Assembly of iron-sulfur clusters mediated by cysteine desulfurases,IscS, CsdB and CSD,from Escherichia coli

Cysteine desulfurase plays a principal role in the assembly of iron-sulfur clusters by mobilizing the sulfur atom of L-cysteine. The active site cysteine residue of the enzyme attacks the sulfur atom of L-cysteine to form a cysteine persulfide residue, and the substrate-derived sulfur atom of this residue is incorporated into iron-sulfur clusters. Escherichia coli has three cysteine desulfurases named IscS, CsdB and CSD. We found that each of them facilitates the formation of the iron-sulfur cluster of ferredoxin in vitro. Since IscU, an iron-sulfur protein of E. coli, is believed to function as a scaffold for the cluster assembly in vivo, we examined whether IscS, CsdB and CSD interact with IscU to deliver the sulfur atom to IscU. By surface plasmon resonance analysis, we found that only IscS interacts with IscU. We isolated the IscS/IscU complex, determined the residues involved in the formation of the complex, and obtained data suggesting that the sulfur transfer from IscS to IscU is initiated by the attack of Cys63 of IscU on the S gamma atom of the cysteine persulfide residue transiently produced on IscS.     

The metabolic effects of thia fatty acids in rat liver depend on the position of the sulfur atom

The effects on oxidation and composition of fatty acids in rat liver were compared after administration of fatty acids with sulfur substituted in different positions. It has been hypothesized that drugs with hydrophobic backbone have lipid-lowering effects because they are not easily catabolized by mitochondrial beta-oxidation. Thia fatty acids cannot be beta-oxidized when sulfur is in 3-position, but beta-oxidation is possible when sulfur is positioned further from the carboxyl group. To investigate whether catabolism of thia fatty acids would affect their ability to influence lipid metabolism, a series of thia fatty acids were synthesized and administered by oral gavage to male Wistar rats (300 mg/kg bodyweight/day for 7 days). Depending on the position of the sulfur atom and the chain length, the thia fatty acids were beta-oxidized, desaturated and/or elongated, and the accumulated amounts were lower as the sulfur atom were positioned further from the carboxyl group. All thia fatty acids led to high peroxisomal beta-oxidation of endogenous fatty acids, whereas the mitochondrial beta-oxidation was high when sulfur was in 3-position, low when sulfur was in 4-position and similar to controls when sulfur was in 5- or 7-position. The changes in hepatic fatty acid composition were more pronounced when sulfur was positioned close to the carboxyl group. In conclusion, both the position of the sulfur atom and the chain length appear to determine the catabolic fate of thia fatty acids, and the non-beta-oxidizable thia fatty acids were most potent in regulating oxidation and composition of endogenous fatty acids in rat liver.     

The enzymology of sulfur activation during thiamin and biotin biosynthesis.

The thiamin and biotin biosynthetic pathways utilize elaborate strategies for the transfer of sulfur from cysteine to cofactor precursors. For thiamin, the sulfur atom of cysteine is transferred to a 66-amino-acid peptide (ThiS) to form a carboxy-terminal thiocarboxylate group. This sulfur transfer requires three enzymes and proceeds via a ThiS-acyladenylate intermediate. The biotin synthase Fe-S cluster functions as the immediate sulfur donor for biotin formation. C-S bond formation proceeds via radical intermediates that are generated by hydrogen atom transfer from dethiobiotin to the adenosyl radical. This radical is formed by the reductive cleavage of S-adenosylmethionine by the reduced Fe-S cluster of biotin synthase.     

Transnitrosation of alicyclic N-nitrosamines containing a sulfur atom

Aromatic and aliphatic nitrosamines are known to transfer a nitrosonium ion to another amine. The transnitrosation of alicyclic N-nitroso compounds generates S-nitrosothiols, which are potential nitric oxide donors in vivo. In this study, certain alicyclic N-nitroso compounds based on non-mutagenic N-nitrosoproline or N-nitrosothioproline were synthesised, and the formation of S-nitrosoglutathione (GSNO) was quantified under acidic conditions. We then investigated the effect of a sulfur atom as the substituent and as a ring component on the GSNO formation. In the presence of thiourea under acidic conditions, GSNO was formed from N-nitrosoproline and glutathione, and an N-nitroso compound containing a sulfur atom and glutathione produced GSNO without thiourea. The quantity of GSNO derived from the reaction of the N-nitrosamines containing a sulfur atom and glutathione was higher than that from the N-nitrosoproline and glutathione plus thiourea. Among the analogues that contained a sulfur atom either in the ring or as a substituent, the thiazolidines produced a slightly higher quantity of GSNO than the analogue with a thioamide group. A compound containing sulfur atoms both in the ring and as a substituent exhibited the highest activity for GSNO formation among the alicyclic N-nitrosamines tested. The results indicate that the intramolecular sulfur atom plays an important role in the transnitrosation via alicyclic N-nitroso compounds to form GSNO.     

