The effect of 5-substitution in the pyrimidine ring of dUMP on the interaction with thymidylate synthase: molecular modeling and QSAR

Thymidylate synthase (TS) is a target enzyme for a number of anticancer agents including the 5-fluorouracil metabolite, FdUMP. The present paper reports on molecular modeling studies of the effect of substitution at C(5) position in the pyrimidine ring of the TS substrate, dUMP, on the binding affinity for the enzyme. The results of molecular dynamics simulations show that the binding of C(5) analogues of dUMP to TS in the binary complexes does not undergo changes, unless a substituent with a large steric effect, such as the propyl group, is involved. On the other hand, apparent differences in the binding of the TS cofactor, resulting from varying substitution at dUMP C(5), are observed in the modeled structures of the ternary complexes of TS. These binding characteristics are supplemented with a classical QSAR model quantifying the relation between the affinity for TS and the substituent electronic and steric effects of C(5) analogues of dUMP. Based on the findings from the present work, the perspectives for finding promising new C(5) analogues of dUMP as potential agents targeted against TS are discussed.     

Substrate binding properties of converting enzyme using a series of p-nitrophenylalanyl derivatives of angiotensin I.

The binding properties of angiotensin I for the active site of rabbit lung converting enzyme (CE) have been investigated. A series of angiotensin I like substrates, all containing the C-terminal tripeptide, (NO2)Phe-His-Leu, were synthesized by increasing the length of the peptide at the N-terminal end. A total of eight peptides were studied, the largest being [Asn1, (NO2)Phe8]angiotensin I. As determined by thin-layer chromatography, all substrates were hydrolyzed only at the (NO2)Phe-His bond by purified converting enzyme, with the release of the dipeptide, His-Leu. By using an absorbance increase upon hydrolysis, the Michaelis constants and velocity maxima were determined and used to estimate those amino acids in the angiotensin I molecule that contribute significantly to binding to converting enzyme. It was hypothesized that, upon addition or substitution of one or more amino acids to the N-terminal end, a proportional decrease in both KM and Vm is needed in order to conclude that the substrate actually increases its affinity for the enzyme. A test of the proportionality for the variation of KM and Vm was found to be positive for all the substrates, except the N-terminal carbobenzoxy-blocked tripeptide, Z(NO2)Phe-His-Leu. Substitutions near the bond that is hydrolyzed (e.g., proline for the carbobenzoxy group) appear to alter the catalytic properties of CE, while additions far removed from the site of hydrolysis (e.g., the N-terminal tripeptide Asn-Arg-Val) may enhance binding affinity.     

Structure of human thymidylate synthase suggests advantages of chemotherapy with noncompetitive inhibitors

Thymidylate synthase (TS) is a major target in the chemotherapy of colorectal cancer and some other neoplasms. The emergence of resistance to the treatment is often related to the increased levels of TS in cancer cells, which have been linked to the elimination of TS binding to its own mRNA upon drug binding, a feedback regulatory mechanism, and/or to the increased stability to intracellular degradation of TS.drug complexes (versus unliganded TS). The active site loop of human TS (hTS) has a unique conformation resulted from a rotation by 180 degrees relative to its orientation in bacterial TSs. In this conformation, the enzyme must be inactive, because the catalytic cysteine is no longer positioned in the ligand-binding pocket. The ordered solvent structure obtained from high resolution crystallographic data (2.0 A) suggests that the inactive loop conformation promotes mRNA binding and intracellular degradation of the enzyme. This hypothesis is supported by fluorescence studies, which indicate that in solution both active and inactive forms of hTS are present. The binding of phosphate ion shifts the equilibrium toward the inactive conformation; subsequent dUMP binding reverses the equilibrium toward the active form. Thus, TS inhibition via stabilization of the inactive conformation should lead to less resistance than is observed with presently used drugs, which are analogs of its substrates, dUMP and CH(2)H(4)folate, and bind in the active site, promoting the active conformation. The presence of an extension at the N terminus of native hTS has no significant effect on kinetic properties or crystal structure.     

