Crystal structure of the human estrogen sulfotransferase-PAPS complex: evidence for catalytic role of Ser137 in the sulfuryl transfer reaction

Estrogen sulfotransferase (EST) transfers the sulfate group from 3'-phosphoadenosine 5'-phosphosulfate (PAPS) to estrogenic steroids. Here we report the crystal structure of human EST (hEST) in the context of the V269E mutant-PAPS complex, which is the first structure containing the active sulfate donor for any sulfotransferase. Superimposing this structure with the crystal structure of hEST in complex with the donor product 3'-phosphoadenosine 5'-phosphate (PAP) and the acceptor substrate 17beta-estradiol, the ternary structure with the PAPS and estradiol molecule, is modeled. These structures have now provided a more complete view of the S(N)2-like in-line displacement reaction catalyzed by sulfotransferases. In the PAPS-bound structure, the side chain nitrogen of the catalytic Lys(47) interacts with the side chain hydroxyl of Ser(137) and not with the bridging oxygen between the 5'-phosphate and sulfate groups of the PAPS molecule as is seen in the PAP-bound structures. This conformational change of the side chain nitrogen indicates that the interaction of Lys(47) with Ser(137) may regulate PAPS hydrolysis in the absences of an acceptor substrate. Supporting the structural data, the mutations of Ser(137) to cysteine and alanine decrease gradually k(cat) for PAPS hydrolysis and transfer activity. Thus, Ser(137) appears to play an important role in regulating the side chain interaction of Lys(47) with the bridging oxygen between the 5'-phosphate and the sulfate of PAPS.     

Comparison of estrogen sulfotransferase and pregnenolone sulfotransferase of guinea pig.

Guinea pig adrenal estrogen sulfotransferase from either sex was eluted as a single peak, irrespective of buffer salt concentration, when subjected to fast protein liquid chromatography on gel filtration columns. The same enzyme was consistently eluted in two distinct peaks during chromatofocusing. Adrenal pregnenolone sulfotransferase was eluted during gel filtration in a heterogeneous pattern, dependent on salt concentration. These properties have made possible almost complete separation of the two sulfotransferases in one step, although adrenal estrogen sulfotransferase may possess a minute intrinsic ability to catalyze sulfation of pregnenolone. Pregnenolone sulfotransferase had no measurable activity toward estrone. Pregnenolone sulfotransferase from both sexes yielded variable elution patterns during chromatofocusing. Estrogen sulfotransferase from the adrenal, as well as that of guinea pig chorion, was strongly inhibited by N-ethylmaleimide and to a lesser degree by iodoacetamide and iodoacetate. Adrenal and chorion estrogen sulfotransferases were thermolabile and were activated, although not protected from the effect of heat, by binding to 3'-phosphoadenosine 5'-phosphosulfate. Adrenal pregnenolone sulfotransferase was inhibited only by high concentrations of N-ethylmaleimide and not at all by iodoacetamide or iodoacetate. It was more thermostable than the estrogen sulfotransferase and was not activated by binding to 3'-phosphoadenosine 5'-phosphosulfate.     

Expression of an isoform of the testis-specific estrogen sulfotransferase in the murine placenta during the late gestational period

Cytosolic sulfotransferases play essential roles in regulating the activities and transfer of steroids. To evaluate their biological significance in the murine uterus and placenta during the course of gestation, we determined their activities with several steroids as substrates. Activated estrogen sulfotransferase (EST) was found in the placenta and uterus during the late gestational period. Reverse-transcribed cDNA of murine placental EST (mpEST) was isolated from mouse placenta at 18 days of gestation and its expression in the tissue coincided with a change in its enzyme activity. The open-reading frame of mpEST encodes a protein composed of 296 amino acids with a predicted molecular mass of 35.5 kDa and was revealed to be an isoform of the murine testis-specific EST gene (99.7%). Also, the amino acid sequence of mpEST showed 49.6 and 77.9% homology with human placental and endometrial EST, respectively, showing that it corresponds to human endometrial EST. COS-7 cells transfected with mpEST exhibited sulfotransferase activity with the phenolic hydroxy groups of steroids and artificial substrates. The best acceptor substrate was estrogen.     

