Inhibitors of sterol biosynthesis. Syntheses of 14α-alkyl substituted 15-oxygenated sterols

The chemical syntheses of a number of 14α-alkyl substituted 15-oxygenated sterols have been pursued to permit evaluation of their activity in the inhibition of the biosynthesis of cholesterol and other biological effects. Described herein are the first chemical syntheses of 14α-ethyl-5α-cholest-7-en-3β-ol-15-one, bis-3β,15α-acetoxy-14α-ethyl-5α-cholest-7-ene, 3β-acetoxy-14α-ethyl-5α-cholest-7-en-15β-ol, 14α-ethyl-5α-cholest-7-en-3β,15β-diol, 14α-ethyl-5α-cholest-7-en-3β,15α-diol, 3β-hexadecanoyloxy-14α-ethyl-5α-cholest-7-en-15α-ol, 3β-hexadecanoyloxy-14α-ethyl-5α-cholest-7-en-15β-ol, bis-3β,15α-hexadecanoyloxy-14α-ethyl-5α-cholest-7-ene, 3β-hexadecanoyloxy-14α-ethyl-5α-cholest-7-en-15-one, 3α-benzoyloxy-14α-ethyl-5α-cholest-7-en-15-one, 14α-ethyl-5α-cholest-7-en-3α-ol-15-one, 14α-ethyl-5α-cholest-7-en-15-on-3β-yl pyridinium sulfate, 14α-ethyl-5α-cholest-7-en-15-on-3β-yl potassium sulfate (monohydrate), 14α-ethyl-5α-cholest-7-en-15-on-3α-yl pyridinium sulfate, 14α-ethyl-5α-cholest-7-en-15-on-3α-yl potassium sulfate (monohydrate), 3β-ethoxy-14α-ethyl-5α-cholest-7-en-15-one, 3β-acetoxy-14α-n-propyl-5α-cholest-7-en-15-one, 14α-n-propyl-5α-cholest-7-en-3β-ol-15-one, bis-3β, 15α-acetoxy-14α-n-propyl-5α-cholest-7-ene, 3β-acetoxy-14α-n-propyl-5α-cholest-7-en-15β-ol, 14α-n-propyl-5α-cholest-7-en-3β, 15α-diol, 14α-n-propyl-5α-cholest-7-en-3β, 15β-diol, 14α-n-butyl-5α-cholest-7-en-3β-ol-15-one, 3β-acetoxy-14-α-n-butyl-5α-cholest-7-en-15-one, bis-3β,15α-acetoxy-14α-n-butyl-5α-cholest-7-ene, 3β-acetoxy-14α-n-butyl-5α-cholest-7-en-15β-ol, 14α-n-butyl-5β-cholest-7-en-3β, 15β-diol, and 14α-n-butyl-5α-cholest-7-en-3β, 15α-diol.     

Synthesis of a branched d-mannopentaoside and a branched d-mannohexaoside: Models of the outer chain of the glycan of soybean agglutinin

Synthetic routes are described to the d-mannopentaoside methyl 3-O-(3,6-di-O-α-d-mannopyranosyl-α-d-mannopyranosyl)-6-O-α-d-mannopyranosyl-α-d-mannopyranoside, and the d-mannohexaoside methyl 3-O-(3,6-di-O-α-d-mannopyranosyl-α-d-mannopyranosyl)-6-O-(2-O-α-d-mannopyranosyl-α-d-mannopyranosyl)-α- d-mannopyranoside, formed in a regio- and stereo-controlled way by employing the properly protected d-mannobioside methyl 2,4-di-O-benzyl-3-O-(2,4-di-O-benzyl-α-d-mannopyranosyl)-α-d-mannopyranoside and d-mannotrioside methyl 2,4-di-O-benzyl-3-O-(2,4-di-O-benzyl-α-d-mannopyranosyl)-6-O-(3,4,6-tri-O-benzyl-α-d- mannopyranosyl)-α-d-mannopyranoside as key intermediates.     