How do biomolecular systems speed up and regulate rates?

The viability of a biological system depends upon careful regulation of the rates of various processes. These rates have limits imposed by intrinsic chemical or physical steps (e.g., diffusion). These limits can be expanded by interactions and dynamics of the biomolecules. For example, (a) a chemical reaction is catalyzed when its transition state is preferentially bound to an enzyme; (b) the folding of a protein molecule is speeded up by specific interactions within the transition-state ensemble and may be assisted by molecular chaperones; (c) the rate of specific binding of a protein molecule to a cellular target can be enhanced by mechanisms such as long-range electrostatic interactions, nonspecific binding and folding upon binding; (d) directional movement of motor proteins is generated by capturing favorable Brownian motion through intermolecular binding energy; and (e) conduction and selectivity of ions through membrane channels are controlled by interactions and the dynamics of channel proteins. Simple physical models are presented here to illustrate these processes and provide a unifying framework for understanding speed attainment and regulation in biomolecular systems.     

Differences in natural ligand and fluoropyrimidine binding to human thymidylate synthase identified by transient-state spectroscopic and continuous variation methods

Thymidylate synthase (TS) is a central target for the design of chemotherapeutic agents due to its vital role in DNA synthesis. Structural studies of binary complexes between Escherichia coli TS and various nucleotides suggest the chemotherapeutic agent FdUMP and the natural ligand dUMP bind similarly. We show, however, that FdUMP binding to human TS yields a substantially greater decrease in fluorescence than does dUMP. Because the difference in quenching due to ligand binding was approximately two-fold and this difference was not seen when using ecTS, the intriguing result indicated a significant difference in the mode of FdUMP binding to the human enzyme. We compared the binding affinities of dUMP, FdUMP, and TMP to TS from both species and found no significant differences for the individual ligands. Because binding affinities were not different among the ligands, the method of continuous variation was employed to determine binding stoichiometry. Similar to that found for dUMP binding to human and ecTS, FdUMP displayed single site occupancy with both enzymes. These results show that nucleotide binding differences exist for FdUMP and dUMP binding to the human enzyme. The observed differences are not due to differences in stoichiometry or ligand affinity. Therefore, although the crystal structure of human TS with various nucleotide ligands has not been solved, these results show that the differences observed using fluorescence methods result from as yet unidentified differential interactions between the human enzyme and nucleotide ligands.     

Rat brain hexokinase: location of the allosteric regulatory site in a structural domain at the N-terminus of the enzyme

After denaturation in 0.6 M guanidine hydrochloride, rat brain hexokinase becomes highly susceptible to proteolysis by trypsin. Glucose 6-phosphate (Glc-6-P) and its analog, 1,5-anhydroglucitol 6-phosphate, selectively protect the N-terminal half of the molecule from proteolysis. These compounds do not protect the C-terminal half of the molecule, nor do they protect enzyme activity; the Glc analog, N-acetylglucosamine, does protect the C-terminal domain and catalytic activity, but does not prevent proteolysis of the N-terminal half of the molecule. These results are consistent with previous work [M. Nemat-Gorgani and J. E. Wilson (1986) Arch. Biochem. Biophys. 251, 97-103; D. M. Schirch and J. E. Wilson (1987) Arch. Biochem. Biophys. 254, 385-396] demonstrating that binding sites for both hexose and nucleotide substrates, and thus catalytic function, are associated with a 40-kDa domain located at the C-terminus of the enzyme. They further demonstrate that the binding site for the allosteric effector, Glc-6-P, lies in the N-terminal half of the molecule and is distinct from the catalytic site. Using protection against proteolysis as a reflection of binding, it is shown that the Glc-6-P binding site in the N-terminal region has all the characteristics described for the allosteric effector site on this enzyme in terms of affinity for Glc-6-P, specificity, and synergistic interactions with the hexose binding site in the C-terminal region of the molecule. This disposition of catalytic and regulatory functions in discrete halves of the molecule is consistent with suggestions by several investigators that mammalian hexokinases evolved by a process of duplication and fusion of an ancestral gene coding for a hexokinase similar to the present-day yeast enzyme, with the regulatory site of mammalian hexokinases having evolved from what was originally a catalytic site.     

