A cottonseed oil-enriched diet improves liver and plasma lipid levels in a male mouse model of fatty liver.

A high-fat (HF) diet causes fatty liver, hyperlipidemia, and hypercholesterolemia, and cottonseed oil (CSO) has been shown to improve liver and plasma lipids in human and mouse models. The purpose of this study was to determine the effect of CSO vs. olive oil (OO)-enriched diets on lipid levels in a HF-diet model of fatty liver disease. We placed mice on a HF diet to induce obesity and fatty liver, after which mice were placed on CSO or OO diets, with chow and HF (5.1 kcal/g) groups as control. When CSO- and OO-fed mice were given isocaloric diets with the HF group, there were no differences in body weight, plasma, or hepatic lipids. However, when the CSO and OO diets were reduced in calories (4.0 kcal/g), CSO and OO groups reduced body weight. The CSO group had lower plasma total cholesterol (-56 ± 6%, P < 0.01), free cholesterol (-53 ± 7%, P < 0.01), triglycerides (-61 ± 14%, P < 0.01), and LDL (-42 ± 16%, P = 0.01) vs. HF group whereas the OO diet lowered LDL (-18 ± 12%, P = 0.05) vs. HF. Furthermore, the CSO diet decreased hepatic total cholesterol (-40 ± 12%, P < 0.01), free cholesterol (-23 ± 11%, P = 0.04), and triglycerides (-47 ± 12%, P = 0.02). There were no significant changes in lipogenesis and fatty acid oxidation among the groups. However, the CSO group increased lipid oxidative gene expression in liver and dihydrosterculic acid increased PPARα target genes with in vitro models. Taken together, consuming a reduced calorie diet enriched in CSO reduces liver and plasma lipid profiles in an obese model of fatty liver.

Production of tocotrienols in seeds of cotton (Gossypium hirsutum L.) enhances oxidative stability and offers nutraceutical potential.

Upland cotton (Gossypium hirsutum L.) is an economically important multi-purpose crop cultivated globally for fibre, seed oil and protein. Cottonseed oil also is naturally rich in vitamin E components (collectively known as tocochromanols), with α- and γ-tocopherols comprising nearly all of the vitamin E components. By contrast, cottonseeds have little or no tocotrienols, tocochromanols with a wide range of health benefits. Here, we generated transgenic cotton lines expressing the barley (Hordeum vulgare) homogentisate geranylgeranyl transferase coding sequence under the control of the Brassica napus seed-specific promoter, napin. Transgenic cottonseeds had ~twofold to threefold increases in the accumulation of total vitamin E (tocopherols + tocotrienols), with more than 60% γ-tocotrienol. Matrix assisted laser desorption ionization-mass spectrometry imaging showed that γ-tocotrienol was localized throughout the transgenic embryos. In contrast, the native tocopherols were distributed unequally in both transgenic and non-transgenic embryos. α- Tocopherol was restricted mostly to cotyledon tissues and γ-tocopherol was more enriched in the embryonic axis tissues. Production of tocotrienols in cotton embryos had no negative impact on plant performance or yield of other important seed constituents including fibre, oil and protein. Advanced generations of two transgenic events were field grown, and extracts of transgenic seeds showed increased antioxidant activity relative to extracts from non-transgenic seeds. Furthermore, refined cottonseed oil from the two transgenic events showed 30% improvement in oxidative stability relative to the non-transgenic cottonseed oil. Taken together, these materials may provide new opportunities for cottonseed co-products with enhanced vitamin E profile for improved shelf life and nutrition.

Di(phenylpropylamino)gossypol: a derivative of the dimeric natural product gossypol.

