Lipase-catalyzed synthesis of chlorogenate fatty esters in solvent-free medium

Chlorogenic acid (5-caffeoylquinic acid or 5-CQA) is an hydrophilic phenolic compound with antioxidant properties. Because of its high polarity, its antioxidant properties may be altered when formulated in oil based food or cosmetic preparations. Therefore, there is an interest in trying to enhance its hydrophobicity by grafting of an aliphatic chain. Such lipophilization reactions can be generally achieved through enzymatic catalysis. Our study consisted in synthesizing fatty cholorogenate esters in a two steps reaction. Firstly, 5-CQA was chemically esterified by methanol using an Amberlite IR120 H resin to obtain methyl chlorogenate that is more soluble in the fatty alcohols than 5-CQA. Secondly, this chlorogenate intermediate was transesterified with fatty alcohols of various chain lengths (C₄, C₈, C₁₂, or C₁₆) in the presence of Candida antarctica B lipase. Under optimal reaction conditions (a_w = 0.05; 5% (w/w) of biocatalyst), the transesterification rates were until two-fold higher than in the direct lipase-catalyzed esterification of chlorogenic acid by the same alcohols. The two-step reaction overall yield was between 61 and 93% depending on the alcohol chain length, whereas it was 40–60% for the direct esterification with the same alcohols.     

Stereochemical selectivity of group II intron splicing, reverse splicing, and hydrolysis reactions.

We have previously shown, using phosphorothioate substitutions at splice site, that both transesterification steps of group II intron self-splicing proceed, by stereochemical inversion, with an Sp but not an Rp phosphorothioate. Under alternative reaction conditions or with various intron fragments, group II introns can splice following hydrolysis at the 5' splice site and can also hydrolyze the bond between spliced exons (the spliced-exon reopening reaction). In this study, we have determined the stereochemical specificities of all of the major model hydrolytic reactions carried out by the aI5 gamma intron from Saccharomyces cerevisiae mitochondria. For all substrates containing exon 1 and most of the intron, the stereospecificity of hydrolysis is the same as for the step 1 transesterification reaction. In contrast, the spliced-exon reopening reaction proceeds with an Rp but not an Sp phosphorothioate at the scissile bond, as does true reverse splicing. Thus, by stereochemistry, this reaction appears to be related to the reverse of step 2 of self-splicing. Finally, a substrate RNA that contains the first exon and nine nucleotides of the intron, when reacted with the intron ribozyme, releases the first exon regardless of the configuration of the phosphorothioate at the 5' splice site, suggesting that this substrate can be cleaved by either the step 1 or the step 2 reaction site. Our findings clarify the relationships of these model reactions to the transesterification reactions of the intact self-splicing system and permit new studies to be interpreted more rigorously.     

A xylosyltransferase that synthesizes beta-(1-->4)-xylans in wheat (Triticum aestivum L.) seedlings

A particulate preparation from 6-day-old seedlings of wheat (Triticum aestivum L.) was found to contain a xylosyltransferase (XylTase) which incorporated xylose (Xyl) from UDP-xylose into exogenous beta-(1-->4)-xylooligosaccharides with 2-aminopyridine-derivatized reducing end groups. High-performance liquid chromatographic analysis showed that the chain elongation of pyridylaminated beta-(1-->4)-xylotriose (Xyl3-PA) occurred by attachment of a series of one, two, or three xylosyl residues, depending on substrate concentrations and reaction times. Methylation analysis and beta-xylosidase digestion of the newly synthesized Xyl4-PA confirmed that the xylosyl residues were incorporated through beta-(1-->4)-linkages. The enzyme was maximally active at pH 6.8 and 20 degrees C, and required Triton X-100, which enhanced activity 5-fold at a concentration of 0.05-2%. Divalent ions, including Mn2+ and Mg2+, did not affect activity. Enzyme activity increased with increasing polymerization of xylosyl residues of the acceptor substrates: for instance, Xyl5-PA was almost 7 times as efficient as Xyl2-PA. The apparent Michaelis constants of the enzyme for Xyl3-PA and UDP-xylose were 13.5 and 7.9 mM, respectively. The enzyme also catalyzed incorporation of radioactive sugars (Xyl together with a small portion of L-arabinose) from UDP-[14C]xylose into higher beta-(1-->4)-xylooligosaccharides (degree of polymerization > 7) with or without (4-O-methyl-)glucuronosyl side chains at activities comparable to those observed for pyridylaminated xylooligosaccharides, and into several heteroxylans but with much lower efficiency. Enzymatic hydrolysis of the product with a beta-xylanase degraded it into mainly xylobiose, providing further evidence that the xylosyl residues are incorporated through beta-(1-->4)-linkages.     

