131 I-induced changes in rat thyroid gland function.

Therapeutic doses of (131)I administered to thyrotoxic patients may cause thyroid failure. The present study used a rat model to determine thyroid function after the administration of different doses of (131)I (64-277 microCi). Thirty male Fisher rats in the experimental group and 30 in the control group (untreated) were followed for 6 months. The animals were 4 months old at the beginning of the experiment and were sacrificed at an age of 9 months. Hormone concentration was determined before (131)I administration (4-month-old animals) and three times following (131)I administration, when the animals were 7, 8, and 9 months old. The thyroid glands were removed and weighed, their volume was determined and histopathological examination was performed at the end of the experiment. Significant differences in serum triiodothyronine and thyroid-stimulating hormone concentration, measured at the age of 7, 8, and 9 months, were found in the experimental group. During aging of the animals, the concentration of thyroxin fell from 64.8 +/- 8.16 to 55.0 +/- 6.1 nM in the control group and from 69.4 +/- 6.9 to 25.4 +/- 3.2 nM in the experimental group. Thyroid gland volume and weight were significantly lower in the experimental than in the control group. Thyroid glands from the experimental group showed hyaline thickness of the blood vessel wall, necrotic follicles, a strong inflammatory reaction, and peeling of necrotic cells in the follicles. In conclusion, significant differences in hormone levels and histopathological findings indicated prolonged hypothyroidism after (131)I administration to rats, which was not (131)I dose dependent.

131I-induced changes in rat thyroid gland function

Therapeutic doses of 131I administered to thyrotoxic patients may cause thyroid failure. The present study used a rat model to determine thyroid function after the administration of different doses of 131I (64-277 µCi). Thirty male Fisher rats in the experimental group and 30 in the control group (untreated) were followed for 6 months. The animals were 4 months old at the beginning of the experiment and were sacrificed at an age of 9 months. Hormone concentration was determined before 131I administration (4-month-old animals) and three times following 131I administration, when the animals were 7, 8, and 9 months old. The thyroid glands were removed and weighed, their volume was determined and histopathological examination was performed at the end of the experiment. Significant differences in serum triiodothyronine and thyroid-stimulating hormone concentration, measured at the age of 7, 8, and 9 months, were found in the experimental group. During aging of the animals, the concentration of thyroxin fell from 64.8 ± 8.16 to 55.0 ± 6.1 nM in the control group and from 69.4 ± 6.9 to 25.4 ± 3.2 nM in the experimental group. Thyroid gland volume and weight were significantly lower in the experimental than in the control group. Thyroid glands from the experimental group showed hyaline thickness of the blood vessel wall, necrotic follicles, a strong inflammatory reaction, and peeling of necrotic cells in the follicles. In conclusion, significant differences in hormone levels and histopathological findings indicated prolonged hypothyroidism after 131I administration to rats, which was not 131I dose dependent.

Effect of a T81A mutation at the subunit interface on catalytic properties of alkaline phosphatase from Escherichia coli.

Although alkaline phosphatase (APase) from Escherichia coli crystallizes as a symmetric dimer, it displays deviations from Michaelis-Menten kinetics supported by a model describing a dimeric enzyme with conformationally and kinetically non-equivalent subunits. The proposed model, explaining the mechanism of substrate hydrolysis, encompasses a conformational change mediated by subunit interactions [S. Orhanovic, M. Pavela-Vrancic, Eur. J. Biochem. 270 (2003) 4356-4364]. The significance of interactions at the subunit interface and the involvement of the beta-pleated sheet stretching from underneath the active site to the subunit surface, in the catalytic mechanism, has been probed by site-directed mutagenesis. The mutant APase, carrying alanine in place of Thr81, was analyzed in comparison to the wild-type protein. The T81A mutation, introduced at the subunit interface, significantly affected the protein kinetic properties, emphasizing the importance of subunit interactions in the catalytic process.

Relationship between activating and editing functions of the adenylation domain of apo-tyrocidin synthetase 1 (apo-TY1).