Di(phenylpropylamino)gossypol [systematic name: 2,2'-bis{1,6-dihydroxy-5-isopropyl-8-[(3-phenylpropylamino)methylidene]naphthalen-7-one}, C48H52N2O6, was formed by reaction of the dimeric natural product gossypol with 3-phenylpropylamine. The structure of this compound has its two naphthalene ring systems oriented approximately perpendicular to each other, and the two pendant phenylpropyl groups have different conformations. One of these side groups is considerably disordered at room temperature but less so at 120 K. The enantiomeric molecules form centrosymmetric dimers that are supported by intermolecular hydrogen bonds and by hydrophobic interactions between a pair of naphthalene rings. Two additional hydrogen bonds tie the dimer pairs into layers. Unlike gossypol and many gossypol Schiff base derivatives, the title compound crystallizes without the inclusion of solvent, which appears to occur because of the size and flexibility of its phenylpropyl pendent groups.

6,6'-Dimethoxygossypolone.

6,6'-Dimethoxygossypolone (systematic name: 7,7'-dihydroxy-5,5'-diisopropyl-6,6'-dimethoxy-3,3'-dimethyl-1,1',4,4'-tetraoxo-2,2'-binaphthalene-8,8'-dicarbaldehyde), C(32)H(30)O(10), is a dimeric molecule formed by oxidation of 6,6'-dimethoxygossypol. When crystallized from acetone, 6,6'-dimethoxygossypolone has monoclinic (P2(1)/c) symmetry, and there are two molecules within the asymmetric unit. Of the four independent quinoid rings, three display flattened boat conformations and one displays a flattened chair/half-chair conformation. The angles between the planes of the two bridged naphthoquinone structures are fairly acute, with values of about 68 and 69°. The structure has several intramolecular O-H...O and C-H...O hydrogen bonds and several weak intermolecular C-H...O hydrogen bonds, but no intermolecular O-H...O hydrogen bonds.

(-)-Gossypol reduces invasiveness in metastatic prostate cancer cells.

BACKGROUND: Acquisition of metastatic ability by prostatic cancer cells is the most lethal aspect of prostatic cancer progression. (-)-Gossypol, a polyphenolic compound present in cottonseeds, possesses anti-proliferative and proapoptotic effects in various cancer cells. MATERIALS AND METHODS: In this study, the differences between MAT-LyLu, rat prostate cancer cells, with a novel isolated subline from metastasized tumors in the lungs of MAT-LyLu-bearing Copenhagen rats (MLL cells) were compared with respect to cell growth and invasion. The effects of (-)-gossypol on cell viability, colony formation, invasive ability and cell migration in MAT-LyLu and MLL cells were also evaluated. RESULTS: Results showed that MLL cells displayed higher growth ability, colony formation and aggressive penetration than those of MAT-LyLu cells. MLL cells possess lower protein expression of Bcl-xL and nm23-H1 than those of MAT-LyLu cells, implying differences in invasive ability. Moreover, (-)-gossypol treatment induced a dose-dependent inhibition of invasive activity and cell viability and reduced Bcl-2 and Bcl-xL proteins but induced nm23-H1 protein in both cell lines. CONCLUSION: These findings illustrated that (-)-gossypol reduced in vitro invasion of both the parental MAT-LyLu cells and the isolated MLL cells, suggesting that (-)-gossypol might serve as a chemotherapeutic and/or chemopreventive agent.

HPLC preparation of the chiral forms of 6-methoxy-gossypol and 6,6'-dimethoxy-gossypol.