Crystal structure-based studies of cytosolic sulfotransferase

Sulfation is a widely observed biological reaction conserved from bacterium to human that plays a key role in various biological processes such as growth, development, and defense against adversities. Deficiencies due to the lack of the ubiquitous sulfate donor 3'-phosphoadenosine-5'-phosphosulfate (PAPS) are lethal in humans. A large group of enzymes called sulfotransferases catalyze the transfer reaction of sulfuryl group of PAPS to the acceptor group of numerous biochemical and xenochemical substrates. Four X-ray crystal structures of sulfotransferases have now been determined: cytosolic estrogen, hydroxysteroid, aryl sulfotransferases, and a sulfotransferase domain of the Golgi-membrane heparan sulfate N-deacetylase/N-sulfotransferase 1. These have revealed the conserved core structure of the PAPS binding site, a common reaction mechanism, and some information concerning the substrate specificity. These crystal structures introduce a new era of the study of the sulfotransferases.     

A continuous assay for the spectrophotometric analysis of sulfotransferases using aryl sulfotransferase IV.

We have developed a continuous spectrophotometric coupled-enzyme assay for sulfotransferase activity. This assay is based on the regeneration of 3'-phosphoadenosine-5'-phosphosulfate (PAPS) from the desulfated 3'-phosphoadenosine-5'-phosphate (PAP) by a recombinant aryl sulfotransferase using p-nitrophenyl sulfate as the sulfate donor and visible spectrophotometric indicator of enzyme turnover. Here recombinant rat aryl sulfotransferase IV (AST-IV) is expressed, resolved to the pure beta-form during purification, and utilized for the regeneration. The activity of betaAST-IV to catalyze the synthesis of PAPS from PAP and p-nitrophenyl sulfate is demonstrated via capillary zone electrophoresis, and the kinetics of this reverse-physiological reaction are calculated. betaAST-IV is then applied to the coupled enzyme system, where the steady-state activity of the commercially available Nod factor sulfotransferase is verified with an enzyme concentration study and substrate-specificity assays of N-chitoses. The potential applications of this assay include rapid kinetic determinations for carbohydrate and protein sulfotransferases, high-throughput screening of potential sulfotransferase substrates and inhibitors, and biomedical screening of blood samples and other tissues for specific sulfotransferase enzyme activity and substrate concentration.     

Immunocytochemical Localization and Biological Activity of Hydroxysteroid Sulfotransferase in the Frog Brain

Abstract : Biosynthesis of the neuroactive steroids pregnenolone sulfate (▵⁵PS) and dehydroepiandrosterone sulfate (DHEAS) is catalyzed by the enzyme hydroxysteroid sulfotransferase (HST), which transfers the sulfonate moiety from 3'-phosphoadenosine 5' -phosphosulfate (PAPS) on thye 3-hydroxy site of steroids. Although high concentrations of ▵⁵PS and DHEAS have been detected in the rat brain, the anatomical localization of HST in the CNS has never been determined. Using an antiserum against rat liver HST, we have investigated the distribution of HST-like Immunoreactivity in the CNS of the frog Rana ridibunda. Two populations of HST-immunoreactive neurons were observed in the hypothalamus, and several bundless of positive nerves fibers were visualized in the telencephalon and diencephalon. lncubation of frog brain homogenates with [³⁵S]PAPS and [³H] pregnenolone yielded the formation of several ³H, ³⁵S-labeled compounds, including ▵⁵PS and testosterone sulfate. When [³] dehydroepiandrosterone and [³⁵S]PAPS were used as precursors, one of the ³H, ³⁵S-labeled metabolities coeluted with DHEAS. Neosynthesis of [³H]▵⁵PS and [³H]DHEAS was reduced significantly by 2,4-dichloro-6-nitrophenol, a specific inhibitor of sulfotransferases. The present study provides the first immunocytochemical mapping of HSt in the brain. Our data also demonstrate for the first time that biopsynthesis of the highly poten neuroactive steroids ▵⁵PS and DHEAS occurs in the CNS of nonmammalian vertebrates.     

Estrogen sulfotransferase of the rat liver: complementary DNA cloning and age- and sex-specific regulation of messenger RNA.