Tyrocidine synthetase 1 (TY1), the initial monomodular constituent of the tyrocidine biosynthetic system, exhibits relaxed substrate specificity, however an efficient editing of the mis-activated amino acid provides for fidelity of product formation. We chose to analyse the consequence of single amino acid substitutions, in the amino acid activation site of apo-TY1, on the editing functions of the enzyme. Discrimination between L-Phe and D-Phe by apo-TY1 depends primarily on the editing reaction. Distraction of unnatural amino acid substrates, such as L-PheSer, implies that editing is not designated to select a specific mis-activated amino acid, but instead to discriminate all mis-activated amino acid analogues. It was shown that active site residues which interact with the adenylate are essential for both activation and editing. Substitution of Lys186 with arginine substantially reduces the editing capacity of the protein. Loss of amino acid discrimination ability by the apo-K186T and apo-R416T mutant proteins suggests a role of active site residues in maintaining the structural determinants for substrate selection. Inadequate conformational changes, induced by non-cognate amino acid substrates, promote ATP breakdown yielding P(i) and ADP. Replacement of residue Lys186 or Arg416 enhances ATP hydrolysis implying a role in binding or adjusting of the triphosphate chain for adenylate formation and pyrophosphate cleavage.

Metal-ion induced conformational changes in alkaline phosphatase from E. coli assessed by limited proteolysis.

Alkaline phosphatase (AP) displays significant structural changes during metal-ion binding, supporting cooperative interactions between the subunits of the dimeric enzyme. Here, we present data on the dynamic properties of AP from E. coli, and characterize the structural changes that accompany variations in metal-ion content, combining limited proteolysis and MALDI-TOF mass spectrometry. Limited proteolysis revealed an internal cleavage site at Arg-293, reflecting a position of conformational flexibility supporting subunit communication essential for catalysis. A specific shielding of a region distant from the metal-binding site has been demonstrated, implying transmission of conformational changes, induced by metal-ion binding to the adjacent subunit, across the subunit interface.

Inhibition of alkaline phosphatase activity by okadaic acid, a protein phosphatase inhibitor.

This paper reports on a potential physiological target of okadaic acid (OA), the toxin metabolite responsible for shellfish poisoning and, consequently, human intoxication. OA is a potent promoter of tumor activity, most likely by inhibiting protein phosphatase 1 and 2A (Adv. Cancer. Res. 61 (1993) 143). However, all of its cellular targets have not yet been characterized. The interaction of OA with alkaline phosphatase (ALP) has been investigated in view of its protein phosphatase inhibition activity. Kinetic analysis of ALP from Escherichia coli, human placental and calf intestinal ALP has shown that OA acts as a non-competitive inhibitor of ALP. The bacterial enzyme displays a higher affinity for OA (K(i) 360 nM) than the eukaryotic proteins (human placental ALP, K(i) 2.05 microM; calf intestinal ALP, K(i) 3.15 microM). The inhibition by OA suggests a putative role of ALP in the phosphorylation status, through regulation of the phosphorylation/dephosphorylation equilibrium of proteins with phosphoseryl or phosphothreonyl residues.

DSP toxin profile in the coastal waters of the central Adriatic Sea.

A monitoring program, carried out in 1996 and 1997, has confirmed that toxic compounds, other than the most frequently detected toxins okadaic acid (OA) and dinophysistoxin-1 (DTX-1), are involved in DSP phenomena in the Adriatic Sea. Toxicity was assessed by the mouse bioassay; the content and the nature of the toxic components were established through fluorometric HPLC analysis combined with mass spectrometry. A rare pectenotoxin-2 (PTX-2) derivative, 7-epi-pectenotoxin-2 seco acid (7-epi-PTX-2SA), was the exclusive contaminant of samples collected from the central Adriatic in 1996. Contrary to its marked oral toxicity, intraperitoneally 7-epi-PTX-2SA displayed no toxic effects, hampering its detection by the mouse bioassay. In 1997, its concentration and frequency of appearance were lower than in 1996, with concomitant occurrence of OA, DTX-2, and a new unidentified component related to the DSP toxic group of compounds. This is the first report on the occurrence of DTX-2 in Adriatic mussels. A survey of the phytoplankton community in the surrounding seawater has established the presence of Prorocentrum micans and several potentially toxic species from the Dinophysis genus. A case of unexplained toxicity, associated with the occurrence of Gonyaulax polyedra, suggested possible shellfish contamination with yessotoxin (YTX).

Dipeptide synthesis by an isolated adenylate-forming domain of non-ribosomal peptide synthetases (NRPS).

A deletion mutant of tyrocidine synthetase 1 (DeltaDeltaTY1), comprising the adenylation domain of TY1 as an independent functional adenylate-forming unit, was used to investigate the ability of the adenylation domain in non-ribosomal peptide synthetases to catalyse peptide bond formation from the aminoacyl adenylate intermediate. The results demonstrate that only one substrate amino acid needs to be activated as an aminoacyl adenylate. In view of the potential exploitation of peptide synthetases for enzymatic synthesis of dipeptides of choice, it is important to note that this does not necessarily require a dimodular construct or an intermediate acyl transfer step.