Revised structures of daturalactone and 12-oxowithanolide

Recently Dhar et al. reported the isolation of two new steroidal lactones from the leaves of Datura quercifolia HBK and formulated them as 5α,12α,17α-trihydroxy-1-oxo-6α, 7α-epoxy-22 S-witha-2,24-dienolide and 5α,17α-dihydroxy-1, 12-dioxo-6α,7α-epoxy-22 S-witha-2,24-dienolide on the basis of UV, IR, NMR and MS studies. Further detailed chemical and spectral studies have led to revised structures, namely 5α, 12α-dihydroxy-1-oxo-6α,7α: 24α, 25α-diepoxy-20 S, 22 R-with-2-enolide and 5α-hydroxy-1, 12-dioxo-6α, 7α: 24α, 25α-diepoxy-20 S, 22 R-with-2-enolide, respectively, for the above two compounds.     

Novel dinoflagellate 4α-methylated sterols from four caribbean gorgonians

Fourteen 4α-methyl sterols have been isolated from the gorgonians Briareum asbestinum, Gorgonia mariae, Muriceopsis flavida and Pseudoplexaura wagenaari, including the following five new sterols: 4α-methyl-24-methylene-5α-cholestan-3β-ol, (24R)-4α, 24-dimethyl-5α-cholesta-7,22-dien-3,β-ol, 4α,24S(or 23ξ)-dimethyl-5α-cholest-7-en-3β-ol, (22E, 24R)-4α,23,24-trimethyl-5α-cholesta-7,22-dien-3β-ol and (24R)-4α,24-dimethyl-5α-cholesta-8(14),22-dien-3β-ol. There is strong evidence that these 4α-methyl sterols are synthesized by the algal (dinoflagellate) symbionts (zooxanthellae) of the gorgonians. It is suggested that analysis of 4Δ-methyl sterol mixtures isolated from a zooxanthellae-bearing invertebrate, collected in several different geographic locations, might give information on the specificity of the symbiotic association between a given animal species and a particular strain of zooxanthellae.     

Mapping the extracellular topography of the α-chain in free and in membrane-bound acetylcholine receptor by antibodies against overlapping peptides spanning the entire extracellular parts of the chain

The extracellular surface of theα-chain ofTorpedo california acetylcholine receptor (AChR) was mapped for regions that are accessible to binding with antibodies against a panel of synthetic overlapping peptides which encompassed the entire extracellular parts of the chain. The binding of the antipeptide antibodies to membrane-bound AChR (mbAChR) and to isolated, soluble AChR. was determined. The specificity of each antiserum was narrowed down by determining the extent of its cross-reaction with the two adjacent peptides that overlap the immunizing peptide. With mbAChR, high antibody reactivity was obtained with antisera against peptidesα1–16,α89–104,α158–174,α262–276, andα388–408. Lower, but significant, levels of reactivity were obtained with antibodies against peptidesα67–82,α78–93,α100–115, andα111–126. On the other hand, free AChR bound high levels of antibodies against peptidesα34–49,α78–93,α134–150,α170–186, andα194–210. It also bound moderate levels of antibodies against peptidesα262–276 andα388–408. Low, yet significant, levels of binding were exhibited by antibodies against peptidesα45–60,α111–126, andα122–138. These binding studies, which enabled a comparison of the accessible regions in mbAChR and free AChR, revealed that the receptor undergoes considerable changes in conformation upon removal from the cell membrane. The exposed regions found here are discussed in relation to the functional sites of AChR (i.e., the acetylcholine binding site, the regions that are recognized by anti-AChR antibodies, T-cells and autoimmune responses and the regions that bind short and long neurotoxins).     