Tryptophan 80 and leucine 143 are critical for the hydride transfer step of thymidylate synthase by controlling active site access

Mutant forms of thymidylate synthase (TS) with substitutions at the conserved active site residue, Trp 80, are deficient in the hydride transfer step of the TS reaction. These mutants produce a beta-mercaptoethanol (beta-ME) adduct of the 2'-deoxyuridine-5'-monophosphate (dUMP) exocyclic methylene intermediate. Trp 80 has been proposed to assist hydride transfer by stabilizing a 5,6,7,8-tetrahydrofolate (THF) radical cation intermediate [Barrett, J. E., Lucero, C. M., and Schultz, P. G. (1999) J. Am. Chem. Soc. 121, 7965-7966.] formed after THF changes its binding from the cofactor pocket to a putative alternate site. To understand the molecular basis of hydride transfer deficiency in a mutant in which Trp 80 was changed to Gly, we determined the X-ray structures of this mutant Escherichia coli TS complexed with dUMP and the folate analogue 10-propargyl-5,8-dideazafolate (CB3717) and of the wild-type enzyme complexed with dUMP and THF. The mutant enzyme has a cavity in the active site continuous with bulk solvent. This cavity, sealed from bulk solvent in wild-type TS by Leu 143, would allow nucleophilic attack of beta-ME on the dUMP C5 exocyclic methylene. The structure of the wild-type enzyme/dUMP/THF complex shows that THF is bound in the cofactor binding pocket and is well positioned to transfer hydride to the dUMP exocyclic methylene. Together, these results suggest that THF does not reorient during hydride transfer and indicate that the role of Trp 80 may be to orient Leu 143 to shield the active site from bulk solvent and to optimally position the cofactor for hydride transfer.     

The Intrinsically Disordered N-terminal Domain of Thymidylate Synthase Targets the Enzyme to the Ubiquitin-independent Proteasomal Degradation Pathway

The ubiquitin-independent proteasomal degradation pathway is increasingly being recognized as important in regulation of protein turnover in eukaryotic cells. One substrate of this pathway is the pyrimidine biosynthetic enzyme thymidylate synthase (TS; EC 2.1.1.45), which catalyzes the reductive methylation of dUMP to form dTMP and is essential for DNA replication during cell growth and proliferation. Previous work from our laboratory showed that degradation of TS is ubiquitin-independent and mediated by an intrinsically disordered 27-residue region at the N-terminal end of the molecule. In the current study we show that this region, in cooperation with an α-helix formed by the next 15 residues, functions as a degron, i.e. it is capable of destabilizing a heterologous protein to which it is fused. Comparative analysis of the primary sequence of TS from a number of mammalian species revealed that the N-terminal domain is hypervariable among species yet is conserved with regard to its disordered nature, its high Pro content, and the occurrence of Pro at the penultimate site. Characterization of mutant proteins showed that Pro-2 protects the N terminus against N^α-acetylation, a post-translational process that inhibits TS degradation. However, although a free amino group at the N terminus is necessary, it is not sufficient for degradation of the polypeptide. The implications of these findings to the proteasome-targeting function of the N-terminal domain, particularly with regard to its intrinsic flexibility, are discussed.     

Studies on the degradative mechanism of phosphoenolpyruvate carboxykinase from yeast Saccharomyces cerevisiae