Synthesis of (di)adenosine polyphosphates by non-ribosomal peptide synthetases (NRPS).

In response to nutritional stress conditions, Bacillus brevis produces the cyclodecapeptide antibiotic tyrocidine via tyrocidine synthetase, a multifunctional non-ribosomal peptide synthetase. The apo-form of tyrocidine synthetase 1 forms adenosine (5')tetraphospho(5')adenosine, when incubated with MgATP(2-), amino acid and inorganic pyrophosphatase. The synthesis is an intrinsic property of the adenylation domain, is strictly dependent upon the amino acid, and proceeds from a reverse reaction of adenylate formation involving a second ATP molecule. In the presence of tri- or tetrapolyphosphate preferential synthesis of adenosine 5'-tetraphosphate and adenosine 5'-pentaphosphate occurs, respectively. A potential involvement of adenosine (5')-n-phospho(5')adenosine in the regulation of the biosynthetic process has been suggested.

The occurrence of 7-epi-pectenotoxin-2 seco acid in the coastal waters of the central Adriatic (Kastela Bay).

Okadaic acid (OA) and 7-epi-pectenotoxin-2 seco acid (7-epi-PTX-2SA) were identified as the toxic determinants in mussels from the central Adriatic Sea. The nature of the pectenotoxin-2 derivative was confirmed by chromatographic comparison with toxins present in algae extracts of Dinophysis acuta from Ireland, and by mass spectrometric analysis. The origin of shellfish toxicity has been associated with the occurrence of the Dinophysis species. This is the first report on the incidence of 7-epi-PTX-2SA in the Adriatic region.

Active site titration of gramicidin S synthetase 2: evidence for misactivation and editing in non-ribosomal peptide biosynthesis.

The catalytic competence of gramicidin S synthetase 2 (GS2) was determined by following the kinetics of PP(i) generation using active site titration measurements with [gamma-(32)P]ATP. The initial 'burst' of product formation can be correlated to the generation of the aminoacyl adenylate:enzyme complexes at the four amino acid activation domains and the subsequent aminoacylation of carrier domains, followed by a slow linear turnover of substrate due to breakdown of the intermediate. Simultaneous activation of all four amino acid substrates at a saturating concentration displayed a consumption of 8.3 ATP/GS2. In the presence of single amino acids, a binding stoichiometry higher than the anticipated two ATP per active site was obtained, implying misactivation at non-cognate domains. Breakdown of acyladenylate intermediates reflects a possible corrective mechanism by which the enzyme controls the fidelity of product formation.

The nonribosomal code.

How genes are expressed and translated into proteins (using mRNA, codons and tRNAs as adaptor molecules) forms the basis of the 'genetic code'. Many peptides are synthesized nonribosomally, however, by large protein complexes that also serve as templates. Recent advances have shed light on what the nonribosomal code is and how it can be read.

Editing of non-cognate aminoacyl adenylates by peptide synthetases.

Non-ribosomally formed peptides display both highly conserved and variable amino acid positions, the variations leading to a wide range of peptide families. Activation of the amino acid substrate proceeds in analogy to the ribosomal biosynthetic mechanism generating aminoacyl adenylate and acyl intermediates. To approach the mechanism of fidelity of amino acid selection, the stability of the aminoacyl adenylates was studied by employing a continuous coupled spectrophotometric assay. The apo-form of tyrocidine synthetase 1 (apo-TY1) was used, generating an l-phenylalanyl-adenylate intermediate stabilized by the interaction of two structural subdomains of the adenylation domain. Adenylates of substrate analogues have shown variable and reduced degrees of stability, thus leading to an enhanced generation of pyrophosphate due to hydrolysis and continuous adenylate formation. Discrimination of the non-aromatic amino acids l-Leu and l-Met, or l-Phe analogues such as p-amino- and p-chloro-l-Phe derivatives, as well as the stereospecific selection of l-Phe, is supported by less-stable adenylate intermediates exhibiting elevated susceptibility to hydrolysis. Breakdown of the l-phenylalanyl intermediate utilizing 2'-deoxy-ATP as the nucleotide substrate was significantly enhanced compared with the natural analogue. Apo-TY1 engineered at positions involved in adenylate formation showed variable protection against hydrolysis. The results imply that stability of the aminoacyl intermediates may act as an essential factor in substrate selection and fidelity of non-ribosomal-peptide-forming systems.