Evolutionary conservation of a testes-specific proteasome subunit gene in Drosophila

Proteasomes are large multisubunit particles that act as the proteolytic machinery for the ubiquitin-dependent proteolytic pathway. The core of this complex, the 20S proteasome, is made up of seven α-type and seven β-type subunits, arranged in an (α1–α7)(β1–β7)(β1–β7)(α1–α7) configuration. Previous work had shown that there exist alternative isoforms of the Drosophila melanogaster α4-type subunit, encoded by two distinct genes, α4t1_dm and α4t2_dm, and that these are expressed exclusively in the germline of the testes. We sought to investigate the evolutionary conservation of this phenomenon by screening for orthologs of the α4-type gene family in the distantly related Drosophila species, D. virilis. We isolated the D. virilis orthologs of the somatically expressed gene, α4_dm, and the testes-specific gene, α4t2_dm. We failed to find an ortholog of the other testes-specific gene, α4t1_dm. The α4_dv gene maps to the X chromosome at 12A-C, its product shares 90% amino acid identity with α4_dm, and it is expressed at high levels in both males and females. The other gene, α4t_dv, encodes a protein most similar to the testes-specific α4t2_dm proteasome subunit (59% a.a. identity), and it maps to position 27 on chomosome 2. The expression of the α4t_dv gene is testes-specific, like that of α4t2_dm. The existence of testes-specific α4-type subunits in two widely diverged subgenera of Drosophila suggests that these subunit isoforms have important functional roles in spermatogenesis.     

Synthesis of a model of an inner chain of cell-wall proteoheteroglycan isolated from Piricularia oryzae: Branched d-mannopentaosides

Efficient syntheses are described of the branched d-mannopentaosides methyl 2,6-di-O-(2-O-α-d-mannopyranosyl-α-d-mannopyranosyl)α-d-mannopyranoside and methyl 2,4-di-O-(2-O-α-d-mannopyranosyl-α-d-mannopyranosyl)-α-d-mannopyranoside, starting from the glycosyl acceptors methyl 3,4-di-O-benzyl-α-d-mannopyranoside and methyl 3,6-di-O-benzyl-α-d-mannopyranoside, and employing the protected d-mannotriosides methyl 3,4-di-O-benzyl-2,6-di-O-(3,4,6-tri-O-benzyl-α-d-mannopyranosyl)-α-d-mannopyranoside, and methyl 3,6-di-O-benzyl-2,4-di-O-(3,4,6-tri-O-benzyl-α-d-mannopyranosyl)-α-d-mannopyranoside as key intermediates.     

Control of yeast cell type by the mating type locus: II. Genetic interactions between MATα and unlinked α-specific STE genes

The alleles of the yeast mating type locus, MATα and MATa, determine the yeast cell types, a,α, and a/α. It has been proposed that the MATα2 product negatively regulates expression of unlinked a-specific genes, and that the MATα1 product positively regulates expression of unlinked α-specific genes. The behavior of mutants defective in MATα2, which are deficient in mating and in production of α-factor, can thus be attributed to antagonism between a-specific and α-specific functions expressed simultaneously in matα2^? strains. If this view is correct, then elimination by mutation of the specific functions required to mate as α may allow matα2 mutants to mate as a. In order to test this possibility, we examined the interactions between matα2 mutations and various unlinked mutations that cause α cells but not a cells to be mating defective (α-specific STE mutations). Three α-specific mutations (ste3, ste13 and kex2) were found to be non-allelic. Furthermore, although matα2 mutants mate weakly as a, matα2, ste3 double mutants, but not matα2 ste13 or matα2 kex2 double mutants, mate efficiently as a. The ability of matα2 ste3 strains to mate as a supports the view that matα2 mutants express a-specific mating functions, and suggests that a mating functions are expressed constitutively in MATa cells. The mating behaviour of the matα2 ste3 double mutant is consistent with the proposal that STE3 is positively regulated by the MATα1 product.     

Jack bean α-mannosidase digestion profile of hybrid-type N-glycans: effect of reaction pH on substrate preference

