Biosynthesis of makisterone A and 20-hydroxyecdysone from labeled sterols by the honey bee,Apis mellifera

In an effort to determine the sterol precursor(s) of the 28-carbon ecdysteroid, makisterone A, honey bee pupae (13 days post-oviposition) were injected with radiolabeled sterols and subsequently examined for labeled ecdysteroids. High performance liquid chromatography of the pupal extracts revealed that [³H]campesterol was converted to a compound that behaved chromatographically identical to authentic makisterone A, and [¹⁴C]cholesterol was incorporated into a compound chromatographically like 20-hydroxyecdysone. No incorporation of either 24-[³H]methylenecholesterol or [¹⁴C]sitosterol into an ecdysteroid was observed. The neutral sterols of uninjected honey bee pupae contained 49.8% 24-methylenecholesterol on a relative percent basis and, with three other C²⁸ and C²⁹ sterols, accounted for over 99% of the total sterols present.     

Sterol utilization and ecdysteroid content in the house fly,Musca domestica (L.)

Larvae of the house fly, Musca domestica were reared aseptically on diets which contained either cholesterol, campesterol or sitosterol as the dietary sterol at a concentration of 0.1% dry wt. Analysis of puraria (24 h post-pupariation) reared on campesterol or sitosterol diets revealed they contained from 2.7 to 4.6% cholesterol, indicating an ability to accumulate this sterol even where it is present in only minute quantities. Purparia on all diets produced the 27-carbon molting hormones, ecdysone and 20-hydroxyecdysone. When the concentration of campesterol was increased to 0.2% dry wt, puparia also contained the 28-carbon ecdysteroid, makisterone A, although it accounted for only 20.7% of the total ecdysteroid produced.     

The neutral sterols of Megalotomus quinquespinosus (say) (hemiptera: Alydidae) and identification of makisterone a as the major free ecdysteroid

Last-stage nymphs of the broad-headed bug, Megalotomus quinquespinosus contain the C₂₈ ecdysteroid makisterone A as their major ecdysteroid. No ecdysone or 20-hydroxyecdysone was detected in whole body extracts analyzed by high performance liquid chromatography and radioimmune assay. Analyses of the neutral sterols of this phytophagous hemipteran revealed that the sterol composition of the nymphs was highly reflective of their dietary sterols. The most abundant nymphal sterols were sitosterol (46.6%), Δ⁷-stigmastenol (13.8%) and spinasterol (13.4%). Cholesterol accounted for only 0.2% of the total sterols and indicates that this species is incapable of converting 24-alkyl sterols to cholesterol.     

Makisterone C: A 29-carbon ecdysteroid from developing embryos of the cotton stainer bug,Dysdercus fasciatus

An ecdysteroid RIA was used to determine the ecdysteroid titer in developing embryos of Dysdercus fasciatus and revealed that peak titer occurred approximately 120 h post-oviposition. Analysis of neutral sterols at this time indicated sitosterol to be the predominant neutral sterol with lesser amounts of campesterol. Embryonic sterols were highly reflective of the sterols found in the cotton seed diet upon which previous generations of the bugs had fed. Analysis of the embryonic extract for ecdysteroids indicated the presence of both makisterone A and the 29-carbon ecdysteroid makisterone C. Isolation of these compounds was accomplished by reversed-phase and silica HPLC in conjunction with RIA, and the identification of both compounds was confirmed by mass spectrometry. No ecdysone or 20-hydroxyecdysone was detected in the embryonic sample.     

Fragility of plasma membranes in Saccharomyces cerevisiae enriched with different sterols.