Previous work carried out in our laboratory (Burlini, N., Lamponi S., Radrizzani, M., Monti, E. and Tortora P. (1987) Biochim. Biophys. Acta 930, 220-229) led to the immunological identification of a yeast 65-kDa phosphoprotein as a modified form of phosphoenolpyruvate carboxykinase; moreover the appearance of this phospho form was proven to be independent of cAMP, whereas the glucose-induced inactivation of the native enzyme is cAMP-dependent. Here, we report further investigations on the mechanism of the glucose-triggered degradation of the enzyme which led to the following results: (a) the aforementioned phospho form displayed a binding pattern to 5 AMP-Sepharose 4B quite similar to that of native enzyme, although it did not retain its oligomeric structure, nor was it catalytically active; (b) its phosphate content was of about two residues per monomer; (c) its isoelectric point was slightly higher than that of native enzyme, this shows that the enzyme undergoes additional modifications besides phosphorylation; (d) it represented about 4% of the native enzyme in glucose-depressed cells; (e) other forms immunologically cross-reactive with the native enzyme were also isolated, whose molecular mass was in the range of 60-62 kDa, and they are probable candidates as degradation products of the phospho form; (f) time courses of the native and phospho forms in the presence and the absence of glucose provided data consistent with a kinetic model involving a strong stimulation of the decay of both forms effected by the sugar; (g) in the mutant ABYS1 (Achstetter, T., Emter, O., Ehmann, C. and Wolf, D.H. (1984) J. Biol. Chem. 259, 13334-13343) which is devoid of the four major vacuolar proteinases, the decay pattern was essentially the same as in wild-type; (h) effectors lowering intracellular ATP also retarded the first step of enzyme degradation; this points to an ATP-dependence of this step. Based on these results we propose a degradation mechanism consisting of an initial cAMP- and ATP-dependent modification of the enzyme, followed by a cAMP-independent phosphorylation, which leads to the appearance of the aforementioned monomeric phospho form; this in turn seems to undergo limited proteolysis. These data strongly suggest the occurrence of an intermediate form arising from the native one and whose phosphorylation gives rise to the 65-kDa phosphoprotein described here.     

Mapping subdomains in the C-terminal region of troponin I involved in its binding to troponin C and to thin filament.

Troponin I (TnI) is the inhibitory component of troponin, the ternary complex that regulates skeletal and cardiac muscle contraction. Previous work showed that the C-terminal region of TnI, when linked to the "inhibitory region" (residues 98-116), possesses the major regulatory functions of the molecule (Farah, C. S., Miyamoto, C. A., Ramos, C. H. I., Silva, A. C. R., Quaggio, R. B., Fujimori, K., Smillie, L. B., and Reinach, F. C. (1994) J. Biol. Chem. 269, 5230-5240). To investigate these functions in more detail, serial deletion mutants of the C-terminal region of TnI were constructed. These experiments showed that longer C-terminal deletions result in lower inhibition of the actomyosin ATPase activity and weaken the interaction with the N-terminal domain of troponin C (TnC), consistent with the antiparallel model for the interaction between these two proteins. The conclusion is that the whole C-terminal region of TnI is necessary for its full regulatory activity. The region between residues 137 and 144, which was shown to have homology with residues 108-115 in the inhibitory region (Farah, C. S., and Reinach, F. C. (1995) FASEB J. 9, 755-767), is involved in the binding to TnC. The region between residues 98 and 129 is involved in modulating the affinity of TnC for calcium. The C-terminal residues 166-182 are involved in the binding of TnI to thin filament. A model for the function of TnI is discussed.     

Ligand-mediated induction of thymidylate synthase occurs by enzyme stabilization. Implications for autoregulation of translation

Thymidylate synthase (TS) is indispensable in the de novo synthesis of dTMP. As such, it has been an important target at which anti-neoplastic drugs are directed. The fluoropyrimidines 5-fluorouracil and 5-fluoro-2'-deoxyuridine are cytotoxic as a consequence of inhibition of TS by the metabolite 5-fluoro-2'-deoxyuridine 5'-monophosphate (FdUMP). This inhibition occurs through formation of a stable ternary complex among the enzyme, the nucleotide analog, and the co-substrate N5, N10-methylenetetrahydrofolate. Numerous studies have shown that cellular concentrations of TS undergo about a 2-4-fold induction following treatment with TS inhibitors. An extensive body of in vitro studies has led to the proposal that this induction occurs because of relief of the translational repression brought on by the binding of TS to its own mRNA. In the current study, we have tested several predictions of this autoregulatory translation model. In contrast to expectations, we find that fluoropyrimidines do not cause a change in the extent of ribosome binding to TS mRNA. Furthermore, mutations within the mRNA that abolish its ability to bind TS have no effect on the induction. Finally, enzyme turnover measurements show that the induction is associated with an increase in the stability of the TS polypeptide. Our results, in total, indicate that enzyme stabilization, rather than translational derepression, is the primary mechanism of TS induction by fluoropyrimidines and call into question the general applicability of the autoregulatory translation model.     

