Synthesis of methyl α- and β-maltotriosides and aryl β-maltotriosides

Reaction of β-maltotriose hendecaacetate with phosphorus pentachloride gave 2′,2″,3,3′,3″,4″,6,6′,6″,-nona-O-acetyl-(2)-O-trichloroacetyl-β-maltotriosyl chloride (2) which was isomerized into the corresponding α anomer (8). Selective ammonolysis of 2 and 8 afforded the 2-hydroxy derivatives 3 and 9, respectively; 3 was isomerized into the α anomer 9. Methanolysis of 2 and 3 in the presence of pyridine and silver nitrate and subsequent deacetylation gave methyl α-maltotrioside. Likewise, methanolysis and O-deacetylation of 9 gave methyl β-maltotrioside which was identical with the compound prepared by the Koenigs—Knorr reaction of 2,2′,2″,3,3′,3″,4″,6,6′,6″-deca-O-acetyl-α-maltotriosyl bromide (12) with methanol followed by O-deacetylation. Several substituted phenyl β-glycosides of maltotriose were also obtained by condensation of phenols with 12 in an alkaline medium. Alkaline degradation of the o-chlorophenyl β-glycoside decaacetate readily gave a high yield of 1,6-anhydro-β-maltotriose.     

Synthesis of α- and β-glycosides containing spin labels,as probes for studies of carbohydrate-protein interaction

Nitroxide spin-labeled α-d-glycopyranosides were synthesized in good yield and in a highly stereoselective manner by reaction of per-O-benzyl-α-d-glycopyranosyl bromides with 2,2,6,6-tetramethyl-4-piperidinol under the bromide ion-catalyzed conditions devised by Lemieux etal. After hydrogenolysis, the deblocked intermidiates were oxidized to give the desired, spin-labeled α-d-glycopyranosides. Nitroxide spin-labeled α-d-glycopyranosides, as well as a β-maltoside, were synthesized by standard methods. The synthesis is also described of 2-amino-2-deoxy-d-glucose and -d-galactose derivatives having a spin label at C-2, and of the spin-labeled compound 1-[4-(β-d-galactopyranosyloxy)phenyl]-3-(2,2,6,6-tetramethylpiperidin-1-oxyl-4-yl)-2-thiourea.     

Characterization of the mRNAs for α-, β- and γ-actin

The mRNAs for α-, β- and γ-actin have been characterized with respect to molecular weight and poly(A) content. Polyacrylamide gel electrophoresis under denaturing conditions shows that the mRNA for α-actin (muscle-specific actin) is approximately 4.6 × 10⁵ daltons in size, and that the mRNAs for β- and γ-actin (nonmuscle actins) are much larger, approximately 6.6 × 10⁵ daltons in size. We therefore calculate that the noncoding regions of the β- and γ-actin mRNAs contain about 800 nucleotides. This is in marked contrast to the noncoding regions of α-actin mRNA which contain only about 180 nucleotides. During electrophoresis in high-resolution nondenaturing gels, the β-actin mRNA migrates slightly slower than the γ-actin mRNA. This indicates either that β-actin mRNA is about 100 nucleotides longer than γ-actin mRNA, or that these mRNAs differ in secondary structure. Fractionation of actin mRNA on the basis of poly(A) content shows that a substantial portion of the β-actin mRNA, but very little of the α- or γ-actin mRNAs, fails to bind to oligo(dT)-cellulose. Much of this poly(A)-deficient β-actin mRNA, however, does bind to poly(U)-Sepharose, a substrate with higher affinity for short poly(A) sequences. This indicates that many of these β-actin mRNA molecules are polyadenylated, but that they have unusually short poly(A) tails. The finding that β- and γ-actins are translated from mRNAs of different electrophoretic mobility and different poly(A) content strongly suggests that these two closely related proteins are products of different genes.     

Bromine oxidation of methyl α- and β-pyranosides of D-galactose,D-glucose,and D-mannose

Methyl α- and β-pyranosides of D-galactose, D-glucose, and D-mannose have been oxidized with bromine in aqueous solution at various pH values. The resulting keto glycosides were converted into their more-stable O-methyloxime derivatives which were characterized by spectroscopy and chromatography. Oxidation at a ring carbon atom where the hydrogen is axial is hindered by bulky substituents in syn (i.e., a 1,3) diaxial relationship. Thus, the aglycon group in the α anomers protects position 3, the axial HO-4 in galactopyranosides protects position 2, and the axial HO-2 in mannopyranosides protects position 4 from oxidation.     