Saccharomyces cerevisiae NCYC 366, grown under strictly anaerobic conditions to induce requirements for an unsaturated fatty acid (supplied by Tween 80) and a sterol, contained free sterol fractions enriched to the extent of 67 to 93% with the exogenously supplied sterol (campesterol, cholesterol, 7-dehydrocholesterol, 22, 23-dihydrobrassicasterol, beta-sitosterol, or stigmasterol). Cells enriched in any one of the sterols did not differ in volume, growth rate, contents of free sterol, esters and phospholipids, or phospholipid composition. Cholesterol-enriched cells contained about 2% more lipid than cells enriched in any of the other sterols, which was largely accounted for by increased contents of triacylglycerols and, to a lesser extent, esterified sterols. Phospholipids were enriched to the extent of about 52 to 63% with C18:1 residues. Cells enriched in ergosterol or stigmasterol were slightly less susceptible to the action of a wall-digesting basidiomycete glucanase than cells enriched with any one of the other sterols. The capacity of the plasma membrane to resist stretching, as indicated by the stability and volume of spheroplasts suspended in hypotonic solutions of buffered sorbitol (particularly in the range 0.9 to 0.7 M), was greater with spheroplasts enriched in sterols with an unsaturated side chain at C17 (ergosterol or stigmasterol) than with any of the other sterols. Plasma membranes were obtained from spheroplasts enriched in cholesterol or stigmasterol and had free sterol fractions containing 70 and 71%, respectively, of the sterol supplied exogenously to the cells. The sterol-phospholipid molar ratios in these membranes were, respectively, 1:7 and 1:8.     

Neutral sterols and ecdysteroids of the solitary cactus bee Diadasia rinconis cockerell (hymenoptera: Anthophoridae)

Using high performance liquid chromatography in conjunction with radioimmunoassay and mass spectrometry, the major ecdysteroid of the solitary cactus bee, Diadasia rinconis, was determined to be 20-hydroxyecdysone, with lesser amounts of makisterone A. Another 28-carbon ecdysteroid thought to be the 24-epimer of makisterone A was also detected. The neutral sterols of Diadasia consisted primarily of 24-methylenecholesterol (92.2%) with lesser amounts of other C₂₈ and C₂₉ sterols. Cholesterol accounted for less than 0.1% of the total tissue sterols. The occurrence of 20-hydroxyecdysone in a phytophagous hymenopteran is discussed in relation to the low level of cholesterol encountered. © 1993 Wiley-Liss, Inc.

1 This article is a US Government work and, as such, is in the public domain in the United States of America.

     

Seasonal and geographical variations of sterol composition in snow crab hepatopancreas and pelagic fish viscera from Eastern Quebec

Sterol composition was determined in snow crab hepatopancreas and mackerel and herring viscera for various locations and collection periods. A simple and valuable method, using direct saponification and extraction with water-cyclohexane has been optimized to recover total sterol. They were identified and quantified as trimethylsilyl ether derivatives by GC-MS analysis. Method validation indicated excellent sensitivity (limit of quantification: 1.25 mg/100 g wet basis for cholesterol and desmosterol; 0.03-0.05 mg/100 g for other sterols), good reproducibility (CV%: 1.5-6.8) and accuracy (recovery%: 94-107). In crab hepatopancreas, cholesterol was the main sterol (67-76%), followed by desmosterol (19-24%). Phytosterols and molluscan sterols were also present in low quantity. A lower total sterol content with different composition was found in crabs from Magdalen Islands compared to those from Gaspé Peninsula or North Shore of the St-Lawrence Gulf. No seasonal variation was observed between collection periods, which were probably too close. Mackerel and herring viscera contained the same sterols as crab except for campesterol and sitosterol, but the cholesterol proportion was higher (93-98%). The higher abundance of sterols in herring caught in September vs. May would be related to an increase of the body lipid content during the summer.     

Regulation of cholesterol biosynthesis in sitosterolemia: effects of lovastatin, cholestyramine, and dietary sterol restriction.