β-Amyloid Peptide Interacts Specifically with the Carboxyl-Terminal Domain of Human Apolipoprotein E

Abstract : Growing evidence indicates the involvement of apolipoprotein E (apoE) in the development of late-onset and sporadic forms of Alzheimer's disease, although its exact role remains unclear. We previously demonstrated that β-amyloid peptide (Aβ) displays membrane-destabilizing properties and that only apoE2 and E3 isoforms inhibit these properties. In this study, we clearly demonstrate that the carboxy-terminal lipid-binding domain of apoE (e.g., residues 200-299) is responsible for the Aβ-binding activity of apoE and that this interaction involves pairs of apoE amphipathic α-helices. We further demonstrate that Aβ is able to inhibit the association of the C-terminal domain of apoE with lipids due to the formation of Aβ/apoE complexes resistant to sodium dodecyl sulfate-polyacrylamide gel electrophoresis. On the contrary, the amino-terminal receptor-binding domain of apoE (e.g., residues 129-169) is not able to form stable complexes with Aβ. These data extend our understanding of human apoE-dependent binding of Aβ by involving the C-terminal domain of apoE in the efficient formation of apoE/Aβ complex.     

Interaction of bradykinin with sodium dodecyl sulfate and certain acidic lipids

The striking change in the circular dichroism (CD) of bradykinin (BK) occasioned by its interaction with sodium dodecyl sulfate (SDS) is evidently due in large part to a change in the conformation of the C-terminal tetrapeptide moiety of the hormone. The full change in CD is induced by the binding of two molecules of monomeric SDS per peptide molecule, the complex being aggregated. Formation of the 1:2 BK-SDS complex apparently proceeds via intermediates of stoichiometry 1:1 and 2:1. The cooperative nature of the interaction is attributed to the SDS-promoted aggregation of BK. Electrostatic interactions with the Arg residues appear important for the binding reaction per se. CD reveals that BK also interacts with acidic lipids which bear a net electrical charge (e.g., cerebroside sulfate and phosphatidyl inositol) but not with lipids bearing no net charge (e.g., cerebroside and phosphatidyl choline). The interactions are with particular mixed micelles of the lipid and the nonionic surfactant used for their solubilization, micellar size and structure being examined by surface tensiometry and electron microscopy.     

Effects of subunit occupancy on partitioning of an intermediate in thymidylate synthase mutants

Experimental evidence for a 5-exocyclic methylene-dUMP intermediate in the thymidylate synthase reaction was recently obtained by demonstrating that tryptophan 82 mutants of the Lactobacillus casei enzyme produced 5-(2-hydroxyethyl)thiomethyl-dUMP (HETM-dUMP) (Barret, J. E., Maltby, D. A., Santi, D. V., and Schultz, P. G. (1998) J. Am. Chem. Soc. 120, 449-450). The unusual product was proposed to emanate from trapping of the intermediate with beta-mercaptoethanol in competition with hydride transfer from H(4)folate to form dTMP. Using mutants of the C-terminal residue of thymidylate synthase, we found that the ratio of HETM-dUMP to dTMP varies as a function of CH(2)H(4)folate concentration. This observation seemed inconsistent with the conclusion that both products arose from a common intermediate in which CH(2)H(4)folate was already bound to the enzyme. The enigma was resolved by a kinetic model that allowed for differential partitioning of the intermediate formed on each of the two subunits of the homodimeric enzyme in forming the two different products. With three C-terminal mutants of L. casei TS, HETM-dUMP formation was consistent with a model in which product formation occurs upon occupancy of the first completely bound subunit, the rate of which is unaffected by occupancy of the second subunit. With one analogous E. coli TS mutant, HETM-dUMP formation occurred upon occupancy of the first subunit, but was inhibited when both subunits were occupied. With all mutants, dTMP formation occurs from occupied forms of both subunits at different rates; here, binding of cofactor to the first subunit decreased affinity for the second, but the reaction occurred faster in the enzyme form with both subunits bound to dUMP and CH(2)H(4)folate. The model resolves the apparent enigma of the cofactor-dependent product distribution and supports the conclusion that the exocyclic methylene intermediate is common to both HETM-dUMP and dTMP formation.     