Probing the domain structure and ligand-induced conformational changes by limited proteolysis of tyrocidine synthetase 1.

The boundaries of the structural domains in peptide synthetases and the conformational changes related to catalysis were investigated by limited proteolysis of tyrocidine synthetase 1 (TY1). Four regions sensitive to proteolysis were detected (cleavage site at Arg13, Arg424, Arg509 and Arg602) that, in addition to an N-terminal extension, accurately delineate the domain boundaries of the adenylate-forming domain, the aminoacyl carrier domain, and the epimerisation domain. Limited proteolysis of an active N-terminal truncated deletion mutant, His6DeltaTY1, generated two stable and structurally independent subunits, corresponding to the subdomains of the adenylation domain. The structural integrity of the carrier domain was substantiated by its resistance to proteolytic degradation. Evidence is provided that the C-terminal "spacer" region with epimerising and/or condensing activity folds into an autonomous domain stable against degradation by limited proteoly sis. In the presence of substrates, reduced susceptibility to proteolysis was observed in the linker region connecting the subdomains of the adenylation domain, and corresponding to a peptide stretch of low electron density in the X-ray structure of the homologous firefly luciferase. Sequence analysis has shown that the respective linker contains conserved residues, whereas the linker regions connecting the structural domains are of low homology with a significant content of Pro, Ala, Glu and polar residues. A combination of kinetic and proteolytic studies using ATP analogues with substitutions in the phosphate chain, AMP-PcP, AMP-PNP and AMP-cPP, strongly suggests that the generation of a productive complex is associated with the ability of the beta, gamma-pyrophosphate moiety of ATP to adopt the proper active-site conformation. These data substantiate the observation that peptide synthetases undergo a series of conformational changes in the process of adenylate formation and product release.

The adenylation domain of tyrocidine synthetase 1--structural and functional role of the interdomain linker region and the (S/T)GT(T/S)GXPKG core sequence.

Sequence analysis of peptide synthetases revealed extensive structure similarity with firefly luciferase, whose crystal structure has recently become available, providing evidence for the localization of the active site at the interface between two subdomains separated by a distorted linker region [Conti, E., Franks, N. P. & Brick, P. (1996) Structure 4, 287-298]. The functional importance of two flexible loops, corresponding to the linker region of firefly luciferase and the highly conserved (S/T)GT(T/S)GXPKG core sequence, has been studied in view of the proposed conformational changes by the use of mutant analysis, limited proteolysis and chemical modification of tyrocidine synthetase 1. Substitution of the highly conserved Arg416, residing in the loop separating the subdomains of the adenylation domain, resulted in profound loss of activity. Limited proteolysis of the mutant suggested significant structural changes as manifested by lack of protection to degradation in the presence of substrates, revealing a probable disturbance of the induced-fit mechanism regulating the transformation from an open to a closed conformation. Mutants, obtained by replacement of the conserved Lys186 from the (S/T)GT(T/S)GXPKG core sequence, displayed only minor differences in substrate-binding affinity despite significant reduction of catalytic efficiency. Residue Lys186 appears to play an important role in either stabilization of the bound substrate through charge-charge-interactions, and/or fixing of the loop for maintainance of the active-site conformation.

Characterization of tyrocidine synthetase 1 (TY1): requirement of posttranslational modification for peptide biosynthesis.

Tyrocidine synthetase 1 (TY1), produced by Bacillus brevis ATCC 8185, consists of a single multifunctional polypeptide chain catalyzing the activation, thioesterification, and epimerization of phenylalanine. Because we were concerned about possible posttranslational issues, a comparative study between the wild-type isolate and the in Escherichia coli overexpressed protein was performed. Analysis by matrix assisted laser desorption mass spectrometry (MALDI) provided a molecular mass of 122,516 +/- 120 Da for the recombinant protein, which is in agreement with the value of 122,590 Da calculated from the gene sequence. MALDI analysis of the tryptic fragments revealed that in the recombinant TY1 the putative 4'-phosphopantetheine binding site (562Ser) is not modified by the cofactor. The substrate specificity profiles of the amino acid dependent ATP[32P]PPi exchange reactions were identical, including activation of L-phenylserine, L-tyrosine, and L-methionine. However, the rates of the reverse adenylation reaction for the recombinant protein were only 22% relative to those of the wild-type enzyme. The aminoacylation levels of about 60% for TY1 from Bacillus brevis reduced to 1.4% in the overexpressed protein. A similar distribution of the D- and the L-isomer was detected at the thioester attachment site. The pI values of the wild-type and expressed TY1 are 4.9 and 5.0, respectively. In conclusion, it could be established that apo- and holo-TY1 differ in their amino acid activating properties. Posttranslational modification by 4'-phosphopantetheine is an essential requirement for aminoacylation, epimerization, and thus the functioning of the multienzyme in peptide synthesis.