Occurrence of Conjugated Dienoic Fatty Acids in the Cellular Lipids of Pediococcus homari

Ninety-two thiolcarbamates with various substituents at the nitrogen and sulfur atoms, and their related compounds were synthesized, and their fungicidal activity against rice blast, Piricularia oryzae, and herbicidal activity against barnyardgrass, Echinochloa crus-galli, were determined in laboratory tests. The thiolcarbamate structure was necessary for the high fungicidal and herbicidal activities. The hydrophobicity of the substituents at the nitrogen atom was shown by the adaptive least-squares (ALS) method to be favorable to the fungicidal activity. The bulkier the substituents at the nitrogen atom, the less was the fungicidal activity. However, bulkiness of the substituents at the nitrogen and sulfur atoms was unfavorable to the herbicidal activity. The existence of a hydrogen atom at the nitrogen atom was favorable to fungicidal activity, but not to herbicidal activity. Correlation analyses were made to find compounds with both fungicidal and herbicidal activities against rice pests.     

The glial Gomori-positive material is sulfane sulpfur

The Gomori-positive glia are periventricular astrocytes with abundant cytoplasmic granular material, predominantly occupying a periventricular site in the brain. These granular inclusions are strongly stained with chrome hematoxylin in the Gomori's method as well as exhibit red autofluorescence and non-enzymatic peroxidase activity. The glial Gomori-positive material (GGPM) granules are positive in the performic acid Alcian blue method indicating the presence of protein-bound sulfur, what has been shown by our previous studies. The number of cells containing glial Gomori-positive granules dropped after administration of cyanide and increased under the influence of sulfane sulfur donor (diallyl disulfide). This suggests, that sulfur of these granules is a sulfane sulfur, possibly in the form of protein-bound cysteine persulfide. Sulfane sulfur is labile, reactive sulfur atom covalently bound to another sulfur atom. In this paper we present evidence that GGPM exhibit affinity to cyanolysis and its stainability in Gomori's method is due to the presence of protein-bound sulfane sulfur. The biological role of the Gomori-positive glia connected with protective properties of sulfane sulfur has been discussed.     

Biotin analogs activate guanylate cyclase

Summary The sulfur atom in the vitamin biotin has previously been suggested to be essential in biotin's mechanism of action. In a series of investigations on structure-function relationships with biotin analogs not containing the sulfur atom, the biotin analogs, azabiotin, bisnorazabiotin, carbobiotin and isoazabiotin enhanced guanylate cyclase, an enzyme that has recently been demonstrated to be activated by biotin. These analogs increased guanylate cyclase activity two-fold in liver, cerebellum, heart, kidney and colon at 1 M concentrations. The ED₅₀ for stimulation of guanulate cyclase activity occurred at 0.1 M for each of the biotin analogs. These data indicate that the sulfur atom is not essential in biotin's activation of guanylate cyclase since these analogs do not contain the sulfur atom. Studies on the ring structure of biotin revealed that even compounds with a single 5-membered ring (2-imidazolidone) could augment guanylate cyclase activity. The guanylate cyclase co-factor manganese was not essential for the enhancement of guanylate cyclase by these agents but a maximal activation of this enzyme by these analogs could not be obtained without manganese present.     

Determination of the metabolic origins of the sulfur and 3'-nitrogen atoms in biotin of Escherichia coli by mass spectrometry

Two steps in the biosynthesis of biotin in Escherichia coli, incorporation of the nitrogen atom of methionine into 7-keto-8-aminopelargonic acid and of the sulfur atom into dethiobiotin, were examined. Sulfur and nitrogen metabolism were monitored by gas chromatography-mass spectrometry of volatile derivatives of internal (protein-bound) amino acids and excreted biotin. We were able to show that internal cysteine and excreted biotin were labeled to the same extent with 34S from either of two exogenous sulfur sources, 34SO4(2)-or L-[sulfane-34S]thiocystine. Internal methionine was eliminated from consideration, while cysteine, or possibly a closely related intermediate, was implicated as providing the sulfur atom for biotin biosynthesis. Also, in experiments designed to follow the metabolism of the nitrogen atom of methionine, it was found that biotin excreted into the culture medium by this organism grown with 95 atom % [15N]methionine contained greater than 70 atom % excess 15N in one of the nitrogens over that obtained from cultures grown with methionine of natural abundance 15N. These results provide evidence for the direct transfer of the methionine nitrogen as the role of S-adenosylmethionine in the conversion of 7-keto-8-aminopelargonic acid to 7,8-diaminopelargonic acid.     