Preparation and characterization of biotinylated probes for the β-interferon receptor

• 1.1. Recently we described the isolation of the β-interferon receptor [Zhang et al. (1986) J. biol. Chem. 261, 8017–8021]. A highly purified product was obtained but in low quantities.
• 2.2. The use ofbiotinylated β-interferon as a ligand represents an alternate approach to receptor isolation.
• 3.3. We have prepared and characterized the derivatives N-(biotinyl)- and N-(biotinyl-ϵ-aminocaproyl)-recombinant human [Ser¹⁷-interferon β (B- and BC-recHulFNβ).
• 4.4. Biotin incorporation does not result in any loss of antiviral activity, demonstrating the recognition of the derivative by the cell receptor.
• 5.5. The biotinylated recHuIFNβ binds specifically and reversibly to succinoylavidin or guanidine thiocyanate-stripped succinoylavidin linked to a Sepharose matrix.
• 6.6. Comparison of the competition curves obtained with [¹⁴C]biotin and [³H]biotinyl recHuIFN, in the presence of increasing concentrations of biotin suggests that the IFN moiety of the derivative has little effect on the affinity of biotin for avidin.
• 7.7. Biotinylated recHuIFNβ derivatives represent useful probes for the β-IFN receptor.

     

Synthesis of derivatives of methyl β-sophoroside

Selective tritylation of methyl β-sophoroside (1) and subsequent acetylation gave the 3,4,2′,3′,4′-penta-O-acetyl-6,6′-di-O-trityl derivative, which was O-detritylated, and the product p-toluenesulfonylated, to give methyl 3,4,2′,3′,4′-penta-O-acetyl-6,6′-di-O-p-tolylsulfonyl-β-sophoroside (4) in 63% net yield. Compound 4 was also obtained in 69% yield by p-toluenesulfonylation of 1, followed by acetylation. Several, 6,6′-disubstituted derivatives of 1 were synthesized by displacement reactions of 4 with various nucleophiles. Treatment of 4 with sodium methoxide afforded methyl 3,6:3′,6′-dianhydro-β-sophoroside. Several 6- and 6′-monosubstituted derivatives of 1 were prepared, starting from the 4,6-O-benzylidene derivative of 1.     

Synthesis and reactions of α- and β-d-glucopyranosyluronic esters of amino acids

The synthesis of the fully benzylated α- and β-d-glucopyranosyluronic esters of 1-benzyl N-benzyloxycarbonyl-l-aspartic and -glutamic acids and N-(tert-butoxycarbonyl)-l-phenylalanine, followed by hydrogenolysis, afforded the respective anomers of the 1-O-acyl-d-glucopyranuronic acids 2, 7, and 12. Esterification of both anomers of the N-acetylated derivatives of 2 and 7 by diazomethane was accompanied by glycosyl-bond cleavage, and, in the case of the α anomers, with concomitant 1→2 acyl migration to give, after O-acetylation, the 2-O-acyl O-acetyl methyl ester derivatives 5 and 10, respectively. Similarly, 12α yielded methyl 1,3,4-tri-O-acetyl-2-O-[N-(tert-butoxycarbonyl)-l-phenylalanyl]-d-glucopyranuronate and an analogue having a furanurono-6,3-lactone structure. Esterification of the C-5 carboxyl group, in 1-O-acyl-α-d-glucopyranuronic acids by methanol in the presence of the BF_3^?-MeOH reagent (1–1.5 equiv.) proceeded without acyl migration. By using this procedure, followed by acetylation, the N-acetylated derivative of 7α afforded methyl 2,3,4-tri-O-acetyl-1-O-(1-methyl N-acetyl-l-glutam-5-oyl)-α-d-glucopyranuronate, and 12α gave methyl 2,3,4-tri-O-acetyl-1-O-(N-acetyl-l-phenylalanyl)-α-d-glucopyranuronate; the formation of the latter involved cleavage of the tert-butoxycarbonyl group by BF₃, followed by N-acetylation in the next step.     