Effect of immobilization support, water activity, and enzyme ionization state on cutinase activity and enantioselectivity in organic media

We studied the reaction between vinyl butyrate and 2-phenyl-1-propanol in acetonitrile catalyzed by Fusarium solani pisi cutinase immobilized on zeolites NaA and NaY and on Accurel PA-6. The choice of 2-phenyl-1-propanol was based on modeling studies that suggested moderate cutinase enantioselectivity towards this substrate. With all the supports, initial rates of transesterification were higher at a water activity (a(w)) of 0.2 than at a(w) = 0.7, and the reverse was true for initial rates of hydrolysis. By providing acid-base control in the medium through the use of solid-state buffers that control the parameter pH-pNa, which we monitored using an organo-soluble chromoionophoric indicator, we were able, in some cases, to completely eliminate dissolved butyric acid. However, none of the buffers used were able to improve the rates of transesterification relative to the blanks (no added buffer) when the enzyme was immobilized at an optimum pH of 8.5. When the enzyme was immobilized at pH 5 and exhibited only marginal activity, however, even a relatively acidic buffer with a pK(a) of 4.3 was able to restore catalytic activity to about 20% of that displayed for a pH of immobilization of 8.5, at otherwise identical conditions. As a(w) was increased from 0.2 to 0.7, rates of transesterification first increased slightly and then decreased. Rates of hydrolysis showed a steady increase in that a(w) range, and so did total initial reaction rates. The presence or absence of the buffers did not impact on the competition between transesterification and hydrolysis, regardless of whether the butyric acid formed remained as such in the reaction medium or was eliminated from the microenvironment of the enzyme through conversion into an insoluble salt. Cutinase enantioselectivity towards 2-phenyl-1-propanol was indeed low and was not affected by differences in immobilization support, enzyme protonation state, or a(w).     

Metal Ion Catalysis in the Hydrolysis of Esters of 2-Hydroxy-1,10-phenanthroline: The Effects of Metal Ions on Intramolecular Carboxyl Group Participation

Rate constants have been determined for hydrolysis of the acetate, glutarate, and phthalate monoesters of 2-hydroxy-1,10-phenanthroline in water at 30°C and μ = 0.1 M with KCl. The hydrolysis reactions of the esters are hydroxide ion catalyzed at pH > 9. The phthalate and glutarate monoesters have in addition pH-independent reactions from pH 5.5 to 9 that involve intramolecular participation by the neighboring carboxylate anion. The pH-independent reaction of the glutarate monoester is 5-fold faster than that of the phthalate monoester. The plots of log k_obsd vs pH for hydrolysis of the carboxyl substituted esters are bell shaped at pH < 5, which indicates a rapid reaction of the zwitterionic species (carboxyl anion and protonated phenanthroline nitrogen). The divalent metal ions, Cu²⁺, Ni²⁺, Zn²⁺, and Co²⁺, complex strongly with the esters; saturation occurs at metal ion concentrations less than 0.01 M. The 1:1 metal ion complexes have greatly enhanced rates of hydrolysis; the second-order rate constants for the OH⁻ reactions are increased by factors of 10⁵ to 10⁸ by the metal ion. The pH-rate constant profiles for the phthalate and glutarate ester metal ion complexes have a sigmoidal region below pH 6 that can be attributed to a metal ion-promoted carboxylate anion nucleophilic reaction. The carboxyl group reactions are enhanced 10² - to 10³ -fold by the metal ions, which allows the neighboring group reaction to be competitive with the favorable metal ion-promoted OH⁻ reaction at pH < 6, but not at pH > 6. The half-lives of the pH-independent neighboring carboxyl group reactions of the Cu(II) complexes at 30°C are l2 s. The other metal ion complexes are only slightly less reactive (half-lives vary from 2.5 to 40 s). These are the most rapid neighboring carboxyl group reactions that have been observed in ester hydrolysis.     

