc toxicity. To identify genes that modulate zinc tolerance, we performed a forward genetic screen for Caenorhabditis elegans mutants that were resistant to zinc toxicity. Here we demonstrate that mutations of the C. elegans histidine ammonia lyase (haly-1) gene promote zinc tolerance. C. elegans haly-1 encodes a protein that is homologous to vertebrate HAL, an enzyme that converts histidine to urocanic acid. haly-1 mutant animals displayed elevated levels of histidine, indicating that C. elegans HALY-1 protein is an enzyme involved in histidine catabolism. These results suggest the model that elevated histidine chelates zinc and thereby reduces zinc toxicity. Supporting this hypothesis, we demonstrated that dietary histidine promotes zinc tolerance. Nickel is another metal that binds histidine with high affinity. We demonstrated that haly-1 mutant animals are resistant to nickel toxicity and dietary histidine promotes nickel tolerance in wild-type animals. These studies identify a novel role for haly-1 and histidine in zinc metabolism and may be relevant for other animals.

Computational investigation of the histidine ammonia-lyase reaction: a modified loop conformation and the role of the zinc(II) ion.

Possible reaction intermediates of the histidine ammonia-lyase (HAL) reaction were investigated within the tightly closed active site of HAL from Pseudomonas putida (PpHAL). The closed structure of PpHAL was derived from the crystal structure of PpHAL inhibited with L-cysteine, in which the 39-80 loop including the catalytically essential Tyr53 was replaced. This modified loop with closed conformation was modeled using the structure of phenylalanine ammonia-lyase from Anabaena variabilis (AvPAL) with a tightly closed active site as a template. Three hypothetical structures of the covalently bound intermediate in the PpHAL active site were investigated by conformational analysis. The distances between the acidic pro-S ß-hydrogen of the ligand and the appropriate oxygen atoms of Tyr53, Ty280 and Glu414--which may act as enzymic bases--in the conformations of the three hypothetical intermediate structures were analyzed together with the substrate and product arrangements. The calculations indicated that the most plausible HAL reaction pathway involves the N-MIO intermediate structure in which the L-histidine substrate is covalently bound to the N-3,5-dihydro-5-methylidene-4H-imidazol-4-one (MIO) prosthetic group of the apoenzyme via the amino group. Density functional theory (DFT) calculations--on a truncated model of the N-MIO intermediate containing a Zn²âº ion coordinated to the imidazole ring of the ligand and to His83, Met382 and a water molecule--indicated that Zn-complex formation plays a role in the reactivity and substrate specificity of HAL.

Structures of two histidine ammonia-lyase modifications and implications for the catalytic mechanism.

Histidine ammonia-lyase (EC 4.3.1.3) catalyzes the nonoxidative elimination of the alpha-amino group of histidine using a 4-methylidene-imidazole-5-one (MIO), which is formed autocatalytically from the internal peptide segment 142Ala-Ser-Gly. The structure of the enzyme inhibited by a reaction with l-cysteine was established at the very high resolution of 1.0 A. Five active center mutants were produced and their catalytic activities were measured. Among them, mutant Tyr280-->Phe could be crystallized and its structure could be determined at 1.7 A resolution. It contains a planar sp2-hybridized 144-N atom of MIO, in contrast to the pyramidal sp3-hybridized 144-N of the wild-type. With the planar 144-N atom, MIO assumes the conformation of a putative intermediate aromatic state of the reaction, demonstrating that the conformational barrier between aromatic and wild-type states is very low. The data led to a new proposal for the geometry for the catalyzed reaction, which also applies to the closely related phenylalanine ammonia-lyase (EC 4.3.1.5). Moreover, it suggested an intermediate binding site for the released ammonia.

Autocatalytic peptide cyclization during chain folding of histidine ammonia-lyase.

Histidine ammonia-lyase requires a 4-methylidene-imidazole-5-one group (MIO) that is produced autocatalytically by a cyclization and dehydration step in a 3-residue loop of the polypeptide. The crystal structures of three mutants have been established. Two mutants were inactive and failed to form MIO, but remained unchanged elsewhere. The third mutant showed very low activity and formed MIO, although it differed from an MIO-less mutant only by an additional 329-C(beta) atom. This atom forms one constraint during MIO formation, the other being the strongly connected Asp145. An exploration of the conformational space of the MIO-forming loop showed that the cyclization is probably enforced by a mechanic compression in a late stage of chain folding and is catalyzed by a well-connected internal water molecule. The cyclization of the respective 3-residue loop of green fluorescent protein is likely to occur in a similar reaction.

Characterization of the active site of histidine ammonia-lyase from Pseudomonas putida.

Elucidation of the 3D structure of histidine ammonia-lyase (HAL, EC 4.3.1.3) from Pseudomonas putida by X-ray crystallography revealed that the electrophilic prosthetic group at the active site is 3,5-dihydro-5-methylidene-4H-imidazol-4-one (MIO) [Schwede, T.F., Rétey, J., Schulz, G.E. (1999) Biochemistry, 38, 5355-5361]. To evaluate the importance of several amino-acid residues at the active site for substrate binding and catalysis, we mutated the following amino-acid codons in the HAL gene: R283, Y53, Y280, E414, Q277, F329, N195 and H83. Kinetic measurements with the overexpressed mutants showed that all mutations resulted in a decrease of catalytic activity. The mutants R283I, R283K and N195A were approximately 1640, 20 and 1000 times less active, respectively, compared to the single mutant C273A, into which all mutations were introduced. Mutants Y280F, F329A and Q277A exhibited approximately 55, 100 and 125 times lower activity, respectively. The greatest loss of activity shown was in the HAL mutants Y53F, E414Q, H83L and E414A, the last being more than 20 900-fold less active than the single mutant C273A, while H83L was 18 000-fold less active than mutant C273A. We propose that the carboxylate group of E414 plays an important role as a base in catalysis. To investigate a possible participation of active site amino acids in the formation of MIO, we used the chromophore formation upon treatment of HAL with l-cysteine and dioxygen at pH 10.5 as an indicator. All mutants, except F329A showed the formation of a 338-nm chromophore arising from a modified MIO group. The UV difference spectra of HAL mutant F329A with the MIO-free mutant S143A provide evidence for the presence of a MIO group in HAL mutant F329A also. For modelling of the substrate arrangement within the active site and protonation state of MIO, theoretical calculations were performed.