Peptidoglycan hydrolase enterolysin a recognizes lipoteichoic Acid chains in the cell walls of sensitive bacteria

C-terminal domain of peptidoglycan hydrolase enterolysin A (EnlA) is involved in specific recognition and binding to the target cell envelopes and represents true cell wall binding (CWB) domain. Sensitivity/resistance to EnlA is dependent on binding ability/disability of its CWB domain. We assume that main mechanism of resistance against EnlA is absence of the specific receptor on the cell surface, which is necessary for binding of the enzyme molecule. Using competitive and enzymatic assays we have uncovered the chemical nature of the EnlA receptor, which is a lipoteichoic acid.     

Analysis of Tubespins as a suitable scale‐down model of bioreactors for high cell density CHO cell culture

High cell density (HCD) culture increases recombinant protein productivity via higher biomass. Compared to traditional fed‐batch cultures, HCD is achieved by increased nutrient availability and removal of undesired metabolic components via regular medium replenishment. HCD process development is usually performed in instrumented lab‐scale bioreactors (BR) that require time and labor for setup and operation. To potentially minimize resources and cost during HCD experiments, we evaluated a 2‐week 50‐mL Tubespin (TS) simulated HCD process where daily medium exchanges mimic the medium replacement rate in BR. To best assess performance differences, we cultured 13 different CHO cell lines in simulated HCD as satellites from simultaneous BR, and compared growth, metabolism, productivity and product quality. Overall, viability, cell‐specific productivity and metabolism in TS were comparable to BR, but TS cell growth and final titer were lower by 25 and 15% in average, respectively. Peak viable cell densities were lower in TS than BR as a potential consequence of lower pH, different medium exchange strategy and dissolved oxygen limitations. Product quality attributes highly dependent on intrinsic molecule or cell line characteristics (e.g., galactosylation, afucosylation, aggregation) were comparable in both scales. However, product quality attributes that can change extracellularly as a function of incubation time (e.g., deamidation, C‐terminal lysine, fragmentation) were in general lower in TS because of shorter residence time than HCD BR. Our characterization results and two case studies show that TS‐simulated HCD cultures can be effectively used as a simple scale‐down model for relative comparisons among cell lines for growth or productivity (e.g., clone screening), and for investigating effects on protein galactosylation. © 2017 American Institute of Chemical Engineers Biotechnol. Prog., 33:490–499, 2017     

Effect of ligand-induced conformational changes on the reactivity of specific sulfhydryl residues in rat brain hexokinase