The origin of the sulfur atom in thiamine.

The mode of biosynthesis of the thiazole moiety of thiamine, 4-methyl-5beta-hydroxyethyl thiazole (MHET) was studied using Salmonella typhimurium as test organism. It was shown by isotope incorporation experiments, that the sulfur atom, but not carbon-3, of cysteine is incorporated into MHET, indicating a separation of the sulfur atom of cysteine from the carbon chain during incorporation. Isotope competition experiments revealed that the incorporation of [35S]cysteine is not significantly diluted by the presence of methionine, homocysteine, and glutathione. No incorporation of label from [14C]glutamate and [14C]formate was observed, leaving the origin of the five-carbon unit still in doubt.     

Differences in the binding of sulfate, selenate and thiosulfate ions to bovine liver rhodanese, and a description of a binding site for ammonium and sodium ions. An X-ray diffraction study

The binding of sulfate, selenate and thiosulfate by the sulfur-transferase rhodanese (EC 2.8.1.1) in the crystalline state has been studied by X-ray analysis at resolutions between 0.23 nm and 0.4 nm. The three ions appear to occupy a common site between the N eta atoms of Arg-29 and the main-chain NH group of Glu-148 at the surface of the enzyme molecule. A second binding site for the three ions is situated at the entrance to the active centre, between the side chains of Arg-186 and Lys-249. Selenate and thiosulfate are bound equally well at both anion-binding sites. Sulfate, however, binds better at the first position, near Arg-29, than at the second site near Arg-186. In the complex of sulfur-rhodanese with thiosulfate, the outer sulfur atom of the anion near the active centre points towards the extra sulfur atom which is bound as a persulfide to the S gamma of the essential Cys-247. The distance between the outer sulfur atom of the thiosulfate ion and the persulfide sulfur atom appears to be about 0.3 nm. The thiosulfate difference Fourier also shows a distinct, localized conformational change involving residues 71, 72 and 249. This is the result of the replacement of an ammonium ion in the sulfate and selenate media by a sodium ion in the sodium thiosulfate solution. Rhodanese is apparently able to accomodate ions with different radii at this cation-binding site by minor structural alterations.     

1-Methyl-DL-tryptophan, beta-(3-benzofuranyl)-DL-alanine (the oxygen analog of tryptophan), and beta-[3-benzo(b)thienyl]-DL-alanine (the sulfur analog of tryptophan) are competitive inhibitors for indoleamine 2,3-dioxygenase

1-methyl-DL-Trp, beta-(3-benzofuranyl)-DL-alanine (the oxygen analog of Trp), and beta-[3-benzo(b)thienyl]-DL-alanine (the sulfur analog of Trp), each of which has a substitution at the indole nitrogen atom, were found to be the first examples of potent substrate analog competitive inhibitors (Ki 7-70 microM) with respect to the substrates D-Trp and L-Trp for rabbit small intestinal indoleamine 2,3-dioxygenase. Binding studies using optical absorption and CD spectroscopy demonstrated that these three inhibitors cause spectral changes upon binding to the native ferric, ferrous, ferrous-CO, and ferrous-NO enzymes. Such spectral effects of 1-methyl-DL-Trp on all of these enzyme derivatives were similar to those caused by L-Trp, while the sulfur and the oxygen analogs of Trp exhibit relatively small effects except for those observed for the sulfur analog with CD spectroscopy. Each of these three Trp analog inhibitors competes with L-Trp for the ferrous-CO enzyme, a model for the ferrous-O2 enzyme. The present findings demonstrate that, although substitution of a methyl group for the hydrogen atom on the indole nitrogen or of a more electron-inductive sulfur or oxygen atom for the indole nitrogen atom does not prevent the binding of the resulting Trp analog to indoleamine 2,3-dioxygenase, the free form of the indole nitrogen base is an important physical and/or electronic structural requirement for Trp to be metabolized by the enzyme. The inability of 1-methyl-Trp to serve as a substrate for the dioxygenase supports a view that singlet oxygen is not the reactive oxygen species involved in the dioxygenation of Trp by the enzyme.     