A concentrated mixture of gossypol, 6-methoxy-gossypol, and 6,6'-dimethoxy-gossypol was extracted from the root bark of St. Vincent Sea Island cotton with acetone. This extract was derivatized with R-(-)-2-amino-1-propanol to form diastereomeric gossypol Schiff's bases. Analytical-scale reverse-phase chromatography of these Schiff's bases produced six peaks, indicating separation of the enantiomeric forms of the three gossypol compounds. The elution order of the peaks was found to vary with the polarity of the mobile phase. The chromatography was scaled to a preparative level and was used to isolate each compound. After hydrolysis of the separated Schiff's bases, the original compounds were recovered by precipitation from solutions of diethyl ether, acetic acid, and water. Fifty injections yielded approximately 500 mg of each methoxy-gossypol enantiomer and 300 mg of each dimethoxy-gossypol enantiomer. Each compound was characterized for carbon and hydrogen content, optical rotation, UV-vis light absorption, and melting point. Standard curves were developed and were used to measure the concentration of each gossypol form in the root bark and dehulled seed of St. Vincent Sea Island cotton. In seed tissue, 48% of the gossypol compounds were methylated, and the (-)-optical form was found to be in a slight excess to the (+)-optical form (53-54%) for all three compounds. In root bark, 71% of the gossypol compounds were methylated, and the (+)-optical form was in excess to the (-)-optical form for all three compounds. However, in this tissue the extent of enantiomeric excess decreased with the degree of methylation, with 77% of the gossypol existing in the (+)-optical form and 59% of the 6,6'-dimethoxy-gossypol existing in the (+)-optical form.

Effect of racemic, (+)- and (-)-gossypol on survival and development of Heliothis virescens larvae.

Gossypol is a constituent of the lysigenous foliar glands of cotton plants and is also found in glands in cottonseed. Gossypol exists as enantiomers because of restricted rotation around the binaphthyl bond. The biological activities of the enantiomers differ. For example, (+)-gossypol can be fed safely to nonruminants such as chickens, but (-)-gossypol cannot. Most commercial cottonseed contain a (+)- to (-)-gossypol ratio of approximately 3:2. Conventional breeding techniques can be used to develop cottonseed that contains >95% (+)-gossypol. Notably, gossypol protects the plant from insect herbivores. Herein, we report the effect of various forms of gossypol on Heliothis virescens (Fabricius) larvae. Three levels (0.16, 0.24, and 0.32%) of racemic, (+)-, and (-)-gossypol were added to artificial rearing diets and were fed to H. virescens larvae. All 0.24 and 0.32% gossypol diets significantly lengthened days-to-pupation and decreased pupal weight compared with the control. Percent survival was significantly less for larvae reared on diets containing 0.24% of all three forms of gossypol as compared with the control diet. (+)-Gossypol was superior or equivalent to racemic gossypol as measured by the three parameters studied. Higher concentrations of all gossypol forms were required to reduce survival and pupal weights and increase days-to-pupation for larvae of H. virescens larvae compared with the concentration needed to affect larvae of Helicoverpa zea (Boddie), which was studied previously. These results indicate that current efforts to breed cotton lines containing mostly (+)-gossypol in seed should not significantly impair the plant's natural defenses against insects.

Gossypol inhibits calcineurin phosphatase activity at multiple sites.

Calcineurin, the Ca2+/calmodulin-dependant serine/threonine phosphatase is the target for the immunosuppressant drugs FK506 and cyclosporine-A. These established calcineurin inhibitors each require an immunophilin protein cofactor. Gossypol, a polyphenol produced by the cotton plant, inhibits calcineurin (IC50=15 microM), in a noncompetitive, reversible manner, and is independent of any cofactor. We found that gossypol acts by at least two mechanisms to inhibit calcineurin phosphatase activity. A calmodulin-independent form of calcineurin was less sensitive to inhibition by gossypol than native calcineurin (IC50=41 and 18 microM, respectively) indicating that gossypol may interfere with calmodulin binding. A fluorescence polarization based assay demonstrated that 100 microM gossypol reduced the affinity of calmodulin for calcineurin (from K(d)=2.4 to 250 nM). Inhibition of calcineurin phosphatase activity by gossypol could not be overcome by adding excess calmodulin or by testing the inhibition toward a calmodulin-independent calcineurin indicating that gossypol acts at a site different from the calmodulin-binding site. Gossypol decreased the affinity of calcineurin for immunosuppressant/immunophilin complexes only in the presence of calmodulin, indicating that gossypol blocks the effects of calmodulin binding to calcineurin. In addition, gossypol had a stimulatory effect on native calcineurin in the absence of calmodulin, possibly indicating a calmodulin mimetic effect. Gossypol exists in two enantiomeric forms which are reported to have different potency for cell toxicity. (+) and (-) gossypol had equivalent potency for inhibition of native and calmodulin-independent calcineurin phosphatase activity, and for inhibition of calmodulin binding. The inhibition of calcineurin by gossypol via multiple binding sites without stereo-specificity indicates that gossypol is not a specific calcineurin inhibitor.