Rat brain hexokinase (ATP:D-hexose 6-phosphotransferase, EC 2.7.1.1) contains 21 cysteine residues. On the basis of the amino acid sequence of the enzyme, these are predicted to be distributed among 14 peptides produced by tryptic digestion. Ten of these peptides, containing cysteine residues derivatized by reaction with the specific sulfhydryl reagent 2-bromoacetamido-4-nitrophenol have been identified in HPLC peptide maps; the four missing peptides are predicted to be relatively large and hydrophobic in character, properties that may have prevented their detection under the present conditions. The sequences encompassed by the 10 identified peptides include 12 of the 21 cysteine residues in the enzyme. The relative reactivity of these sulfhydryl groups with 2-bromoacetamido-4-nitrophenol has been assessed, and is in general accord with what might be predicted on the basis of their accessibility in the previously proposed structure for this enzyme. The effect of various ligands on reactivity of identified sulfhydryl groups has been determined; unique patterns of altered reactivity, resulting from ligand-induced conformational changes, have been observed. Biphasic effects were observed with increasing concentrations of either glucose 6-phosphate (Glc-6-P) or Pi. In both cases, decreased reactivity of sulfhydryls in the N-terminal half of the molecule was observed at low concentrations of the ligand, while further increase in ligand concentration resulted in decreased reactivity of sulfhydryl groups in the C-terminal half. In contrast, sulfhydryls in both N- and C-terminal halves were protected concomitantly by increasing concentrations of Glc. These results are consistent with previous studies that indicated (a) the existence of two sites for binding of Glc-6-P or Pi, a high affinity site in the N-terminal half and a site with lower affinity in the C-terminal half of the brain hexokinase molecule, and (b) binding of Glc to a single site located in the C-terminal half but evoking conformational effects throughout the molecule; the glucose analog, N-acetylglucosamine, previously shown to have more limited effects on conformation, affected reactivity of sulfhydryl groups only in the C-terminal half of the molecule. As reflected by effects on reactivity of sulfhydryl groups, conformational changes induced by binding of nucleotides depends markedly on the specific nature of the purine or pyrimidine base as well as the length and chelation status of the polyphosphate side chain. These results focus attention on specific regions of the molecule (the immediate environment of the sulfhydryl groups) that are affected by the binding of these ligands.     

Biological and pathological functions of phospholipase A(2) receptor

In 40% dimethyl sulfoxide (Me2SO) high-affinity ouabain (O) binding to Na,K-ATPase (E) is promoted by Mg2+ in the absence of inorganic phosphate (Pi) (Fontes et al., Biochim. Biophys. Acta 1104, 215-225, 1995). Furthermore, in Me2SO the EO complex reacts very slowly with Pi and this ouabain binding can therefore be measured by the degree of inhibition of rapid phosphoenzyme formation. Here we found that, unexpectedly, the ouabain binding decreased with the enzyme concentration in the Me2SO assay medium. We extracted the enzyme preparation with Me2SO or chloroform/methanol and demonstrated that the extracted (depleted) enzyme bound ouabain poorly. Addition of such extracts to assays with low enzyme concentration or depleted enzyme fully restored the high-affinity ouabain binding. Dialysis experiments indicated that the active principle had a molecular mass between 3.5 and 12 kDa. It was highly resistant to proteolysis. It was suggested that the active principle could either be a low-molecular-weight, proteolysis-resistant-peptide (e.g., a proteolipid) or a factor with a nonproteinaceous nature. A polyclonal antibody raised against the C-terminal 10 amino acids of the rat kidney gamma-subunit was able to recognize this low-molecular-weight peptide present in the extracts. The previously depleted enzyme displayed lower amounts of the gamma-proteolipid in comparison to the native untreated enzyme, as demonstrated by immunoreaction with the antibody.     

Selectide Technology: Bead-Binding Screening

The Selectide process is a random synthetic chemical library method based on the one-bead one-peptide (structure) concept. A "split-synthesis" method is used to generate huge random libraries (10⁶-10⁸). At the end of the synthesis, each bead expresses only one chemical entity (e.g., peptide). The whole library is then tested simultaneously for binding to a specific acceptor molecule of biologic interest. The ligand bead that interacts specifically with the acceptor molecule is then isolated for structure determination. Once a binding motif is identified, a secondary library (based on the motif of the primary screen) is generated and screened under a more stringent condition to identify leads of higher affinity. This process can be applied to both peptide and nonpeptide (small organic) libraries. In the case of nonsequencable structure libraries, the coding principle has to be applied for structure elucidation of positively reacting beads. Coding peptide is synthesized in parallel to the screening structure, and classical Edman degradation (one or multiple-step) is used for structural analysis. To exclude the possibility of interaction of the macromolecular target (e.g., receptor, enzyme, antibody) with the coding structure, a synthetic technique for segregation of the surface (screening structure) and the interior (coding structure) of the beads was developed. The one-bead one-structure process is invaluable in drug discovery for lead identification as well as further optimization of the initial leads. It also serves as an important research tool for molecular recognition.