We investigated the effects of lovastatin, cholestyramine, and dietary sterol restriction on cholesterol synthesis and low density lipoprotein receptor function in freshly isolated mononuclear leukocytes from two unrelated sitosterolemic families. Total plasma sterol concentrations were elevated in the two homozygous sitosterolemic subjects (343 and 301 vs. 185 mg/dl in controls) and contained increased amounts of plant sterols and 5 alpha-saturated stanols (20% and 8% vs. less than 1% in controls), but were not significantly different from controls in the two heterozygous subjects. The rates of conversion of acetate to cholesterol by mononuclear leukocytes were subnormal in all homozygous and heterozygous subjects and correlated with markedly reduced microsomal 3-hydroxy-3-methylglutaryl co-enzyme A (HMG-CoA) reductase activity. In the two homozygous subjects, cholestyramine treatment decreased plasma sterols 29% and 35%, and yet was associated with a paradoxical decline in mononuclear leukocyte HMG-CoA reductase activity. In contrast, plasma sterol concentrations decreased 14% and 5%, and mononuclear leukocyte HMG-CoA reductase activities increased 13% and 46% in three control and one heterozygous subjects treated with cholestyramine, respectively. Plasma sterol concentrations in the homozygous subjects unexpectedly failed to decline during treatment with lovastatin or a low sterol diet. In distinction, plasma sterol concentrations in three control and one heterozygous subjects dropped 28% and 31%, respectively, during treatment with lovastatin. Both cholestyramine and low dietary sterols stimulated low density lipoprotein receptor function. These results demonstrate a marked abnormality in cholesterol homeostasis in patients with homozygous sitosterolemia with xanthomatosis.(ABSTRACT TRUNCATED AT 250 WORDS)     

Sterols in Germinating Seeds and Developing seedlings of Longleaf Pine, Pinus palustris

Sterols in germinating embryos and young seedlings of longleaf pine (Pinus palustris Mill.) were identified and quantities determined for different periods after germination. Sterol analyses were performed by gas-liquid chromatography (GLC) and verified by combination of GLC-mass spectrometry. Campesterol and β-sitosterol were two major sterols which accounted for most of the sterol composition while stigmasterol was present in very small amounts. No cholesterol was revealed by GLC-mass spectrometry although there was a minor peak appearing on the sterol gas-liquid chromatograms with a retention time close to that of authentic cholesterol. By fractionation, three different forms of sterols were obtained: steryl esters, steryl glycosides, and free sterols. The sterols were mainly found in the esterified fraction, while steryl glycosides and free sterols only made up a small portion of the total sterol value. The total sterol content in general increased during seedling development, and this increase reflected mainly a change in steryl esters. The low levels of both free and glycosidic sterols remained nearly unchanged throughout the experimental germination period.     

Neutral sterols of representatives of two groups of hemiptera and their correlation to ecdysteroid content

The sterols of four species of Pentatomomorpha—Oncopeltus fasciatus (Dallas), Nezara viridula (L.), Dysdercus cingulatus (F.), and Podisus maculiventris (Say)—and threé species of Cimicomorpha—Rhodnius prolixus Stal, Arilus cristatus (L), and Cimex lectularius (L.)—were isolated and examined in order to compare neutral sterol utilization and content with the known ecdysteroids of these species. In the phytophagous Pentatomomorpha, O. fasciatus, N. viridula, and D. cingulatus, the low content of cholesterol and the high content of C₂₈ and C₂₉ phytosterols (< 1% and > 99% of the tissue sterols, respectively) indicated that these species are unable to dealkylate the C-24 position of sterols. These insects appear to have adapted to the challenge of both insufficient dietary cholesterol and inability to dealkylate phytosterols by evolving the ability to produce a C₂₈ ecdysteroid (makisterone A). The secondarily predacious P. maculiventris has adequate cholesterol available for C₂₇ ecdysteroid production, but appears to have retained the ecdysteroid biosynthetic pathways of its phytophagous ancestors because it produces a C₂₈ ecdysteroid. Cholesterol was the major sterol of each of the three species of Cimicomorpha, and these insects are only able to produce C₂₇ ecdysteroids.     