Modulation of multidrug resistance gene expression in human breast cancer cells by (-)-gossypol-enriched cottonseed oil.

BACKGROUND: Multidrug resistance (MDR) is a major impediment to successful cancer chemotherapy. P-glycoprotein (P-gp), the product of the multidrug resistance 1 (MDR1) gene, acts as an efflux pump and prevents sufficient intracellular accumulation of several anticancer agents, thus, playing a major role in MDR. Tamoxifen (Tam), ICI 182 780 (ICI) and Adriamycin (Adr) alone or with (-)-gossypol-enriched cottonseed oil [(-)-GPCSO] possible effects on cell growth inhibition and regulation of MDR1, mRNA and P-gp expression were examined in both an MDR human breast cancer cell line, MCF-7/Adr cells, and primary cultured human breast cancer epithelial cells (PCHBCEC). MATERIALS AND METHODS: Cells were treated with 0.05% of (-)-GPCSO either in the absence or presence of either 0.1 microM Tam, ICI or Adr for 24 h. RESULTS: Using the non-radioactive cell proliferation MTS assay, none of these chemotherapeutic agents alone inhibited MCF-7/Adr cell and PCHBCEC proliferation; meanwhile, the combination of 0.1 microM Tam, ICI or Adr with 0.05% (-)-GPCSO significantly reduced MCF-7/Adr cell growth by approximately 34%, 32% and 23%, respectively, of that of the vehicle-treated cells. For PCHBCEC, the combination of 0.05% (-)-GPCSO with 0.1 microM of Tam, ICI and Adr reduced cell growth to about 94%, 90%, and 71% respectively, of the vehicle treated PCHBCEC. Furthermore, (-)-GPCSO inhibited MDR1/P-gp expression in both MCF- 7/Adr and PCHBCEC in a dose-dependent manner. Our results provide insight into the MDR-reversing potential of (-)-GPCSO in human breast cancer cells resistant to current chemotherapeutic agents.

Dihydrosterculic acid from cottonseed oil suppresses desaturase activity and improves liver metabolomic profiles of high-fat-fed mice.

Polyunsaturated fatty acid (PUFA)-rich diets are thought to provide beneficial effects toward metabolic health in part through their bioactive properties. We hypothesized that increasing PUFA intake in mice would increase peroxisome proliferator activated receptor delta (PPARδ) expression and activity, and we sought to examine the effect of different PUFA-enriched oils on muscle PPARδ expression. One of the oils we tested was cottonseed oil (CSO) which is primarily linoleic acid (53%) and palmitic acid (24%). Mice fed a CSO-enriched diet (50% energy from fat) displayed no change in muscle PPARδ expression; however, in the liver, it was consistently elevated along with its transcriptional coactivator Pgc-1. Male mice were fed chow or CSO-, saturated fat (SFA)-, or linoleic acid (18:2)-enriched diets that were matched for macronutrient content for 4 weeks. There were no differences in food intake, body weight, fasting glucose, glucose tolerance, or energy expenditure between chow- and CSO-fed mice, whereas SFA-fed mice had increased fat mass and 18:2-fed mice were less glucose tolerant. Metabolomic analyses revealed that the livers of CSO-fed mice closely matched those of chow-fed but significantly differed from SFA- and 18:2-enriched groups. Fatty acid composition of the diets and livers revealed an impairment in desaturase activity and the presence of dihydrosterculic acid (DHSA) in the CSO-fed mice. The effect of DHSA on PPARδ and stearoyl-CoA desaturase-1 expression mimicked that of the CSO-fed mice. Taken together, these data suggest that DHSA from CSO may be an effective means to increase PPARδ expression with concomitant suppression of liver stearoyl-CoA desaturase-1 activity.