Crystal structure of histidine ammonia-lyase revealing a novel polypeptide modification as the catalytic electrophile.

Histidine ammonia-lyase (EC 4.3.1.3) catalyzes the nonoxidative elimination of the alpha-amino group of histidine and is closely related to the important plant enzyme phenylalanine ammonia-lyase. The crystal structure of histidase from Pseudomonas putida was determined at 2.1 A resolution revealing a homotetramer with D2 symmetry, the molecular center of which is formed by 20 nearly parallel alpha-helices. The chain fold, but not the sequence, resembles those of fumarase C and related proteins. The structure shows that the reactive electrophile is a 4-methylidene-imidazole-5-one, which is formed autocatalytically by cyclization and dehydration of residues 142-144 with the sequence Ala-Ser-Gly. With respect to the first dehydration step, this modification resembles the chromophore of the green fluorescent protein. The active center is clearly established by the modification and by mutations. The observed geometry allowed us to model the bound substrate at a high confidence level. A reaction mechanism is proposed.

Homogenization and crystallization of histidine ammonia-lyase by exchange of a surface cysteine residue.

Histidase (histidine ammonia-lyase, EC 4.3.1.3) from Pseudomonas putida was expressed in Escherichia coli and purified. In the absence of thiols the tetrameric enzyme gave rise to undefined aggregates and suitable crystals could not be obtained. The solvent accessibility along the chain was predicted from the amino acid sequence. Among the seven cysteines, only one was labeled as 'solvent-exposed'. The exchange of this cysteine to alanine abolished all undefined aggregations and yielded readily crystals diffracting to 1.8 A resolution.

Site-directed mutagenesis of conserved serines in rat histidase. Identification of serine 254 as an essential active site residue.

We have identified serine 254 as an essential residue in rat histidase (histidine ammonia-lyase, EC 4.3.1.3). Histidase and phenylalanine ammonia-lyase are the only two enzymes that have been postulated to require the modified amino acid, dehydroalanine, for enzyme activity. In the bacterial peptides nisin and subtilin, and in the pyruvoyl enzymes, the precursor for dehydroalanine is a serine. To determine whether serine may be the dehydroalanine precursor in rat histidase, we substituted four highly conserved serines with alanines, and expressed the mutated histidase cDNAs in COS cells, which have no endogenous histidase activity. Substitution of serines 223, 254, 508, and 533 resulted in the production of approximately equal amounts of histidase protein with histidase activities of 2.4, 0.0, 75, and 16%, respectively. The abrogation of histidase activity by the substitution of alanine for serine 254, together with the modification by L-cysteine of the corresponding residue in Pseudomonas putida histidase (Hernandez, C., Stroh, J. G., and Phillips, A. T. (1993) Arch. Biochem. Biophys. 307, 126-132), is strong evidence that this residue is the precursor of the essential electrophilic moiety of histidase.

Histidine ammonia-lyase mutant S143C is posttranslationally converted into fully active wild-type enzyme. Evidence for serine 143 to be the precursor of active site dehydroalanine.

Histidase [histidine ammonia-lyase (HAL); EC 4.3.1.3] from Pseudomonas putida is a homotetramer and contains one catalytically essential dehydroalanine residue per subunit. Since the mutant S143A was catalytically inert, it has been proposed that serine 143 is the precursor of the active site dehydroalanine [Langer et al. (1994) Biochemistry 33, 6462-6467]. To further define the role of serine 143, we prepared the mutants S143T and S143C by site-directed mutagenesis. The threonine 143 mutant was neither catalytically active (< 0.01%) nor did it form with L-cysteine and oxygen a product absorbing at 340 nm. In contrast, the cysteine 143 mutant showed full catalytic activity and, after treatment with L-cysteine and oxygen, an increased absorbance at 340 nm similar to that of the wild-type enzyme. Also the kinetic constants (Km and Vmax) were identical with those of wild-type histidase. Titration with Ellman's reagent revealed that both wild-type and S143C mutant histidase contained seven thiol groups after exhaustive reduction. It must be concluded that posttranslational modification occurs with both serine 143 and cysteine 143 by elimination of water and hydrogen sulfide, respectively. In both cases dehydroalanine is formed and the resulting histidases are indistinguishable. In contrast, the threonine 143 mutant is not processed to active enzyme.

Ser-143 is an essential active site residue in histidine ammonia-lyase of Pseudomonas putida.

Site directed mutagenesis was used to investigate the role of Ser-143 in enzyme activity and as a point for attack by cyanide or L-cysteine, two irreversible inhibitors of histidine ammonia-lyase (histidase). Two mutant proteins, a S143A substitution and an A142S-S143A transposition, were made. Both mutant histidases completely lost all enzymatic activity. Western blots with anti-histidase antibodies revealed that the mutant proteins were being expressed at a level equal to that of the wild-type protein. The purified mutant proteins could not incorporate [14C]cyanide nor could they generate the UV-absorbing species normally observed when L-cysteine modifies wild-type histidase. These results support the hypothesis that Ser-143 is the binding site for an as yet unidentified histidase cofactor.