Schistosoma mansoni: sterol and phospholipid composition of cercariae, schistosomula, and adults

The sterol and phospholipid composition of cercariae, schistosomula, and adult Schistosoma mansoni was analyzed by gas-liquid chromatography and high-performance liquid chromatography (HPLC). Cercariae and schistosomula contained cholesterol, desmosterol, campesterol, stigmasterol, and beta-sitosterol while adults contained only cholesterol. In all stages cholesterol comprised greater than 50% of the total sterols, and in cercariae and schistosomula desmosterol comprised 38 and 21% of the total sterols, respectively. The other three sterols, campesterol, stigmasterol, and beta-sitosterol, made up approximately 10% of the total. The same five sterols found in cercariae and schistosomula were present in the hepatopancreas of uninfected snails but with a much higher desmosterol concentration in the parasite, 38%, than in the snail, 2%. As in cercariae and schistosomula the three minor sterols comprised approximately 10%. Thus, the sterol composition of cercariae and schistosomula was similar but not identical to that of the snail host. Phosphatidylcholine was the major phospholipid of all three stages (50%) as determined by two HPLC procedures. The remaining phospholipids consisted of phosphatidylethanolamine, phosphatidylserine, and phosphatidylinositol. In addition, in adults there were small quantities of sphingomyelin and lysophosphatidylcholine. The percentage of each phospholipid was similar among stages with the exception of a slight increase in phosphatidylserine in adults compared to cercariae and schistosomula. These results show that a characteristic lipid composition is found in cercariae, schistosomula, and adults.     

Distribution and dynamic state of sterols and steroids in the tissues of an insect, the roach Eurycotis floridana

The total concentrations of sterols in the tissues of the roach, Eurycotis floridana, reared under aseptic conditions and on semisynthetic diets, are similar to, but somewhat lower than, those of tissues of vertebrates. Total concentrations of tissue sterols are relatively independent of dietary concentration of sterols whether the diet contains 0.1% cholesterol as the sole sterol, or a "minimal cholesterol" mixture (0.1% cholestanol together with 0.005% cholesterol). Under the latter conditions the cholesterol is incorporated preferentially into most tissues and remains almost exclusively unesterified, while the cholesterol-sparing sterol is esterified to varying degree, depending upon the tissue. The turnover of tissue sterols has been studied. Cholesterol of the tissues of adult insects grown on a diet containing this sterol alone may be displaced by cholestanol fed as 5% of the total diet, initially at an appreciable rate but later much less rapidly. In growing insects that have received a diet containing cholestanol together with minimal cholesterol, the unesterified cholesterol turns over slowly in all tissues and immeasurably slowly in some. The unesterified sparing sterol, on the other hand, turns over at a much greater rate. The turnover of sterols during growth is accompanied by a shift of sterols from the unesterified to the esterified pool in all tissues. The fat body of the growing insect stores sterols (apparently as their esters) that have been displaced from other tissues. The fat body of the adult does not show evidence of sterol storage. Polar derivatives of sterols are present in minor amount in all tissues of the insect, most abundantly in the mid-intestine and gastric caeca. These compounds seem likely to be C(27) steroids.     

Dietary cholesterol utilization by the housefly,Musca domestica

The amount of cholesterol and the distribution of its metabolites were studied in various larval tissues of the housefly (Musca domestica), reared on a high cholesterol diet containing the radioactive cholesterol. The sterol content was also examined in adults derived from larvae reared on increasing dietary cholesterol concentration in separate batches. The results suggest that when the dietary sterol concentration was raised from 0.002 to 0.02% wet weight (an optimal concentration required for a maximal growth and development of insect), the sterol content of six-day old larvae was increased approx. 4-fold. However, a further 10-fold increase of dietary cholesterol (to 0.22% of wet weight) was associated with only a 1.5-fold increase in larval sterol content, and no increase in the sterol content of adult insects derived from such larvae was observed. This increase of sterol content of whole larvae was found to be confined to the larval cuticle and composite gut fractions and may be attributed to unabsorbed cholesterol in the gut, and to a solubilizing effect of the cuticle. These findings suggest that when the cholesterol requirement for the maximal growth of the insect has been reached, larvae are able to regulate the intake of ingested cholesterol, and no more is taken up through the gut even when a high gut concentration of cholesterol is present.The adults contained a higher percentage of esterified sterols than the larvae, approx. 25% of the sterol in females and 14% of sterol in males were esterified.     