Effects of serum on (-)-gossypol-suppressed growth in human prostate cancer cells.

BACKGROUND: Gossypol, a natural polyphenolic compound present in cottonseeds, possesses antiproliferative and pro-apoptotic effects in in vivo and in vitro models. There are two enantiomers, (+)-gossypol and (-)-gossypol, the latter being a more potent inhibitor of cancer cell growth. Here, the effect of bovine serum albumin (BSA) and dextran-coated charcoal-treated fetal bovine serum (DCC-FBS)-containing medium on the ability of (-)-gossypol to inhibit the growth of human prostate cancer cells was studied. MATERIALS AND METHODS: BSA- and DCC-FBS-supplemented medium were used to examine the influence of serum proteins on the antiproliferative effects of (-)-gossypol in DU-145 cells, a human prostate cancer cell line. The viability of the DU-145 cells was determined by CellTiter 96 Aqueous assay. The expressions of mRNA and protein for the cell cycle regulators, cyclin-D1, Rb, CDK, p21 and TGF-beta, were determined by RT-PCR and Western blot analyses, respectively. RESULTS: (-)-Gossypol caused growth suppression of the DU-145 cells. In comparison with BSA-supplemented medium, DCC-FBS blocked the antiproliferative effects of (-)-gossypol at 1 and 2.5 microM, but not at 5 microM. Furthermore, (-)-gossypol treatment down-regulated cyclin-D1, Rb, CDK4 and CDK6, and up-regulated p21 and TGF-beta1 at the mRNA and/or protein levels. CONCLUSION: The data suggested that (-)-gossypol-suppressed prostate cancer cell growth may be influenced through cell cycle regulators, which may lead to better prognosis. We further speculate that (-)-gossypol might serve as a chemotherapeutic agent for human prostate cancer patients.

Molecular mechanisms of (-)-gossypol-induced apoptosis in human prostate cancer cells.

BACKGROUND: Gossypol, a natural compound present in cottonseeds, displays antiproliferative and pro-apoptotic effects against various cancer cells. The (-)-gossypol enantiomer is a more potent inhibitor of cancer cell growth. Here, the molecular mechanisms of apoptosis induced by (-)-gossypol were studied in human prostate cancer cells. MATERIALS AND METHODS: After the prostate cancer cell DU-145 had been treated with (-)-gossypol, the trypan blue exclusion assay and DNA fragment end-labeling assay were used to stain the dead cells and to detect DNA laddering, respectively. The effects of (-)-gossypol on the expression of apoptotic-regulated gene markers in both death receptor- and mitochondria-mediated apoptotic pathways, such as the Bcl-2 family and caspase, etc., were detected by RT-PCR and Western blot analysis. To further investigate the apoptotic pathways induced by (-)-gossypol, different caspase inhibitors were used to block caspase activities and cell viability was detected by the CellTiter 96 AQueous assay in DU-145 cells. RESULTS: At a 5-10 microM dose-level, (-)-gossypol significantly enhanced apoptosis measured by DNA fragmentation. (-)-Gossypol caused apoptosis in DU-145 cells through the down-regulation of Bcl-2 and Bcl-xL and the up-regulation of Bax at the mRNA and protein levels. (-)-Gossypol also activated caspases-3, -8 and -9 and increased PARP [poly (ADP-ribose) polymerase] cleavage. Furthermore, (-)-gossypol-induced apoptosis might be due to an increase in CAD (caspase-activated deoxyribonuclease) proteins and a decrease in ICAD (inhibitor of CAD) proteins. By using caspase inhibitors, (-)-gossypol caused apoptosis via the caspase-dependent pathways. CONCLUSION: Our results indicated that the apoptotic processes caused by (-)-gossypol are mediated by the regulation of the Bcl-2 and caspase families in human prostate cancer cells. Our data also suggested that (-)-gossypol may have chemotheraputic benefits for prostate cancer patients.