Acid-catalyzed hydrolysis of α-ketoglutaramic acid : A proposed mechanism involving decarboxylation and amide hydrolysis of the γ-lactam, 2-pyrrolidone-5-hydroxy-5-carboxylic acid

The rates of the acid-catalyzed decarboxylation and amide hydrolysis of α-ketoglutaramic acid, the keto analog of glutamine, were investigated and the products of the reactions were characterized. In strong acid at 100°C, amide hydrolysis and decarboxylation occur with about equal facility, yielding α-ketoglutaric acid and 5-hydroxy-2-pyrrolidone, respectively. 5-Hydroxy-2-pyrrolidone undergoes further amide hydrolysis so that the products of complete acid hydrolysis of α-ketoglutaramic acid are ammonia (100%), carbon dioxide (50%), and approximately equal yields (50%) of α-ketoglutaric acid and succinic semialdehyde (β-formylpropionic acid). At increasing pH values, the relative rate of decarboxylation to amide hydrolysis of α-ketoglutaramic acid increases, such that, at pH values of 2 or greater, decarboxylation occurs almost exclusively. The decarboxylation product 5-hydroxy-2-pyrrolidone, was characterized chromatographically and by its infrared and pmr spectra; the compound may be regarded as the cyclized form of succinamic semialdehyde. A mechanism for the competing amide hydrolysis and decarboxylation reactions is proposed, and the potential biological significance of the decarboxylation pathway is discussed.     

Screening of plant peptidases for the synthesis of arginine-based surfactants

Partially purified preparations with proteolytic activity, obtained from South American native plants, were used as biocatalysts in condensation reactions of N-protected arginine alkyl ester derivatives with decylamine and dodecylamine in low-water content systems. The final products are cationic surfactants with potential application as emulsifiers and preservatives. Most of the proteolytic extracts were obtained from latex of species belonging to the Asclepiadaceae family (araujiain from Araujia hortorum, asclepain c from Asclepias curassavica and funastrain from Funastrum clausum). Hieronymain was obtained from unripe fruits of Bromelia hieronymi (Bromeliaceae). Plant proteases from commercial sources (papain and bromelain) were also tested as catalysts in the same reactions. Araujiain and funastrain furnished good reaction conversions (60–84%, with a ratio synthesis/hydrolysis of 2–5) similar to those obtained with commercial papain. Moreover, araujiain was the biocatalyst which rendered the best conversions (60%) for the synthesis of the two novel Bz-Arg-NH-dodecylamide (Bz-Arg-NHC₁₂) and Bz-Arg-NH-decylamide (Bz-Arg-NHC₁₀) derivatives. Moderate to poor conversions (10–50%, showing a ratio synthesis/hydrolysis of 0.5–1) were achieved with asclepain c, hieronymain and bromelain. The screening presented in this work revealed that, although these are structurally similar, their behavior for the synthesis of this kind of products differ among them.     

High-performance liquid chromatographic determination of N-[2- (hydroxyethyl)-N-(2-(7-guaninyl)ethyl)]methylamine, a reaction product between nitrogen mustard and DNA and its application to biological samples

Nitrogen mustard (HN2) is a bifunctional alkylating agent which is thought to cause cytotoxicity by covalently binding to DNA. Most studies to date have looked at qualitatively determining the presence of DNA–HN2 adducts from reactions with native DNA. The adduct which is predominately formed in these reactions is N-[2-(hydroxyethyl)-N-(2-(7-guaninyl)ethyl]methylamine (N7G). A simple and sensitive reversed-phase high-performance liquid chromatographic (HPLC) method for the determination of N7G from DNA using ultraviolet detection is described. DNA samples having been exposed to HN2 treatment were hydrolyzed and preseparated from high-molecular-mass material by filtration using a molecular mass cut-off of 3000. The mobile phase consisted of methanol–26 mM ammonium formate, pH 6.5 (24:76, v/v). N7G, as well as the internal standard, methoxyphenol, were separated within 30 min. The recovery of N7G after hydrolysis of the DNA reaction product was quantitative and limits of detection and quantification of 10 and 20 ng/ml, respectively, were calculated. The method was validated in DNA–HN2 dose response experiments. The N7G reaction product appears to be the first reaction product formed at lower ratios of HN2/DNA but its production plateaus at higher ratios of HN2/DNA probably due to increased formation of hitherto unknown adducts. The method is simple and sensitive and for this reason, may be suited for the determination of DNA/HN2 reaction products.     