Mammalian estrogen sulfotransferase (EST; EC 2.8.2.4) sulfurylates the hydroxyl group of estrogenic steroids by transferring the sulfate from a cosubstrate adenosine 3'-phosphate-5'-phosphosulfate. Sulfurylated steroids do not bind to the estrogen receptor with high affinity and, therefore, are hormonally inactive. We have purified rat liver EST and developed monoclonal antibody to this enzyme. By immunoscreening a lambda gt-11 expression library constructed from male rat liver cDNAs, the cDNA clone corresponding to EST was identified and isolated. A recombinant expression plasmid (pCMV5) containing this cDNA insert when transfected into COS-7 cells generated both immunologically and enzymatically active EST. With the help of this cDNA probe, we have explored the regulation of the EST mRNA in the liver and the possible role of this enzyme in sex hormone action. During the lifespan of male rats, only the young adult animals show hepatic androgen responsiveness. Also, estrogenic hormones strongly antagonize androgen action in the rat liver. Northern blot analysis of liver RNA derived from male rats of different ages shows that the androgen sensitivity of young adult animals is associated with a high expression of EST mRNA. During the same period, mRNA corresponding to dehydroepiandrosterone sulfotransferase is markedly (approximately 10-fold) down-regulated. Such a correlation is in concordance with the role of these enzymes in the maintenance of hepatic androgen sensitivity during young adult life by inactivating the estrogenic and sparing the androgenic steroids. Furthermore, the increase in the hepatic androgen sensitivity of androgen-treated female rats is also associated with the induction of EST.(ABSTRACT TRUNCATED AT 250 WORDS)     

A nucleotide-gated molecular pore selects sulfotransferase substrates

Human SULT2A1 is one of two predominant sulfotransferases in liver and catalyzes transfer of the sulfuryl moiety (-SO(3)) from activated sulfate (PAPS, 3'-phosphoadenosine 5-phosphosulfate) to hundreds of acceptors (metabolites and xenobiotics). Sulfation recodes the biologic activity of acceptors by altering their receptor interactions. The molecular basis on which these enzymes select and sulfonate specific acceptors from complex mixtures of competitors in vivo is a long-standing issue in the SULT field. Raloxifene, a synthetic steroid used in the prevention of osteoporosis, and dehydroepiandrosterone (DHEA), a ubiquitous steroid precusor, are reported to be sulfated efficiently by SULT2A1 in vitro, yet unlike DHEA, raloxifene is not sulfated in vivo. This selectivity was explored in initial rate and equilibrium binding studies that demonstrate pronounced binding antisynergy (21-fold) between PAPS and raloxifene, but not DHEA. Analysis of crystal structures suggests that PAP binding restricts access to the acceptor-binding pocket by restructuring a nine-residue segment of the pocket edge that constricts the active site opening, or "pore", that sieves substrates on the basis of their geometries. In silico docking predicts that raloxifene, which is considerably larger than DHEA, can bind only to the unliganded (open) enzyme, whereas DHEA binds both the open and closed forms. The predictions of these structures with regard to substrate binding are tested using equilibrium and pre-steady-state ligand binding studies, and the results confirm that a nucleotide-driven isomerization controls access to the acceptor-binding pocket and plays an important role in substrate selection by SULT2A1 and possibly other sulfotransferases.     

Substrate gating confers steroid specificity to estrogen sulfotransferase.

Estrogen sulfotransferase (EST) exhibits a high substrate specificity and catalytic efficiency toward estrogens such as estradiol (E2) but insignificant ability to sulfate hydroxysteroids such as dehydroepiandrosterone (DHEA). To provide the structural basis for this estrogen specificity, we mutated amino acid residues that constitute the substrate-binding site of EST. Among these mutants, only Tyr-81 decreased E2 and increased DHEA sulfotransferase activities. Substitution for Tyr-81 by smaller hydrophobic residues increased K(m(E2)) for E2 activity, whereas the k(cat(E2)) remained relatively constant. The Y81L mutant exhibited the same DHEA activity as wild-type hydroxysteroid sulfotransferase, for which K(m(DHEA)) remained relatively constant, and k(cat(DHEA)) was markedly increased. The side chain of Tyr-81 is directed at the A-ring of the E2 molecule in the substrate-binding pocket of EST, constituting a steric gate with Phe-142 sandwiching E2 from the opposite side. The present mutagenesis study indicates that the 3beta-hydroxyl group of the DHEA molecule is excluded from the catalytic site of EST through steric hindrance of Tyr-81 with the C-19 methyl group of DHEA. Thus, this stricture-like gating caused by steric hindrance appears to be a structural principle for conferring estrogen specificity to EST.     