Isolation of 6-methoxy gossypol and 6,6'-dimethoxy gossypol from Gossypium barbadense Sea Island cotton.

6-methoxy gossypol and 6,6'-dimethoxy gossypol were isolated from the seeds and root bark of a St. Vincent Sea Island variety of cotton (AZK-267, GRIN# PI 528406). Crude mixtures of gossypol and the methoxy compounds were obtained by extraction of the tissue with acetone and precipitation with acetic acid. After recrystallization, the preparations were treated with 3-amino-1-propanol to form gossypol Schiff's bases, which were separated by preparative reverse phase chromatography. The separated Schiff's bases were then hydrolyzed with acid, extracted into diethyl ether, concentrated, and precipitated with acetic acid. From the above procedure, both methoxy gossypol compounds were obtained as 1:1 molar acetic acid solvates. Each compound was prepared in sufficient amounts to determine its physical properties and begin testing for bioactivity. Light absorbance differed significantly for the di-3-amino-1-propanol derivatives of gossypol and the methoxy gossypol compounds at 254 nm. Relative response factors were developed, which can be used for determining or correcting analytical measurements of these methylated gossypol forms.

Substrate utilization by Aspergillus flavus in inoculated whole corn kernels and isolated tissues.

Utilization of the major corn (Zea mays) reserve materials (free saccharides, starch, triglycerides, and zein) was monitored during infection of detached kernels by Aspergillus flavus (A. flavus) over a 12-day period. Inoculated whole kernels were compared to noninoculated kernels. Concentrations of sucrose and raffinose in inoculated seed decreased to nearly zero at 6 days, whereas concentrations of these saccharides in noninoculated seed dropped at a considerably slower rate, and significant levels remained at the end of the incubation period. Triglyceride concentrations remained unchanged in the noninoculated seed but dropped continuously after 2 days in the inoculated seed. Starch and zein concentrations did not change during the 12-day incubation period. Aflatoxin B1 was first detected after 2 days and increased to about 20 microg/g (20,000 ppb) after 12 days. Very low aflatoxin concentrations were detected in the noninoculated seed. Significant concentrations of erythritol, arabitol, and mannitol were produced during infection, with peak concentrations occurring at 8 days. Whole seed and germ tissue appeared to support good fungal growth and aflatoxin production, whereas ground tissues and endosperm did not. A. flavus preferentially utilized saccharides as initial carbon substrates followed by triglycerides. When invading nonwounded corn kernels, the fungus selectively targets the germ tissue where these materials are localized in the highest concentrations.

The (-)-enantiomer of gossypol possesses higher anticancer potency than racemic gossypol in human breast cancer.