Synthesis and antiproliferative activity of novel α- and β-dialkoxyphosphoryl isothiocyanates

A series of 15 mostly new dialkoxyphosphoryl alkyl and aralkyl isothiocyanates were synthesized using two alternative strategies, and their in vitro antiproliferative activity against several cancer cell lines (including drug resistant) is here demonstrated. The IC₅₀ values measured for the new compounds are within the range of 6.3-21.5 μM, and they are quite similar to the activity of two best and most extensively investigated natural benzyl isothiocyanate (A) and phenethyl isothiocyanate (B). Preliminary studies utilizing the cell cycle and reduced glutathione level analysis performed on A549 lung cancer cell line using representative compounds revealed important differences in the mechanism of action possibly correlated with their chemical properties. Hydrophobic compounds react mainly with the cytosolic glutathione reduced leading to its depletion, causing an oxidative stress and cell cycle arrest in G0/G1 phase. On the other hand, hydrophilic compounds cause moderate cell cycle arrest and massive cell death associated with moderate reduced glutathione depletion. These suggest that significant changes in the chemical structure of isothiocyanates, which do not lead to the significant changes in antiproliferative activity, but simultaneously cause a differences in the mechanism of action are possible.     

Synthesis and characterization of magnetic β-cyclodextrin-chitosan nanoparticles as nano-adsorbents for removal of methyl blue

A novel nano-adsorbent, β-cyclodextrin-chitosan (CDC) modified Fe(3)O(4) nanoparticles (CDCM) is fabricated for removal of methyl blue (MB) from aqueous solution by grafting CDC onto the magnetite surface. The characteristics results of FTIR, SEM and XRD show that CDC is grafted onto Fe(3)O(4) nanoparticles. The grafted CDC on the Fe(3)O(4) nanoparticles contributes to an enhancement of the adsorption capacity because of the strong abilities of CDCM, which includes the multiple hydroxyl, carboxyl groups, amino groups and the formation of an inclusion complex due to the β-CD molecules through host-guest interactions, to adsorb MB. The adsorption of MB onto CDCM is found to be dependent on pH and temperature. Adsorption equilibrium is achieved in 50 min and the adsorption kinetics of MB is found to follow a pseudo-second-order kinetic model. Equilibrium data for MB adsorption are fitted well by Langmuir isotherm model. The maximum adsorption capacity for MB is estimated to be 2.78 g/g at 30°C. The CDCM was stable and easily recovered. Moreover the adsorption capacity was about 90% of the initial saturation adsorption capacity after being used four times.     

Characterization of the α- and β-Mannosidases of Porphyromonas gingivalis

Mannose is an important sugar in the biology of the Gram-negative bacterium Porphyromonas gingivalis. It is a major component of the oligosaccharides attached to the Arg-gingipain cysteine proteases, the repeating units of an acidic lipopolysaccharide (A-LPS), and the core regions of both types of LPS produced by the organism (O-LPS and A-LPS) and a reported extracellular polysaccharide (EPS) isolated from spent culture medium. The organism occurs at inflamed sites in periodontal tissues, where it is exposed to host glycoproteins rich in mannose, which may be substrates for the acquisition of mannose by P. gingivalis. Five potential mannosidases were identified in the P. gingivalis W83 genome that may play a role in mannose acquisition. Four mannosidases were characterized in this study: PG0032 was a β-mannosidase, whereas PG0902 and PG1712 were capable of hydrolyzing p-nitrophenyl α-d-mannopyranoside. PG1711 and PG1712 were α-1→3 and α-1→2 mannosidases, respectively. No enzyme function could be assigned to PG0973. α-1→6 mannobiose was not hydrolyzed by P. gingivalis W50. EPS present in the culture supernatant was shown to be identical to yeast mannan and a component of the medium used for culturing P. gingivalis and was resistant to hydrolysis by mannosidases. Synthesis of O-LPS and A-LPS and glycosylation of the gingipains appeared to be unaffected in all mutants. Thus, α- and β-mannosidases of P. gingivalis are not involved in the harnessing of mannan/mannose from the growth medium for these biosynthetic processes. P. gingivalis grown in chemically defined medium devoid of carbohydrate showed reduced α-mannosidase activity (25%), suggesting these enzymes are environmentally regulated.     

Studies of the selective silylation of methyl α- and β-d-aldohexopyranosides: stability of the partially protected derivatives in polar solvents

Treatment of methyl α- (1) and β-d-glucopyranoside, methyl α- (3) and β-d-galactopyranosides, and methyl α-d-mannopyranoside (5) with 2, 3, or 4 mol. equiv. of tert-butyldimethylsilyl (TBDMS) chloride under two conditions afforded mixtures of TBDMS ethers which were identified. The following compounds were isolated in synthetically useful yields, the 2,6-di-TBDMS either of 1 (70%), the 2,6-di- and 2,3,6-tri-TBDMS ethers of 3 (84% and 57%, respectively), and the 2,6-di-and 3,6-di-TBDMS ethers of 5 (50% and 80%, respectively). In dipolar solvents, no migration of the TBDMS groups was detected between partially silylated hydroxyl groups, but the addition of a base (triethylamine or imidazole) caused migration to vicinal cis positions.     