Mutational study of heparan sulfate 2-O-sulfotransferase and chondroitin sulfate 2-O-sulfotransferase

Heparan sulfate (HS) and chondroitin sulfate (CS) are highly sulfated polysaccharides with a wide range of biological functions. Heparan sulfate 2-O-sulfotransferase (HS-2OST) transfers the sulfo group from 3'-phosphoadenosine 5'-phosphosulfate (PAPS) to the 2-OH position of the hexauronic acid that is adjacent to N-sulfated glucosamine, whereas chondroitin sulfate 2-O-sulfotransferase (CS-2OST) transfers the sulfo group to the hexauronic acid that is adjacent to N-acetylated galactosamine. Here we report a systematic mutagenesis study of HS-2OST and CS-2OST based on their structural homology to estrogen sulfotransferase and HS 3-O-sulfotransferase isoform 3 (3-OST3), for which crystal structures exist. We have identified six residues possibly involved in binding to PAPS. HS-2OST carrying mutations of these residues lacks sulfotransferase activity and the ability to bind 3'-phosphoadenosine 5'-phosphate, a PAPS analogue, as determined by isothermal titration calorimetry. Similar residues involved in binding to PAPS were also identified in CS-2OST. Additional residues that participate in carbohydrate substrate binding were also identified in both enzymes. Mutations at these residues led to the loss of sulfotransferase activity but maintained the ability to bind to phosphoadenosine 5'-phosphate. The catalytic function of HS-2OST appears to involve two histidine residues (His140 and His142), whereas only one histidine (His168) of CS 2-OST is likely to be critical. This unique feature of HS 2-OST catalytic residues directed us to characterize the Drosophila heparan sulfate 2-O-sulfotransferase. The results from this study provide insight into the differences and similarities various residues play in the biological roles of the HS-2OST and CS-2OST enzymes.     

Testosterone sulfotransferase: evidence in the guinea pig that this reaction is carried out by 3 alpha-hydroxysteroid sulfotransferase.

During the course of isolating, characterizing, and cloning estrogen and 3-hydroxysteroid sulfotransferases from the guinea pig adrenal gland, it was noted that cytosolic preparations from this tissue would also sulfonate testosterone. Therefore, we set out to isolate and clone the enzyme that performs this reaction. Testosterone sulfotransferase (TST) was isolated from the guinea pig adrenal by using the standard procedures of ion exchange, affinity, and high-performance liquid chromatography. When purified, TST was examined by liquid-phase nondenaturing isoelectric focusing, it was found that the TST activity profile completely overlapped with the activity profile of the 3alpha-hydroxysteroid sulfotransferase (3alphaHST) isoform, but not the 3beta-hydroxysteroid sulfotransferase (3betaHST) isoform. This finding was further investigated by overexpressing the cDNAs for 3alphaHST and 3betaHST in Escherichia coli and examining the expressed proteins for TST activity. This experiment confirmed that 3alphaHST does indeed function as a TST. In addition, 3alphaHST was also found to sulfonate estradiol but not estrone, a finding that further suggested that 3alphaHST may function as a general 17beta-hydroxysteroid sulfotransferase.     

Substrate inhibition in human hydroxysteroid sulfotransferase SULT2A1: studies on the formation of catalytically non-productive enzyme complexes

The cytosolic sulfotransferase hSULT2A1 is the major hydroxysteroid (alcohol) sulfotransferase in human liver, and it catalyzes the 3′-phosphoadenosine-5′-phosphosulfate (PAPS)-dependent sulfation of various endogenous hydroxysteroids as well as many xenobiotics that contain alcohol and phenol functional groups. The hSULT2A1 often displays substrate inhibition, and we have hypothesized that a key element in this response to increasing substrate concentration is the formation of non-productive ternary dead-end enzyme complexes involving the nucleotide product, adenosine 3′,5′-diphosphate (PAP). One of these substrates for hSULT2A1 is dehydroepiandrosterone (DHEA), a major circulating steroid hormone in humans that serves as precursor to both androgens and estrogens. We have utilized DHEA in both initial velocity studies and equilibrium binding experiments in order to evaluate the potential role of ternary complexes in substrate inhibition of the enzyme. Our results indicate that hSULT2A1 forms non-productive ternary complexes that involve either DHEA or dehydroepiandrosterone sulfate, and the formation of these ternary complexes displays negative cooperativity in the binding of DHEA.     

Metabolism of pregnenolone by human breast cancer. Evidence for 17 alpha-hydroxylase and 17,20-lyase.