Natural gossypol (GP), a polyphenolic pigment in cottonseed, is a racemic mixture of two enantiomers, (+)GP and (-)GP. Our aim was to compare the abilities of (+/-)GP, (+)GP and (-)GP to reduce proliferation of breast cancerous epithelial cells (cEC) and cancerous stromal cells (cSC). Proliferation was measured by 3H-thymidine uptake. Results showed that (+)GP had no effect on both cEC and cSC. In contrast, in both cell types, (+/-)GP and (-)GP significantly inhibited proliferation. (+/-)GP caused reductions of 15, 46 and 82% at 25, 5.0 and 7.5 microM, respectively, in cEC, and reductions of 17, 28, 39 and 56% at 2.0, 3.0, 4.0 and 5.0 microM, respectively, in cSC. (-)GP induced reductions of 33, 89 and 98% at 2.5, 5.0 and 7.5 microM, respectively, in cEC, and reductions of 29, 51, 64 and 72% at 2.0, 3.0, 4.0 and 5.0 microM, respectively, in cSC. By RT-PCR, we found that 3 microM of (+/-)GP and (-)GP decreased cyclin D1 mRNA expression in both cell types (52% and 71%, respectively, in cEC; and 47% and 71%, respectively, in cSC), and increased transforming growth factor beta (TGFbeta) mRNA expression in both cell types (93% and 130%, respectively, in cEC; and 45% and 89%, respectively, in cSC). Interestingly, (-)GP was significantly more potent than (+/-)GP. These results show that (-)GP is the major inhibitory component of (+/-)GP, (-)GP is the more potent inhibitor of cancerous breast cell growth, and the inhibitory activity of (-)GP and (+/-)GP is related to the reduction of the cell cycle regulator, cyclin D1, and the induction of the cell proliferation inhibitor, TGFbeta.

Cytotoxicity of enantiomers of gossypol Schiff's bases and optical stability of gossypolone.

Optical Schiff's bases of gossypol were prepared with chiral gossypol and ethylamine. As has been similarly observed among the gossypol enantiomers, the (-)-gossypol ethylimine was more active than either the (+)-gossypol ethylimine or the racemic gossypol ethylimine against KB and MCF7 cells. Gossypolone was also observed to be more toxic than gossypol against both cell lines. All of the gossypol products tested showed comparable toxicity toward MCF7/ADR (adriblastine-resistant) cells. Attempts at producing chiral gossypolone from chiral gossypol failed because of rapid racemization. In addition, the Schiff's base derivatives of gossypolone formed with R-(+)-2-amino-3-phenyl-1-propanol could only be separated at reduced temperature, indicating that gossypolone Schiff's bases are less optical stable than gossypol Schiff's bases.

The crystal structure of the alpha-cellobiose.2 NaI.2 H(2)O complex in the context of related structures and conformational analysis.

The crystal structure of beta-D-glucopyranosyl-(1-->4)-alpha-D-glucopyranose (alpha-cellobiose) in a complex with water and NaI was determined with Mo K(alpha) radiation at 150 K to R=0.027. The space group is P2(1) and unit cell dimensions are a=9.0188, b=12.2536, c=10.9016 A, beta=97.162 degrees. There are no direct hydrogen bonds among cellobiose molecules, and the usual intramolecular hydrogen bond between O-3 and O-5' is replaced by a bridge involving Na+, O-3, O-5', and O-6'. Both Na+ have sixfold coordination. One I(-) accepts six donor hydroxyl groups and three C-H***I(-) hydrogen bonds. The other accepts three hydroxyls, one Na+, and five C-H***I(-) hydrogen bonds. Linkage torsion angles phi(O-5) and psi(C-5) are -73.6 and -105.3 degrees, respectively (phi(H)=47.1 degrees and psi(H)=14.6 degrees ), probably induced by the Na+ bridge. This conformation is in a separate cluster in phi,psi space from most similar linkages. Both C-6-O-H and C-6'-O-H are gg, while the C-6'-O-H groups from molecules not in the cluster have gt conformations. Hybrid molecular mechanics/quantum mechanics calculations show <1.2 kcal/mol strain for any of the small-molecule structures. Extrapolation of the NaI cellobiose geometry to a cellulose molecule gives a left-handed helix with 2.9 residues per turn. The energy map and small-molecule crystal structures imply that cellulose helices having 2.5 and 3.0 residues per turn are left-handed.

Time course study of substrate utilization by Aspergillus flavus in medium simulating corn (Zea mays) kernels.