Sterols of the syndinian dinoflagellate Amoebophrya sp., a parasite of the dinoflagellate Alexandrium tamarense (Dinophyceae)

Several harmful photosynthetic dinoflagellates have been examined over past decades for unique chemical biomarker sterols. Little emphasis has been placed on important heterotrophic genera, such as Amoebophrya, an obligate, intracellular parasite of other, often harmful, dinoflagellates with the ability to control host populations naturally. Therefore, the sterol composition of Amoebophrya was examined throughout the course of an infective cycle within its host dinoflagellate, Alexandrium tamarense, with the primary intent of identifying potential sterol biomarkers. Amoebophrya possessed two primary C(27) sterols, cholesterol and cholesta-5,22Z-dien-3beta-ol (cis-22-dehydrocholesterol), which are not unique to this genus, but were found in high relative percentages that are uncommon to other genera of dinoflagellates. Because the host also possesses cholesterol as one of its major sterols, carbon-stable isotope ratio characterization of cholesterol was performed in order to determine whether it was produced by Amoebophrya or derived intact from the host. Results indicated that cholesterol was not derived intact from the host. A comparison of the sterol profile of Amoebophrya to published sterol profiles of phylogenetic relatives revealed that its sterol profile most closely resembles that of the (proto)dinoflagellate Oxyrrhis marina rather than other extant genera.     

Effects of diet and metamorphosis upon the sterol composition of the butterfly Morpho peleides

Whole body sterol metabolism in insects has seldom been studied. We were able to design an appropriate study at a butterfly farm in Belize. We collected six larvas of butterfly (Morpho peleides), their food (leaves of Pterocarpus bayessii), and their excretions. In addition, six adult butterflies were collected. The sterols of the diet, the larva, and adult butterfly were analyzed by gas-liquid chromatography. The structures of these sterols were identified by digitonin precipitation, GC-MS, and NMR. Four sterols (cholesterol, campesterol, stigmasterol, and sitosterol) and a sterol mixture were found in the food, the body, and the excreta of the larva. The tissue sterol content of the larva was 326 microg. They consumed 276 microg of sterols per day. Their excretion was 185 microg per day as sterols. The total tissue sterol contents of the larva and butterfly were similar, but they had different sterol compositions, which indicated interconversion of sterols during development. There was a progressive increase in the cholesterol content from larva to butterfly and a decrease in the content of sitosterol and other plant sterols, which were likely converted to cholesterol. Our data indicated an active sterol metabolism in butterfly larva. Diet played an important role in determining its sterol composition. During metamorphosis, there was an interconversion of sterols. This is the first paper documenting the fecal sterol excretion in insects as related to dietary intakes.     

Lethal atherosclerosis associated with abnormal plasma and tissue sterol composition in sitosterolemia with xanthomatosis