Jack bean α-mannosidase (JBM) is a well-studied plant vacuolar α-mannosidase, and is widely used as a tool for the enzymatic analysis of sugar chains of glycoproteins. In this study, the JBM digestion profile of hybrid-type N-glycans was examined using pyridylamino (PA-) sugar chains. The digestion efficiencies of the PA-labeled hybrid-type N-glycans Manα1,6(Manα1,3)Manα1,6(GlcNAcβ1,2Manα1,3)Manβ1,4GlcNAcβ1,4GlcNAc-PA (GNM5-PA) and Manα1,6(Manα1,3)Manα1,6(Galβ1,4GlcNAcβ1,2Manα1,3)Manβ1,4GlcNAcβ1,4GlcNAc-PA (GalGNM5-PA) were significantly lower than that of the oligomannose-type N-glycan Manα1,6(Manα1,3)Manα1,6Manβ1,4GlcNAcβ1,4GlcNAc-PA (M4-PA), and the trimming pathways of GNM5-PA and GalGNM5-PA were different from that of M4-PA, suggesting a steric hindrance to the JBM activity caused by GlcNAcβ1-2Man(α) residues of the hybrid-type N-glycans. We also found that the substrate preference of JBM for the terminal Manα1-6Man(α) and Manα1-3Man(α) linkages in the hybrid-type N-glycans was altered by the change in reaction pH, suggesting a pH-dependent change in the enzyme-substrate interaction.     

Control of yeast cell type by the mating type locus: I. Identification and control of expression of the a-specific gene BAR1

The MATα allele of the yeast mating type locus confers the α mating phenotype and contains two complementation groups, MATα1 and MATα2. The α1–α2 hypothesis proposes that MATα1 is a positive regulator of α-specific genes and that MATα2 is a negative regulator of a-specific genes. According to this hypothesis, matα2 mutants, which are defective in mating and in production of extracellular α-factor, express both a-specific functions (because they lack MATα2 product) and α-specific functions (because they contain MATα1 product). Failure to produce extracellular α-factor results from antagonism between these functions; in particular, because α-factor (an α-specific function) is degraded by an a-specific function. If this view is correct, matα2 mutants should acquire the ability to produce α-factor if they also carry a defect in the gene(s) responsible for α-factor degradation. We have isolated a derivative of a matα2 mutant that produces α-factor and have characterized the suppressor mutation in this strain. (1) This strain carries a mutation (bar1-1) tightly linked to HIS6 (on chromosome IX) that allows matα2 mutants to produce α-factor. (2) It does not allow matα1 mutants to produce α-factor. (3) Haploids of the a mating type bearing the bar1-1 mutation still mate, but are unable to act as a barrier to the diffusion of α-factor. MATa bar1-1 cells display increased sensitivity to α-factor. (4) A mutation (sst1?2) that causes increased sensitivity to α-factor is allelic to bar1-1 and also allows α-factor synthesis by matα2 mutants. The ability of matα2 bar1 double mutants to produce extracellular α-factor indicates that matα2 mutants do produce α-factor but that it is degraded by the Barrier function. These results suggest that BAR1 is normally expressed only in a cells, and is negatively regulated in α cells by the MATα2 product.     

Brassinosteroids and sterols from a green alga,Hydrodictyon reticulatum: Configuration at C-24

Two brassinosteroids, (24S)-24-ethylbrassinone [(22R,23R,24S)-2α,3α,22,23-tetrahydroxy-24-ethyl-5α-cholestan-6-one] and 24-epicastasterone [(22R,23R,24R)-2α,3α,22,23-tetrahydroxy-24-methyl-5α-cholestan-6-one] have been identified from Hydrodictyon reticulatum. Examination of the sterols of this alga has established that 24-ethylcholesterol is predominantly the 24α-epimer, but 24-methylcholesterol is a mixture of the 24α- and 24β-epimers. Thus, similarity with respect to the C-24 configuration was observed between the brassinosteroids and 4-demethylsterols.     