Utilization of the three major corn reserve materials, starch, triglycerides (refined corn oil), and zein (storage protein), by Aspergillus flavus was monitored in vitro over a 7-day fermentation. Medium composition in which proportions of reserve materials initially approximated proportions in mature corn kernels changed little over the first 18 h. Subsequently, hydrolysis of both starch and triglycerides occurred simultaneously, with peak concentrations of glucose and free fatty acids on day 2 of the fermentation period. Fatty acid concentrations dropped relatively rapidly after day 2 but increased again after day 6. Aflatoxin B(1) production increased after 36 h, with a peak at day 4. Aflatoxin B(1) production paralleled fungal biomass production during the exponential growth phase. A. flavus did not appear to preferentially utilize any of the released fatty acids. A number of fungus-specific metabolites were detected, including arabitol, erythritol, mannitol, trehalose, and kojic acid. Mannitol exceeded the other metabolites in concentration, and the timing of mannitol production closely paralleled that of aflatoxin B(1). Kojic acid concentrations peaked at day 6. In contrast to previously described selective use of simple carbohydrates by A. flavus, less discrimination was displayed when faced with utilization of complex substrates such as starch or triglycerides.

Toxicity of (+)- and (-)-gossypol to the plant pathogen, Rhizoctonia solani.

The dimeric sesquiterpene gossypol occurs naturally in cottonseed and other parts of the cotton plant. Gossypol exists as enantiomers because of the restricted rotation around the central binaphthyl bond. The (-)-enantiomer is toxic to nonruminant animals while the (+)-enantiomer exhibits little, if any, toxicity to these animals. Developing cotton plants with low levels of the (-)-gossypol could expand the use of cottonseed as a feed source. Gossypol also may play a role in protecting the plant from pathogens. The relative toxicity of (+)- and (-)-gossypol to plant pathogens has not been reported. We measured the concentration of (+)- and (-)-gossypol in roots from cotton seedlings that were treated with the biocontrol agent Trichoderma virens that induces biosynthesis of gossypol and related terpenoids in cotton roots. (-)-Gossypol was the minor enantiomer in control and treated roots, but levels were slightly higher in roots from T. virens-treated seed. We also determined the toxicity of the gossypol enantiomers and the racemate to the seedling disease pathogen Rhizoctonia solani. The (+)- and (-)-enantiomers of gossypol and the racemate are equally effective in inhibiting growth of this pathogen. The lethal doses of the gossypols required to kill the pathogen appeared to be similar, but their toxicities are significantly less than those of related cotton and kenaf sesquiterpenes. The results indicate that altering the enantiomeric ratio in cotton roots will not adversely affect the resistance of seedlings to the seedling pathogen R. solani.

Inhibitory effects of gossypol, gossypolone, and apogossypolone on a collection of economically important filamentous fungi.

Racemic gossypol and its related derivatives gossypolone and apogossypolone demonstrated significant growth inhibition against a diverse collection of filamentous fungi that included Aspergillus flavus, Aspergillus parasiticus, Aspergillus alliaceus, Aspergillus fumigatus, Fusarium graminearum, Fusarium moniliforme, Penicillium chrysogenum, Penicillium corylophilum, and Stachybotrys atra. The compounds were tested in a Czapek agar medium at a concentration of 100 µg/mL. Racemic gossypol and apogossypolone inhibited growth by up to 95%, whereas gossypolone effected 100% growth inhibition in all fungal isolates tested except A. flavus. Growth inhibition was variable during the observed time period for all tested fungi capable of growth in these treatment conditions. Gossypolone demonstrated significant aflatoxin biosynthesis inhibition in A. flavus AF13 (B(1), 76% inhibition). Apogossypolone was the most potent aflatoxin inhibitor, showing greater than 90% inhibition against A. flavus and greater than 65% inhibition against A. parasiticus (B(1), 67%; G(1), 68%). Gossypol was an ineffectual inhibitor of aflatoxin biosynthesis in both A. flavus and A. parasiticus. Both gossypol and apogossypolone demonstrated significant inhibition of ochratoxin A production (47%; 91%, respectively) in cultures of A. alliaceus.