Molecular modeling of penicilloate anions: an RHF-SCF analysis

An ab initio restricted Hartree-Fock self-consistent field (RHF-SCF) analysis of penicilloate anions was performed at the TZV level with GAMESS. Geometry optimization was initialized by the semi-empirical AM1 method followed by optimization at the 6-31++G** level. The total energy obtained was -1116.0997 a.u. for the penicilloate amine, -1115.3164 a.u. for the imine, -1115.2969 a.u. for the enamine and -1115.2017 a.u. for the amine that was deprotonated at the thiazolidine nitrogen. Formation of the free thiolate in the imine and enamine anions by deprotonation of the penicilloate amine is associated with: (1) an increase in total energy (2) an increase in the energy of the highest occupied molecular orbital (HOMO) to that of anti-bonding (3) a decrease in chemical hardness (4) an increase in the chemical potential (5) a more negative Mulliken net charge on the sulfur atom and (6) an increase in the Mulliken atomic population on the former thiazolidine sulfur atom in the HOMO. The RHF-SCF analysis presented here suggests a potential role for the thiolate sulfur of penicilloate anions, especially of the imine, as a chemically reactive soft nucleophile.     

The origin of the sulfur atom in thiamine

The mode of biosynthesis of the thiazole moiety of thiamine, 4-methyl-5β-hydroxyethyl thiazole (MHET) was studied using Salmonella typhimurium as test organism. It was shown by isotope incorporation experiments, that the sulfur atom, but not carbon-3, of cysteine is incorporated into MHET, indicating a separation of the sulfur atom of cysteine from the carbon chain during incorporation. Isotope competition experiments revealed that the incorporation of [³⁵S]cysteine is not significantly diluted by the presence of methionine, homocysteine, and glutathione. No incorporation of label from [¹⁴C]glutamate and [¹⁴C]formate was observed, leaving the origin of the five-carbon unit still in doubt.     

The synthesis of thio- and selenoanalogues of phospholipids on the basis of 2-butyl-2-hydroxymethyl-1,3-propanediol

New analogues of nonglycerol polyol phospholipids were prepared on the basis of 1,1,1-trimethylolethane. Amidophosphites and cyclophosphites of the isopropylidene derivative of this polyol were intermediates in the syntheses. They were treated with sulfur or selenium. Phosphoacetals were converted into lipids by the direct acylation with higher fatty acid chlorides. The triol bicyclophosphite was also used in the lipid syntheses. It was directly acylated at the oxygen atom, the resulting acylpolyol of chlorophosphite was then converted into phospholipids by alcoholysis and subsequent treatment with sulfur.     

Insertion of an electronegative sulfur atom in the side chain of position 5 of angiotensin II: changes in the tachyphylactic properties of the peptide.

Angiotensin II (AII) analogs bearing n-Leu, Met or S-substituted groups for cysteine at position 5 were studied regarding their agonistic and tachyphylactic properties. It was shown that these analogs lowered the relative affinity towards the AT1 receptor as determined by contractile responses, which could be due to the removal of the beta-branching residue at position 5. Insertion of a sulfur atom in a different position away from the attached backbone carbon atom presented no significant difference in EC50 values for these analogs. Interestingly, the S-bearing analogs at position 5 were full agonists but the tachyphylactic property was lost, in contrast to [n-Leu5]AII, which still induced reduction of the contractile responses. Nevertheless after replacing the Asp with Sar in position 1 (Sar1) tachyphylaxis was again established. It is concluded that the insertion of Met or an S-substituted cysteine into the side chain at position 5 of AII may promote interactions with its receptor due to the slight electronegative character of the sulfur atom and changes in the restricted conformational freedom of the Ile5 residue in the AII molecule. This was overcome by Sar1, probably through interactions due to its fully protonated N-terminal amino group and favoring the conformation responsible for the tachyphylaxis phenomenon.     