Effect of repeated harvesting on the content of caffeic acid and seven species of caffeoylquinic acids in sweet potato leaves

The purpose of this study was to investigate the effect of repeated harvesting on the content of caffeic acid (CA) and seven species of caffeoylquinic acids (CQAs) in sweet potato leaves using a newly developed high-performance liquid chromatography method. Six cultivars and two breeding lines were used in this study. Leaves were collected at monthly intervals from 1st harvest (May) to 4th harvest (August) in 2011 and 2012. ANOVA analysis revealed that the contents of CQAs were significantly different among all cultivars and breeding lines, but no significant differences were found for CA. No annual variation was confirmed in CA and CQAs. Repeated harvest of sweet potato leaves affected the content of only 4-CQA and 5-CQA. Post-hoc comparisons using Tukey’s method indicated that the contents of 4-CQA and 5-CQA in sweet potato leaves harvested at first time were significantly higher compared to those at the other harvest times.     

Unexpected metal ion requirements specific for catalysis of the branching reaction in a group II intron

The splicing process catalyzed by group II intron ribozymes follows the same two-step pathway as nuclear pre-mRNA splicing. In vivo, the first splicing step of wild-type introns is a transesterification reaction giving rise to a branched lariat intron-3'-exon intermediate characteristic of this splicing mode. In the wild-type introns, the ribozyme core and the substrate intron-exon junctions are carried by the same precursor molecule, making it difficult to distinguish between RNA folding and catalysis under normal splicing reactions. To characterize the catalytic step of the first transesterification reaction, we studied the reversal of this reaction, reverse branching. In this reverse reaction, the excised lariat intron and the substrate 5'-exon can be preincubated and folded separately, allowing the measure of the catalytic rate of the reaction. To measure the catalytic rate of the second splicing step, purified lariat intron-3'-exon intermediate molecules were preincubated and folded prior to the addition of 5'-exon. Conditions could be found where chemistry appeared rate limiting for both catalytic steps. Study of the metal ion requirements under these conditions resulted in the unexpected finding that, for the intron studied, substitution of magnesium ions by manganese ions enhanced the rate of the first transesterification reaction by two orders of magnitude but had virtually no effect on the second transesterification reaction or the 5' splice site cleavage by hydrolysis. Finally, the catalytic rates measured under optimal conditions for both splicing steps were faster by three orders of magnitude in the branching pathway than in the hydrolytic pathway.     

Improvement of cell-bound lipase from Rhodotorula mucilaginosa P11I89 for use as a methanol-tolerant, whole-cell biocatalyst for production of palm-oil biodiesel

Rhodotorula mucilaginosa P11I89, isolated from oil-contaminated soil, was effectively used as the methanol-tolerant, whole-cell lipase for the synthesis of fatty acid methyl ester (FAME) via transesterification reaction in the presence of palm oil and methanol substrates at a 1:6 mole ratio. A combination of Taguchi experimental design and response surface methodology (RSM) were applied to systemically enhance transesterification activity of the whole-cell lipase or cell-bound lipase (CBL) from R. mucilaginosa P11I89 in a solvent-free system. The significant impacts of four factors including carbon sources, nitrogen sources, surfactants and pH on hydrolysis activity of extracellular and cell-bound lipases, and on the transesterification activity of CBL were evaluated using Taguchi design. Gum Arabic was the most significant component for high transesterification activity, whereas soybean oil was the most influential factor for the hydrolysis activity. Maximal CBL production of 272.72 U/L was obtained in the cultivation medium containing 2.1 % palm oil, 0.2 % NH₄NO₃ , and 0.45 % Gum Arabic, with initial pH 5.0 under shaking speed of 200 rpm at a temperature of 30?±?2 °C after 60 h incubation using Central Composite Design (CCD). Yeast cells grown under such conditions increased FAME yield from 84.0 to 92.98 % when the transesterification reaction was carried out, in comparison to those cultivated in the initial medium.     

Characterization of the reversible nature of the reaction catalyzed by sphingolipid ceramide N-deacylase. A novel form of reverse hydrolysis reaction.