The metabolism of 7-(3)H-pregnenolone was studied in vitro using 16 human breast carcinomas. All mammary tumors transformed pregnenolone to progesterone. All estrogen receptor poor tumors and 4 out of 8 estrogen receptor rich tumors converted pregnenolone to 17-hydroxypregnenolone. Five estrogen receptor poor tumors showed the presence of 17,20-lyase as evidenced by formation of dehydroepiandrosterone and androstenedione. In two estrogen receptor poor tumors, conversions of pregnenolone to progesterone, 17-hydroxy pregnenolone, dehydroepiandrosterone, androstenedione and finally to estradiol was documented, providing a hypothetical pathway for steroid metabolism in human breast cancer. The conversion of pregnenolone to 17-hydroxypregnenolone was significantly less in receptor rich tumors and was totally absent in 4 receptor rich tumors with estrogen receptors of over 45 fmol/mg protein.     

The dimerization motif of cytosolic sulfotransferases

Cytosolic sulfotransferases sulfate steroids such as estrogens and hydroxysteroids. The enzymes, including human estrogen sulfotransferase (hEST) and hydroxysteroid sulfotransferase (hHST), are generally homodimers in solution with mouse estrogen sulfotransferase (mEST) being one of few exceptions. To identify the amino acid residues responsible for the dimerization, eight residues on the surface of hEST were mutated to their counterparts in mEST and mutated hESTs were then analyzed by gel filtration chromatography. A single mutation of Val(269) to Glu was sufficient to convert hEST to a monomer and the corresponding mutation of Val(260) also altered hHST to a monomer. The hHST crystal structure revealed a short stretch of peptide with the side-chains from two hHST monomers forming a hydrophobic zipper-like structure enforced by ion pairs at both ends. This peptide consisted of 10 residues near the C-terminus that, including the critical Val residue, is conserved as KXXXTVXXXE in nearly all cytosolic sulfotransferases. When mEST underwent the double mutations Pro269Thr/Glu270Val dimerization resulted. Thus, the KXXXTVXXXE sequence appears to be the common protein-protein interaction motif that mediates the homo- as well as heterodimerization of cytosolic sulfotransferases.     

Inhibition and binding studies of coenzyme A and bovine phenol sulfotransferase.

Phenol sulfotransferases (PSTs, EC 2.8.2.1) catalyze sulfonyl group transfer from 3'-phosphoadenosine-5'-phosphosulfate (PAPS) to the hydroxyl oxygen of aromatic acceptor substrates. The structural overlap between PAPS and coenzyme A (CoA) suggested a possible role of this common acyl carrier in modulating PST activity. To test this hypothesis, purified recombinant bovine PST was examined by kinetic and affinity chromatographic approaches. After demonstrating PST enzyme inhibition by CoA, systematic variation of CoA and PAPS concentrations indicated simple competitive inhibition with K(i) = 1. 3 microM. PST bound to CoA-agarose, attached via the pantetheinyl thiol group, was eluted with PAP but not by 2-naphthol. This observation was consistent with the pattern of inhibition. Additional members of the sulfotransferase superfamily, as well as acylated CoAs, should be further investigated.     

Sulfation of iodothyronines by recombinant human liver steroid sulfotransferases.

Sulfation is an important pathway in the metabolism of thyroid hormones. Sulfated iodothyronines are elevated in nonthyroidal illnesses and in the normal human fetal circulation. We assayed and characterized COS-1 cell expressed recombinant human liver dehydroepiandrosterone sulfotransferase (DHEA ST or SULT2A1) and estrogen sulfotransferase (EST or SULT1E1) activities for the first time with triiodothyronine (T(3)) as the substrate. Several biochemical properties that included apparent K(m) values, thermal stabilities, and responses to the inhibitors 2, 6-dichloro-4-nitrophenol and NaCl were tested. SULT2A1, a member of the hydroxysteroid sulfotransferase family, used 3,3'-T(2) more readily than T(3) and 3,5-T(2) as substrates, but had the lowest apparent K(m) value for T(3) of any reported human SULT. SULT1E1, a member of the phenol sulfotransferase family, used 3,3'-T(2) and rT(3) more readily than T(3), and also displayed the greatest specificity for T(4) among human SULTs. SULT2A1 may contribute more to iodothyronine sulfation than previously suspected. Potential roles of both steroid sulfotransferases in the enhanced sulfation of nonthyroidal illnesses and fetal development invite further investigation.     