Tissue sterol composition was determined in an 18-year-old male with sitosterolemia with xanthomatosis who died suddenly and whose coronary and aortic vessels showed extensive atherosclerosis and, for comparison, in an 18-year-old male with minimal atherosclerosis who died accidently. Sterols in the control tissues (plasma, erythrocytes, cardiac muscle, lung, liver, aorta, and brain) contained cholesterol with only trace amounts of cholestanol. In contrast, sterols in corresponding tissues of the sitosterolemic subject (except brain) were composed of cholesterol, increased amounts of plant sterols, campesterol and sitosterol, and 5 alpha-saturated stanols, cholestanol, 5 alpha-campestanol, and 5 alpha-sitostanol, that were deposited in approximately the same ratio as present in plasma. However, sitosterolemic brain sterol composition resembled that of the control brain with cholesterol and only trace amounts (less than 1%) of cholestanol and phytosterols. The sitosterolemic aorta was extensively atherosclerotic and contained more than twice the quantity of sterols as the control aorta (5.6 mg/g versus 2.6 mg/g) with increased amounts of cholesterol, plant sterols, and 5 alpha-saturated stanols. These results indicate that cholesterol, plant sterols, and 5 alpha-stanols are deposited prematurely and are associated with accelerated atherosclerosis in subjects with sitosterolemia with xanthomatosis.     

Sterols and sterylglycosides of oats (Avena sativa). Distribution in the leaf tissue and medium-induced glycosylation of sterols during protoplast isolation

Sterols, sterylglycosides (SG), acylated sterylglycosides (ASG) and steroidal saponins of primary leaves of oat ( Avena sativa L. cv. Flämingskrone) were analyzed by thin-layer chromatography, gas-liquid chromatography and high-performance liquid chromatography. Intact leaves, epidermis preparations, epidermis-stripped leaves, isolated protoplasts and chloroplasts were compared. The mesophyll contained 79% of the total leaf sterols, 80% of the SG and 78% of the ASG, but only 33–67% of the saponins. Free sterols, SG and ASG were mainly localized within the mesophyll, whereas steroidal saponins were localized in the epidermis to a significantly higher extent. The sterol parts consisted mainly of sitosterol, stigmasterol. cholesterol. Δ⁵-avenasterol, Δ⁷-avenasterol, campesterol and Δ⁷-cholestenol, and were quantitatively different in different sterol groups. A higher percentage of sitosterol at the expense of stigmasterol was typical for SG and ASG as compared to free sterols. Only minor differences in the sterol composition were found in a given sterol group when isolated from different tissues. Isolated protoplasts contained only 5–9% of the sterols present in mesophyll cells, indicating that the major part of the free sterols was lost during isolation. Exposure of radioactively labelled leaf segments to either buffer or digestion medium induced rapid transformation of sterols to SG and ASG as shown by the shift of radioactivity from free sterols to the glyeosides. This suggests that two sterol pools exist in the cell: one in the plasmalemma, which is accessible to medium-induced transformation, and a second non-accessible pool in the interior membranes (e.g. chloroplasts) of the cell.     

Variations of hepatic cholesterol precursors during altered flows of endogenous and exogenous squalene in the rat

Hepatic and serum levels of cholesterol precursors were analyzed in rats under basal (control) conditions and when cholesterol synthesis was activated by feeding 1% squalene or 5% cholestyramine. Exogenous squalene stimulated the activity of acyl-coenzyme A:cholesterol acyltransferase (ACAT) but strongly inhibited the activity of hydroxymethylglutaryl-coenzyme A (HMG-CoA) reductase; cholestyramine did not affect ACAT but increased HMG-CoA reductase several-fold, indicating enhanced production of endogenous squalene. Activation of cholesterol synthesis by the two methods markedly increased the hepatic and serum contents of cholesterol precursor sterols. However, the sterol profiles were clearly different. Thus, exogenous squalene raised most significantly (up to 109-fold) free and esterified methyl sterols, and less so (up to 2-fold) demethylated C27 sterols (desmosterol and cholestenols) and also esterified cholesterol. Activation of endogenous squalene production by cholestyramine was associated with a depletion of esterified cholesterol and by a marked, up to 8-fold, increase of the free demethylated sterol precursor levels, whereas the increase of methyl sterols, up to 5-fold, was less conspicuous than during the squalene feeding. The changes were mostly insignificant for esterified sterols. The altered serum sterol profiles were quite similar to those in liver. Serum cholestenols and especially their portion of total serum precursor sterols were closely correlated with the hepatic activity of HMG-CoA reductase.     