Non-hydrogen bond interactions involving the methionine sulfur atom

Of all the nonbonded interactions, hydrogen bond, because of its geometry involving polar atoms, is the most easily recognizable. Here we characterize two interactions involving the divalent sulfur of methionine (Met) residues that do not need any participation of proton. In one an oxygen atom of the main-chain carbonyl group or a carboxylate side chain is used. In another an aromatic atom interacting along the face of the ring is utilized. In these, the divalent sulfur behaves as an electrophile and the other electron-rich atom, a nucleophile. The stereochemistry of the interaction is such that the nucleophile tends to approach approximately along the extension of one of the covalent bonds to S. The nitrogen atom of histidine side chain is extensively used in these nonbonded contacts. There is no particular geometric pattern in the interaction of S with the edge of an aromatic ring, except when an N-H group in involved, which is found within 40 degrees from the perpendicular to the sulfide plane, thus defining the geometry of hydrogen bond interaction involving the sulfur atom. As most of the Met residues which partake in such stereospecific interactions are buried, these would be important for the stability of the protein core, and their incorporation in the binding site would be useful for molecular recognition and optimization of the site's affinity for partners (especially containing aromatic and heteroaromatic groups). Mutational studies aimed at replacing Met by other residues would benefit from the delineation of these interactions.     

Synthesis of a novel class of sulfonium ions as potential inhibitors of UDP-galactopyranose mutase

Two sulfonium salts of 1,4-anhydro-4-thio-D-galactitol, with structures related to the known sulfonium salt glycosidase inhibitor, salacinol, have been synthesized as potential inhibitors of UDP-galactopyranose mutase. The synthetic strategy relies on the alkylation reaction of 1,4-anhydro-2,3,5,6-tetra-O-benzyl-4-thio-D-galactitol at the sulfur atom with 2,4-O-benzylidene-D- or -L-erythritol-1,3-cyclic sulfate. In each case, the reaction proceeded stereoselectively to yield only one stereoisomer at the stereogenic sulfur atom. The effect of the polar solvent, 1,1,1,3,3,3-hexafluoroisopropanol (HFIP), in promoting high-yielding reactions is highlighted. The target compounds are then obtained by hydrogenolysis.     

Sulfur-Specific Microbial Desulfurization of Sterically Hindered Analogs of Dibenzothiophene

Dibenzothiophenes (DBTs) bearing alkyl substitutions adjacent to the sulfur atom, such as 4,6-diethyldibenzothiophene (4,6-DEDBT), are referred to as sterically hindered with regard to access to the sulfur moiety. By using enrichment cultures with 4,6-DEDBT as the sole sulfur source, bacterial isolates which selectively remove sulfur from sterically hindered DBTs were obtained. The isolates were tentatively identified as Arthrobacter species. 4,6-DEDBT sulfone was shown to be an intermediate in the 4,6-DEDBT desulfurization pathway, and 2-hydroxy-3,3(prm1)-diethylbiphenyl (HDEBP) was identified as the sulfur-free end product.     

Structure of bis(2-acetylpyridine 3-hexamethyleneiminylthiosemicarbazonato) palladium II,a potential antitumor complex

The crystal structure of the potential antitumor complex bis(2-acetyppyridine 3-hexamethyleneiminylthiosemicarbazonato)palladium(II) has been solved. The palladium(II) atom is in a square planar environment surrounded by two cis nitrogen atoms and two cis sulfur atoms. The ligands are not equivalent, one being tridentate with (N,N,S) donation, the other being monodentate using only the sulfur atom to coordinate to the metal. The tridentate ligand shows a Z, E, Z configuration while the monodentate ligand shows an E, E, Z. Intermolecular hydrogen bonds stabilize the structure, while the crystal packing is determined by Pd-C, Pd-pi, C-H-pi and pi-pi interactions.     

The Cysteine Desulfhydrase CdsH Is Conditionally Required for Sulfur Mobilization to the Thiamine Thiazole in Salmonella enterica

Thiamine pyrophosphate is a required coenzyme that contains a mechanistically important sulfur atom. In Salmonella enterica, sulfur is trafficked to both thiamine biosynthesis and 4-thiouridine biosynthesis by the enzyme ThiI using persulfide (R-S-S-H) chemistry. It was previously reported that a thiI mutant strain could grow independent of exogenous thiamine in the presence of cysteine, suggesting there was a second mechanism for sulfur mobilization. Data reported here show that oxidation products of cysteine rescue the growth of a thiI mutant strain by a mechanism that requires the transporter YdjN and the cysteine desulfhydrase CdsH. The data are consistent with a model in which sulfide produced by CdsH reacts with cystine (Cys-S-S-Cys), S-sulfocysteine (Cys-S-SO₃⁻), or another disulfide to form a small-molecule persulfide (R-S-S-H). We suggest that this persulfide replaced ThiI by donating sulfur to the thiamine sulfur carrier protein ThiS. This model describes a potential mechanism used for sulfur trafficking in organisms that lack ThiI but are capable of thiamine biosynthesis.