Conformational stabilities of the rat α- and β-parvalbumins

It is widely believed that β-parvalbumin (PV) isoforms are intrinsically less stable than α-parvalbumins, due to greater electrostatic repulsion and an abbreviated C-terminal helix. However, when examined by differential scanning calorimetry, the apo-form of the rat β-PV (i.e. oncomodulin) actually displays greater thermal stability than the α-PV. Whereas the melting temperature of the α isoform is 45.8°C at physiological pH and ionic strength, the T_m for the β isoform is more than 7° higher (53.6°C). This result suggests that factors besides net charge and C-terminal helix length strongly influence parvalbumin conformational stability. Extension of the F helix in the β-PV, by insertion of Ser-109, has a modest stabilizing effect, raising the T_m by 1.1°. Truncation of the α-PV F helix, by removal of Glu-108, has a more profound impact, lowering the T_m by 4.0°.     

Synthesis of Novel Heterobranched β-Cyclodextrins from α-D-Mannosyl- Maltotriose and β-Cyclodextrin by the Reverse Action of Pullulanase,and Isolation and Characterization of the Products

α-D-Mannosyl-maltotriose (Man-G3) were synthesized from methyl α-mannoside and maltotriose by the transfer action of α-mannosidase. (Man-G3)-βCD and (Man-G3)₂-βCD were produced in about 20% and 4% yield, respectively when Aerobacter aerogenes pullulanase (160 units per 1 g of Man-G3) was incubated with the mixture of 1.6 M Man-G3 and 0.16 M βCD at 50°C for 4 days. The reaction products, (Man-G3)-βCD were separated to three peaks by HPLC analysis on a YMC-PACK A-323-3 column and (Man-G3)₂-βCD were separated to several peaks by HPLC analysis on a Daisopak ODS column. The major product of (Man-G3)-βCDs was identified as 6-O-α-(6³-O-α-D-mannosyl-maltotriosyl)-βCD by FAB-MS and NMR spectroscopies. The structures of (Man-G3)₂-βCDs were analyzed by TOF-MS and NMR spectroscopies, and confirmed by comparison of elution profiles of their hydrolyzates by α-mannosidase and glucoamylase on a graphitized carbon column with those of the authentic di-glucosyl-βCDs. The structures of three main components of (Man-G3)₂-βCDs were identified as 6¹,6²-, 6¹,6³- and 6¹,6⁴-di-O-(6³-O-α-D-mannosyl-maltotriosyl)-βCD.     

Synthesis and hydrogenolysis of the methylene,ethylidene, isopropylidene,and diastereoisomeric 1-phenylethylidene acetals of β-l-arabino- and α-l-rhamnopyranoside derivatives

Both diastereoisomers of 1-phenylethylidene acetals (acetophenone acetals) of methyl and benzyl β-l-arabinopyranoside and α-l-rhamnopyranoside were prepared. Acetal-exchange reactions gave only the endo-phenyl isomers; their 2-O- and 4-O-acetyl derivatives were isomerised into the exo-phenyl compounds. ¹H-N.m.r. data were used to determine the absolute configuration at the acetal carbon atom in these compounds. The protons of the methyl group of the exo-phenyl isomers resonate at lower field than those of the endo-phenyl isomers. Hydrogenolysis of various methylene, ethylidene, and isopropylidene derivatives gave axial ethers. The endo-phenyl isomers of the acetophenone derivatives also gave axial 1-phenylethyl ethers in two diastereoisomeric forms. The exo-phenyl isomers of the arabinosides were stable towards the reagent (LiAlH₄AlCl₃), whereas the corresponding rhamnopyranosides gave the 2-(1-phenylethyl) ethers, but cleavage required prolonged reaction time and higher temperature.     

Differences between α- and β-Chain Mutants of Human Haemoglobin and between α- and β-Thalassaemia. Possible Duplication of the α-Chain Gene

Human adult haemoglobin consists of two unlike pairs of polypeptide chains, and can be described as α₂β₂. Amino-acid substitutions in either of the two types of chain result in α- and β-chain variants. In thalassaemia, which causes a lowered production of haemoglobin, the α or the β chain can be affected, the result being α- or β-thalassaemia. There is a quantitative difference in the proportion of α- and β-chain variants to normal haemoglobin in the respective heterozygotes, and there is also a difference in the pattern of inheritance of α- and β-thalassaemia: these could possibly be explained by assuming that man has one gene for the β- and two for the α-chain.