ATP binding in peptide synthetases: determination of contact sites of the adenine moiety by photoaffinity labeling of tyrocidine synthetase 1 with 2-azidoadenosine triphosphate.

Characterization of the nucleotide binding domain in peptide synthetases was approached by photoaffinity labeling of tyrocidine synthetase 1 (TY1) with 2-azidoadenosine triphosphate (2-azido-ATP). Exposure of TY1 in the presence of photolabel to irradiation with ultraviolet light resulted in a time-dependent covalent modification of the enzyme with a concomitant loss of catalytic activity. Inactivation was not observed if incubation was performed in the absence of either light or the nucleotide analogue. Specificity of labeling was indicated by the ability of 2-azido-ATP to serve as a substrate in the amino acid activation reaction. The modified protein was subjected to tryptic digestion, and the fragments labeled by the nucleotide analogue were purified by reverse-phase high-performance liquid chromatography. Sequence analysis identified three tryptic peptides corresponding to residues G373-K384, W405-R416, and L483-K494, derived from the N-terminal half of the TY1 sequence. As this region shows similarity to strongly conserved regions in other peptide synthetases and acyl-CoA synthetases, it is considered to be the region catalyzing aminoacyl adenylate formation. The identified sequences appear to define components of the nucleotide binding domain found in close proximity to the adenine ring in ATP. Conservation of primary structure and homology to other carboxyl-activating enzymes of this superfamily, including peptide synthetases, insect luciferases, and acyl-CoA synthetases, is discussed.

Identification of the ATP binding site in tyrocidine synthetase 1 by selective modification with fluorescein 5'-isothiocyanate.

Identification of the nucleotide binding site in peptide synthetases has been approached by affinity labeling of tyrocidine synthetase 1 with fluorescein 5'-isothiocyanate. Binding was accompanied by irreversible inhibition of the ATP-dependent phenylalanine activation reaction and was prevented in the presence of MgATP2-. The reaction obeyed pseudo first-order rate kinetics and was accelerated by Mg2+. Complete inhibition corresponded to incorporation of 2.3 mol of fluorescein 5'-isothiocyanate (FITC)/mol of protein. Upon protection by MgATP2-, about 1 mol of FITC is still incorporated; however, this does not affect activity. The modified synthetase was extensively fragmented by tryptic digestion and the labeled fragments isolated by reverse-phase high performance liquid chromatography. Two peptides, DHQVKIR and LDKMPLTPNDKIDR, have been identified by sequencing, and the FITC conjugate of the former peptide has been detected by laser desorption mass spectrometry. The labeled residues, Lys-422 and Lys-505, are located within highly conserved segments of this new class of synthetases.

Nucleotide binding by multienzyme peptide synthetases.

Peptide synthetases consist of linearly arranged catalytic units, which by sequence alignment show equally spaced amino-acid-activating segments/modules of 600-700 amino acid residues. The consensus sequence comprises a new class of sequence motifs which are shared by some carboxyl-activating enzymes, but which do not occur in aminoacyl-tRNA synthetases. The catalytic properties of peptide synthetases with respect to the nucleotide substrate were investigated by enzyme kinetic studies. In the activation reaction ATP may be substituted by 2'-deoxy-ATP (dATP) and 7-deazaadenosine 5'-triphosphate, substrate analogues which are not recognised by many aminoacyl-tRNA synthetases, and may thus prove useful alternative substrates in the detection of peptide synthetases within complex protein mixtures. ATP derivatives substituted at C2 are substrates, while those substituted at C8 are not, indicating a preference for the anti-conformation in substrate binding. Kinetic studies revealed that coenzyme A is a non-competitive inhibitor of the activation reaction, suggesting the presence of a second nucleotide binding site which accommodates nucleotides with phosphate in the C2' or C3' position. This substrate and inhibition profile is markedly different from that of aminoacyl-tRNA synthetases and indicative of a separate homogeneous family of carboxyl-activating enzymes.