Antioxidant properties of diorganoyl diselenides and ditellurides: modulation by organic aryl or naphthyl moiety

Sulfotransferases catalyze the sulfate conjugation of a wide variety of endogenous and exogenous molecules. Human pathogenic mycobacteria produce numerous sulfated molecules including sulfolipids which are well related to the virulence of several strains. The genome of Mycobacterium avium encodes eight putative sulfotransferases (stf1, stf4-stf10). Among them, STF9 shows higher similarity to human heparan sulfate 3-O-sulfotransferase isoforms than to the bacterial STs. Here, we determined the crystal structure of sulfotransferase STF9 in complex with a sulfate ion and palmitic acid at a resolution of 2.6 ?. STF9 has a spherical structure utilizing the classical sulfotransferase fold. STF9 exclusively possesses three N-terminal α-helices (α1, α2, α3) parallel to the 3'-phosphoadenosine-5'-phosphosulfate (PAPS) binding motif. The sulfate ion binds to the PAPS binding structural motif and the palmitic acid molecule binds in the deep cleft of the predicted substrate binding site suggesting the nature of endogenous acceptor substrate of STF9 resembles palmitic acid. The substrate binding site is covered by a flexible loop which may have involvement in endogenous substrate recognition. Based on the mutational study (Hossain et al., Mol Cell Biochem 350:155-162; 2011) and structural resemblance of STF9-sulfate ion-palmitic acid complex to the hHS3OST3 complex with PAP (3'-phosphoadenosine-5'-phosphate) and an acceptor sugar chain, Glu170 and Arg96 are appeared to be catalytic residues in STF9 sulfuryl transfer mechanism.     

The structures of the unique sulfotransferase retinol dehydratase with product and inhibitors provide insight into enzyme mechanism and inhibition

The structure of retinol dehydratase (DHR) from Spodoptera frugiperda, a member of the sulfotransferase superfamily, in complexes with the inactive form of the cofactor PAP 3'-phosphoadenosine 5'-phosphate (PAP) and (1) the product of the reaction with retinol anhydroretinol (AR), (2) the retinoid inhibitor all-trans-4-oxoretinol (OR), and (3) the potent steroid inhibitor androsterone (AND) have been determined and compared to the enzyme complex with PAP and retinol. The structures show that the geometry of the active-site amino acids is largely preserved in the various complexes. However, the beta-ionone rings of the retinoids are oriented differently with respect to side chains that have been shown to be important for the enzymatic reaction. In addition, the DHR:PAP:AND complex reveals a novel mode for steroid binding that contrasts significantly with that for steroid binding in other sulfotransferases. The molecule is displaced and rotated approximately 180 degrees along its length so that there is no acceptor hydroxyl in close proximity to the site of sulfate transfer. This observation explains why steroids are potent inhibitors of retinol dehydratase activity, rather than substrates for sulfonation. Most of the steroid-protein contacts are provided by the alpha-helical cap that distinguishes this member of the superfamily. This observation suggests that in addition to providing a chemical environment that promotes the dehydration of a sulfonated intermediate, the cap may also serve to minimize a promiscuous sulfotransferases activity.     

Unconjugated and sulfoconjugated steroids in plasma and zones of the adrenal cortex of the guinea pig

The following steroids were measured in their unconjugated and sulfoconjugated forms in plasma and in the outer and inner zones of the adrenal cortex of the guinea pig: pregnenolone, 17-hydroxypregnenolone, 21-hydroxypregnenolone, dehydroepiandrosterone and deoxycorticosterone. In plasma, pregnenolone and 21-hydroxypregnenolone were the predominant unconjugated steroids with concentrations 10-30 times higher than the other three steroids. Among the sulfoconjugated steroids, pregnenolone sulfate had a concentration 25-50 times higher than the other sulfoconjugates. For each steroid except 21-hydroxypregnenolone the sulfoconjugated form was present in a concentration 2-7 times higher than the unconjugated form. In the adrenal cortex, the content of 21-hydroxypregnenolone was significantly higher in the outer zone than in the inner zone and was present in amounts 3-100 times greater than the other unconjugated steroids in the outer zone. On the other hand, the content of pregnenolone was significantly greater in the inner zone than the outer zone, and was present in amounts 3-80 times greater than the other unconjugated steroids in the inner zone. With the exception of 21-hydroxypregnenolone and deoxycorticosterone, the steroid sulfoconjugates were significantly higher in the inner cortical zone. As in plasma, pregnenolone sulfate was the most abundant sulfoconjugated steroid. This report also describes preliminary studies concerning sulfurylated hydroxyl groups in different positions of 21-hydroxypregnenolone. The sulfoconjugate was prepared by using partially purified steroid sulfotransferase from the guinea pig adrenal. The results obtained indicated that of the total 21-hydroxypregnenolone conjugate formed, approximately 40% was the 21-sulfate and 20% the 3-sulfate, whereas 40% was non-hydrolyzable with the techniques used and was not further characterized.