The synthesis of 6-deoxy-6-fluoro-α,α-trehalose and related analogues

Selective acid-catalysed methanolysis of 2,3,2′,3′-tetra-O-benzyl-4,6:4′,6′-di-O-benzylidene-α,α-trehalose yielded the monobenzylidene derivative, which was converted into the 4,6-dimesylate. Selective nucleophilic displacement of the primary sulphonyloxy group then gave 2,3-di-O-benzyl-6-deoxy-6-fluoro-4-O-mesyl-α-d-glucopyranosyl 2,3-di-O-benzyl-4,6-O-benzylidene-α-d-glucopyranoside. Removal of the protecting groups then yielded 6-deoxy-6-fluoro-α,α-trehalose. In addition, 6-deoxy-6-fluoro-4-O-mesyl-α,α-trehalose and a derivative of 4-chloro-4,6-dideoxy-6-fluoro-α-d-galactopyranosyl α-d-glucopyranoside were also prepared from the same substrate. Iodide displacement of 2,3-di-O-benzyl-4,6-di-O-mesyl-α-d-glucopyranosyl 2,3-di-O-benzyl-4,6-di-O-mesyl-α-d-glucopyranoside afforded the 6-iodide and 6,6′-di-iodide in yields of 31 and 36%, respectively. Similarly, the 6-azide and 6,6′-diazide were isolated in yields of 17 and 21%, respectively.     

Ten cis-clerodane-type diterpene lactones from Gutierrezia texana

Ten new 5α,10α-cis-clerodane-type diterpene lactones were isolated from the aerial parts of Gutierrezia texana. Using NMR techniques and some chemical transformations, the structures were established as 6α,18-dihydroxy-cis-cleroda-3,13(14)-diene-15,16-olide; 18,19-dihydroxy-cis-cleroda-3,13(14)-diene-15,16-olide; cis-cleroda-3,13(14)-diene-15,16:18,19-diolide; 18,19-epoxy-19α-hydroxy-cis-cleroda-3,13(14)-diene-15,16-olide; 3α,4:18,19-diepoxy-18β,19α-dihydroxy-cis-cleroda-13(14)-ene-15,16-olide; 3α,4-epoxy-19α-hydroxy-cis-cleroda-13(14)-ene-15,16:18,19-diolide; 3α,4:18,19-diepoxy-19α-hydroxy-cis-cleroda-13(14)-ene-15,16-olide; 3α,4β,19α-trihydroxy-18,19-epoxy-cis-cleroda- 13(14)-ene-15,16-olide; 19-O-α-L-arabinopyranosyl-cis-cleroda-3,3,13(14)-diene-15,16-olide-19-oic ester and 2β,6α-dihydroxy-cis-cleroda-3,13(14)-diene-15,16:18,6α-diolide. One of the structures was also confirmed by X-ray crystallographic analysis.     

Diterpenoids from Nepeta tuberosa subsp. reticulata

Three new diterpene compounds have been isolated from Nepeta tuberosa subsp. reticulata and their structures elucidated by spectroscopic methods. They were identified as diisopimaryl malonate isopimarylmalonic acid and 7-oxo-isopimara-8,15-dien-18-ol. We have also isolated 4aα,7α,7aβ-nepetalactone, 4aα,7α,7aα-nepetalactone, 3α-hydroxy-4α,4aα,7α 4α,4aα,7α,7aα-dihydronepetalactone, isopimaryl acetate, isopimarol, isopimaric acid, 8(14),15-isopimaradien-7α,18-diol, myrceocomunic acid and α-tocopheryl quinone.     

Triterpenes from Douglas fir sapwood

The saponified ether-soluble extractives of Douglas fir sapwood contained (24R)- 4α,14α,24-trimethyl-9β,19-cyclo-5α-cholestan-3β-ol(24R-cyclocucalanol),a new natural product; 4α,14α-dimethyl-9β,19-cyclo-24-methylene-5α-cholestan-3β- ol (cycloeucalenol); and (24R)-4α,24-dimethyl-5α-cholest-7-en-3β-ol (24R- methyllophenol); this is the first time they have been reported from Douglas fir.     