Sphingolipid ceramide N-deacylase catalyzes a reversible reaction in which the amide linkages of the ceramides of various sphingolipids are cleaved or synthesized. Hydrolysis of sphingolipids by the enzyme proceeded efficiently at acidic pH in the presence of high concentrations of detergents, whereas the reverse reaction tended to be favored at neutral pH with a decrease in the detergent concentration. Although the catalytic efficiency (V(max)/K(m)) of the hydrolysis and reverse reactions was changed mainly by the concentration of detergents in the reaction mixture, V(max) and K(m) for the reverse reaction were relatively higher than those for the forward reaction, irrespective of the detergent concentration. The reverse reaction proceeded most efficiently when the molar ratio of lyso-sphingolipids and fatty acids was fixed at 1 : 1-2, the yield of the reaction exceeding 70-80%. The reverse and exchange (transacylation) reactions did not require ATP, CoA, metal ions or addition of organic solvents. Studies using inhibitors and chemical modifiers of the enzyme protein suggested that both the hydrolysis and condensation reactions are catalyzed at the same catalytic domain. These results indicate that the reverse hydrolysis reaction of the enzyme is unique, being completely different from those of lipases, proteases and glycosidases reported to date.     

Bacterial Degradation of Ring-Chlorinated Acetophenones

Two strains, Alcaligenes sp. strain ACA and Pseudomonas fluorescens ACB, isolated from acetophenone and 4′-hydroxyacetophenone enrichments, respectively, cometabolize a range of chlorinated acetophenones (CAs). A biological Baeyer-Villiger reaction converts the CA to chlorophenyl acetate. This is evident only in the presence of an esterase inhibitor, since the CA is normally rapidly hydrolyzed to a chlorophenol which has the same substitution pattern as the original ketone. The oxygenase that attacks the ketone uses NADPH in the incorporation of one atom of ¹⁸O₂ and is strongly inhibited by phenols that bear an ortho or meta chlorine or bromine, but much less by cresols or phenol itself. A feedback phenomenon may thus account for the inability of strain ACA to grow on CAs, which also fail to induce the cells for their own metabolism.     

Enzymatic transesterifications of carbonates in water-restricted environments

We investigated the ability of several hydrolases to catalyze reactions with an abiotic water-insoluble substrate, carbonic acid diphenyl ester, also known as diphenyl carbonate (DPC). In single-phase water/organic systems, turnover numbers (TN) of greater than 2 x 10(4) min(-1)have been achieved for the hydrolysis of DPC. The K(m) values for the hydrolytic reaction were measured to be 200muM and 330muM for Candida cylindracea lipase and Porcine liver esterase, respectively. In addition to hydrolysis, we observed transesterification of carbonates with a wide variety of alcohol and phenol species. Transesterifications of DPC with bifunctional alcohols resulted in the synthesis of polycarbonates. We investigated the stability and transesterification activity of these enzymes in several water-restricted environments to limit competing hydrolysis reactions. We find that, with the removal of water, hydrolysis is reduced more than four orders of magnitude while transesterification is diminished only 10-fold (turnover numbers of 600 min(-1) in water-miscible systems to 60 min(-1) in water-restricted environments with pure Candida lipase). Stability of the Candida lipase in these water-restricted environments (half-life of longer than 3 days) is much greater than in water/organic single phase systems (5 h in 20% methanol). In addition, the Candida lipase displayed enantiomeric selectivity in transesterifications of DPC with racemic 2-butanol (greater than 80% ee).     

Catalytic effects of Murchison Material: Prebiotic Synthesis and Degradation of RNA Precursors

Mineral components of the Murchison meteorite were investigated in terms of potential catalytic effects on synthetic and hydrolytic reactions related to ribonucleic acid. We found that the mineral surfaces catalyzed condensation reactions of formamide to form carboxylic acids, amino acids, nucleobases and sugar precursors. These results suggest that formamide condensation reactions in the parent bodies of carbonaceous meteorites could give rise to multiple organic compounds thought to be required for the emergence of life. Previous studies have demonstrated similar catalytic effects for mineral assemblies likely to have been present in the early Earth environment. The minerals had little or no effect in promoting hydrolysis of RNA (24mer of polyadenylic acid) at 80°C over a pH range from 4.2 to 9.3. RNA was most stable in the neutral pH range, with a half-life ~5 h, but at higher and lower pH ranges the half-life decreased to ~1 h. These results suggest that if RNA was somehow incorporated into a primitive form of RNA-based thermophilic life, either it must be protected from random hydrolytic events, or the rate of synthesis must exceed the rate of hydrolysis.     