Natural selection of Varroa jacobsoni explains the different reproductive strategies in colonies of Apis cerana and Apis mellifera

In colonies of European Apis mellifera, Varroa jacobsoni reproduces both in drone and in worker cells. In colonies of its original Asian host, Apis cerana, the mites invade both drone and worker brood cells, but reproduce only in drone cells. Absence of reproduction in worker cells is probably crucial for the tolerance of A. cerana towards V. jacobsoni because it implies that the mite population can only grow during periods in which drones are reared. To test if non-reproduction of V. jacobsoni in worker brood cells of A. cerana is due to a trait of the mites or of the honey-bee species, mites from bees in A. mellifera colonies were artificially introduced into A. cerana worker brood cells and vice versa. Approximately 80% of the mites from A. mellifera colonies reproduced in naturally infested worker cells as well as when introduced into worker cells of A. mellifera and A. cerana. Conversely, only 10% of the mites from A. cerana colonies reproduced, both in naturally infested worker cells of A. cerana and when introduced into worker cells of A. mellifera. Hence, absence of reproduction in worker cells is due to a trait of the mites. Additional experiments showed that A. cerana bees removed 84% of the worker brood that was artificially infested with mites from A. mellifera colonies. Brood removal started 2 days after artificial infestation, which suggests that the bees responded to behaviour of the mites. Since removal behaviour of the bees will have a large impact on fitness of the mites, it probably plays an important role in selection for differential reproductive strategies. Our findings have large implications for selection programmes to breed less-susceptible bee strains. If differences in non-reproduction are mite specific, we should not only look for non-reproduction as such, but for colonies in which non-reproduction in worker cells is selected. Hence, in selection programmes fitness of mites that reproduce in both drone and worker cells should be compared to fitness of mites that reproduce only in drone cells. © Rapid Science Ltd. 1998     

Utilization of Δ5,7 - and Δ8-sterols by larvae of Heliothis zea

Larvae from two populations of Heliothis zea were reared on artificial diets containing various sterols, which supported suboptimal growth, and their tissue sterols were characterized in order to determine how these dietary sterols are utilized by this insect. The sterols studied included Δ^5,7-sterols (7-dehydrocholesterol or ergosterol), Δ⁸-sterols (lanosterol and/or 24-dihydrolanosterol), and a Δ⁵-sterol (4,4-dimethylcholesterol). Although larvae did not develop on 4,4-dimethylcholesterol, those fed primarily Δ⁸-4,4,14-trimethylsterols developed to the third instar. When the latter sterols were spared with cholesterol, the larvae reached the sixth instar and contained 4,4,14-trimethylsterols as well as cholesterol in their tissues. When larvae were fed 7-dehydrocholesterol, <1% of the larvae from one population developed to the sixth instar and these larvae contained 7-dehydrocholesterol as their principal sterol. The other larvae successfully completed their larval stage when they were transferred from the diet containing 7-dehydrocholesterol (or no sterol) to a diet containing cholesterol within at least 9 days. The sterol composition of larvae transferred from a diet containing cholesterol to a diet containing 7-dehydrocholesterol, after they had reached 60% of their final weight, was 54% cholesterol and 46% 7-dehydrocholesterol. The major sterol isolated from the tissues of the larvae fed ergosterol was also 7-dehydrocholesterol. Therefore, although the larva of H. zea can dealkylate and saturate the side chain of the Δ^5,7,22-24β-methylsterol, it carries out little metabolism of the B ring of the nucleus. These studies demonstrate that, when Δ^5,7- or Δ⁸-sterols are the principal sterols in the diet of H. zea, they are absorbed and incorporated into its tissues, although they slow the rate of growth and may prevent complete development of the larva.