Chemical syntheses of 5α-cholesta-6,8(14)-dien-3β-ol-15-one and related 15-oxygenated sterols

Hydroboration of 5α-cholesta-8,14-dien-3β-ol (I) gave 5α-cholest-8-en-3β,15α-diol (IV) in 89% yield. 5α-Cholest-7-en-3β,15α-diol (V) was prepared in 91% yield by hydroboration of 5α-cholesta-7,14-dien-3β-ol (II). Hydroboration of 27:63 mixture of I and II gave IV and V in 18% and 70% yields, respectively. 5α-Cholest-8-en-15α-ol-3-one and 5α-cholest-7-en-15α-ol-3-one were prepared in high yields from IV and V, respectively, by either selective oxidation with silver carbonate-celite or by enzymatic oxidation using cholesterol oxidase. 7α,8α-Epoxy-5α-cholestan-3β,15α-diol (VIII) was prepared in 93% yield by treatment of V with m-chloroperbenzoic acid. 5α-Cholest-8(14)-en-7α-ol-3,15-dione (IX) was prepared in 56% yield by oxidation of VIII with pyridinium chlorochromate followed by treatment of the crude product with acid. Compound IX was also obtained in 72% yield by selective chemical oxidation of 5α-cholest-8(14)-en-3β,7α,15α-triol. 5α-Cholesta-6,8(14)-dien-3,15-dione (X) was prepared in 89% yield by treatment of IX with p-toluenesulfonic acid under controlled conditions. Reduction of X with lithium tri-tert-butoxyaluminum hydride under controlled conditions gave 5α-cholesta-6,8(14)-dien-3β-ol-15-one in 84% yield.     

Synthesis of a branched d-mannopentaoside and a branched d-mannohexaoside: Models of the inner core of cell-wall glycoproteins of Saccharomyces cerevisiae

Synthetic routes are discussed to the branched d-mannopentaoside methyl 6-O-(2,6-di-O-α-d-mannopyranosyl-α-d-mannopyranosyl)-3-O-α-d-mannopyranosyl-α-d-mannopyranoside and d-mannohexaoside methyl 6-O-(2,6-di-O-α-d-mannopyranosyl-α-d-mannopyranosyl)-3-O-(2-O-α-d-mannopyranosyl-α-d-mannopyranosyl)- α-d-mannopyranoside, employing the properly benzylated d-mannobioside methyl 2,4-di-O-benzyl-6-O-(3,4-di-O-benzyl-α-d-mannopyranosyl)-α-d-mannopyranoside and d-mannotrioside methyl 2,4-di-O-benzyl-6-O-(3,4-di-O-benzyl-α-d-mannopyranosyl)-3-O-(3,4,6-tri-O-benzyl-α-d-mannopyranosyl)-α-d- mannopyranoside as key intermediates.     

3′,6′-anhydro-6-O-corynomycoloyl trehalose: Synthesis and identification as the impurity in synthetic cord factor preparations

Acylation of 2,3,4,2′,3′,4′-hexa-O-benzyl-6,6′-di-O-methanesulphonyl-α-α-trehalose (1) with a reduced amount of potassium corynomycolate yielded a mixture which consisted mainly of 2,3,4,2′,3′,4′-hexa-O-benzyl-6-O-corynomycoloyl-6′-O-methanesulphonyl-α,α-trehalose (2). Catalytic hydrogenolysis of 2 gave the mono-mesylate 4 which was converted into 3′,6′-anhydro-6-O-corynomycoloyl-α,α-trehalose (5) but treatment with sodium hydride. The structure of 5 was studied by mass-spectroscopy. Compound 5 was found to be identical with the byproduct obtained in the acylation of 6,6′-di-O-p-toluenesulphonyl-α,α-trehalose with potassium corynomycolate.     

Cytotoxic lignans from Podophyllum, and the nomenclature of aryltetralin lignans

Roots of Podophyllum hexandrum and P. peltatum both contain (1R,2R,3R)-desoxypodophyllotoxin [(1α,2α,3β)- desoxypodophyllotoxin] and the previously unreported (1R,2R,3R)-podophyllotoxone [(1α,2α,3α)-podophyllotoxone]. Thermal isomerization of (loc,2ct,3fl)-podophyllotoxone readily occurs to yield (1α,2α,3α)-podophyllotoxone (isopicropodophyllone) with traces of (1α,2β,3β)-podophyllotoxone (picropodophyllone). Small amounts of (1α,2α,3α)-podophyllotoxone were also present in dried roots of P. hexandrum and P. peltatum. A more systematic nomenclature for podophyllotoxin derivatives and other aryltetralin lignans using α,β conventions is proposed.