Fluorescent properties of monoamine neurons following glyoxylic acid treatment of intact leech ganglia

Summary The SPG modification (de la Torre and Surgeon 1976) of the glyoxylic acid method for amine condensation is a straightforward procedure which can be used upon intact ganglia from the leech. Intense fluorescence of the neurosomata of identified neurons which contain either indoleamine (serotonin, 5-HT) or catecholamine (CA) is obtained in less than 30 min. The fluorescence of the 5-HT containing neurons is yellow (518–526 nm) and decays more rapidly than the dominant blue emission (478–480 nm) of the CA neurons. Most importantly, the SPG technique greatly enhances the visibility of the axonal processes of neurons which contain both classes of amines over the fluorescence produced by formaldehyde condensation techniques. Both blue and yellow fluorescent varicosities are easily distinguished in the longitudinal connectives and lateral roots of the leech C.N.S. Because of its simplicity and high fluorescence yields, the SPG method for histochemical fluorescence should contribute to investigations of amine functions in invertebrate nervous systems.Supported by NIH research grant No. NS14481-03 and NSF research grant BNS-7915/08     

Photo and thermal reactions of ferrous hydroxide

The reactions of ferrous ion near neutral pH are of interest because of its known presence in the Archaean oceans. We have confirmed the long wavelength ultraviolet photochemical and the thermal reactions of ferrous hydroxide to form hydrogen. We have shown that a claim of the reduction of carbon dioxide to formaldehyde at neutral pH is mistaken. By the use of¹⁴C labelled compounds, we have found that less than 1 ppm of carbon dioxide is reduced to formaldehyde and less than 10 ppm of formate ion is so reduced. The thermal reaction to form hydrogen has a small activation energy of 7 kcal mole^–1. We conclude that thermal and photochemical formation of hydrogen from ferrous ion in the Archaean ocean could be comparable at pH 8–9. At lower pH, toward its limit at pH 5, the photochemical reaction would predominate. Both the thermal and photochemical reactions are specific for ferrous hydroxide, being far slower for the phosphate (>50- and 7-fold) and the bicarbonate (2- and 30-fold) complexes.     

Analogues of oxytocin antagonists bearing a ureido group in the amino acid side chain at position 4 or 5.

Substitution of the side chain carboxamido group at position 4 in the potent oxytocin antagonist (OTA) [ThiaPmp(1), D-Trp(2), Cys(6), Arg(8)]-OT, PA, in which ThiaPmp = beta,beta-(3-thiapentamethylene)-beta-mercaptopropionic acid, led to [Orn(Car)(4)]-PA, ([Cit(4)]-PA), which had uterotonic antagonistic activity equal to that of PA. The same modification at position 5, leading to [Cit(5)]-PA, resulted in antagonistic potency more than 10 times lower than that of PA. This paper also describes the same substitutions introduced in the highly potent OTA [Pen(6)]-PA (antioxytocic in vitro pA(2) = 8.72). Analogues of the general formula [U(4)-X(5)-Pen(6)]-PA, in which U = Lys, Orn, Dab, Dap or X = Orn, Dab or Dap, were synthesized by SPPS. Each of these analogues was carbamoylated by treatment with KCNO in DMF-H(2)O, yielding the corresponding U(Car)(4) or X(Car)(5) derivatives. In the uterotonic assay, the substitution with the ureido group at Gln(4) results in retention of high antagonistic potency, albeit somewhat lower than that of PA, e.g. [Orn(Car)(4), Pen(6)]-PA and [Dab(Car)(4), Pen(6)]-PA having pA(2) = 8.52 and pA(2) = 8.42 respectively. In the pressor assay, [Lys(Car)(4), Pen(6)]-PA and [Dab(Car)(4), Pen(6)]-PA were somewhat weaker antagonists of arginine vasopressin than [Pen(6)]-PA; [Dap(Car)(4), Pen(6)]-PA showed only a faint trace of pressor agonistic activity. The substitution with the ureido group at position 5 leads to a significant loss of OTA potency in the in vitro uterotonic assay. The [Orn(Car)(5), Pen(6)]-PA was the most potent of the series (pA(2) = 8.05). An interesting finding is that [Dap(Car)(5), Pen(6)]-PA is equipotent with its precursor [Dap(5), Pen(6)]-PA (potency in the uterotonic test in vitro, pA(2) = 7.71 and pA(2) = 7.68, respectively). Furthermore, neither [Dap(5), Pen(6)]-PA nor [Dap(5), Pen(6), Gly(9)]-PA exhibited activity in the antidiuretic or pressor assays. Although these last two analogues show some decrease in antioxytocin potency, they behave as pure oxytocin antagonists, which makes them attractive candidates for further studies on the development of potent and specific OTAs.