Biotransformation of linear alkylbenzene sulfonate (LAS) by Phanerochaete chrysosporium: oxidation of alkyl side-chain.

The white rot fungus Phanerochaete chrysosporium, which generally mineralizes substituted aromatics to CO2, transformed linear alkylbenzene sulfonate (LAS) surfactants mainly at their alkyl side chain. Degradation of LAS was evidenced by a zone of clearing on LAS-containing agar plates and colorimetric analysis of liquid cultures. Disappearance of LAS was virtually complete within 10 days in low nitrogen (2.4 mM N), high nitrogen (24 mM N) and malt extract (ME) liquid media. After 5 days of incubation in ME medium, transformation of LAS was complete at concentrations < or = 4 mg l(-1), but decreased at higher concentrations. The LAS degradation was not dependent on lignin peroxidases (LiPs) and manganese-dependent peroxidases (MnPs). Mineralization of 14C-ring-LAS to 14CO2 by P. chrysosporium was < 1% regardless of the culture conditions used. Thin layer chromatography and mass spectral analyses indicated that P. chrysosporium transformed LAS to sulfophenyl carboxylates (SPCs) through oxidative shortening of the alkyl side-chains. While LAS disappearance in the cultures was not dependent on LiPs and MnPs, transformation of the parent LAS moieties to SPCs was more extensive in low N medium that favors expression of these enzymes. The SPCs produced in LN cultures were shorter in chain- length than those produced in ME cultures. Also there was a notable shift in the relative abundance of odd and even chain length metabolites compared to the starting LAS particularly in the low N cultures suggesting the possible involvement of processes other than or in addition to beta-oxidation in the chain-shortening process.

Epitestosterone: a potential new antiandrogen.

Epitestosterone (EpiT) is the 17 alpha-hydroxy epimer of testosterone (T) and a natural steroid metabolite. It has previously been shown to be a 5 alpha-reductase inhibitor. We have studied EpiT as an antiandrogen using the hamster flank organ model. One-centimeter silastic capsules of crystalline T or dihydrotestosterone (DHT) were implanted subcutaneously in female Golden Syrian hamsters to provide continuous androgenic stimulation. After 3 weeks, the pigmented spot was measured and the flank organs were fixed for histologic sectioning. The maximum surface area (SA) from a central section of the sebaceous gland and the diameter of hair follicles were measured using a computerized digitizing tablet. Following T and DHT, respectively, there was a significant increase in pigmented spot size (656/382%), sebaceous gland SA (210/315%), and mean hair follicle diameter (80/56%). A 1-cm capsule of EpiT alone had no androgenic effect. Five- and ten-fold doses of EpiT were implanted with T or DHT. Epitestosterone significantly inhibited the T-dependent stimulation of pigment, sebaceous gland, and hair follicle at either 5- and/or 10-fold excess doses. Additionally, a 10-fold dose of EpiT also inhibited DHT-dependent stimulation of all 3 cutaneous structures. We conclude that EpiT was effective as an antiandrogen and had no intrinsic androgenic activity in the hamster flank organ. It probably functions both as a competitive inhibitor of the androgen receptor and as a 5 alpha-reductase inhibitor. Pigment and sebaceous gland growth were more sensitive than the hair follicle to androgen inhibition by EpiT at the time and doses tested.

Topical minoxidil does not act as an antiandrogen in the flank organ of the golden Syrian hamster.

Little is known about the mechanism of action of minoxidil-induced hair growth in male pattern baldness. We studied the potential antiandrogenic effect of topical minoxidil administered at the same dose and in the same vehicle that has been used successfully clinically in human subjects on the androgen-dependent cutaneous structures of the flank organ of the golden Syrian hamster. Minoxidil applied topically to one flank organ had no androgenic effect. Neither 1% nor 5% minoxidil topically applied for three weeks prevented the androgen-dependent growth of the pigmented spot, the sebaceous gland, or the hair follicle diameter induced by subcutaneous Silastic capsules filled with crystalline testosterone. As a positive control in the same experiments, 5% progesterone did significantly inhibit pigment and sebaceous gland enlargement. We conclude that there is no antiandrogenic component to the mechanism of action of topical minoxidil in the hamster flank organ, and thus there is probably no antiandrogenic role in man either.

Hair follicle response of the golden Syrian hamster flank organ to continuous testosterone stimulation using silastic capsules.

The hamster flank organ has served as a model to study androgen-dependent responses of the skin, but the quantitative response of hair follicles to androgenic stimulation has been neglected. We assayed the hair follicle response to testosterone (T) and compared it to the response of the sebaceous glands and of the dermal pigment in the Golden Syrian hamster flank organ. Because of biologic variation in male animals and uneven absorption of hormone from parenteral injections, we implanted silastic capsules 0.25, 0.5, 1, and 2 cm in length filled with crystalline T subcutaneously into female hamsters for 6 weeks. Hair follicle response to T was more sensitive than sebaceous gland or pigment. Diameters of hairs under the sebaceous gland increased significantly from control values of 27.7 +/- 1.0 micron to 38.0 +/- 1.6 micron at the lowest dose of T tested, the 0.25-cm capsule (p less than 0.001). There was an increase in the absolute number of hairs under the sebaceous gland as the flank organ enlarged, from 27.9 +/- 9.9 control to 55.3 +/- 5.8 with the 2-cm T capsule. There was no concomitant increase in hair density, 14.4 +/- 3.5 hairs/mm control vs 12.5 +/- 1.1 hairs/mm with the 2-cm capsule. Hair follicles lateral to the sebaceous gland did not show the same response to androgen stimulation. Sebaceous gland and pigmentation responded in a dose-dependent fashion, the maximum effect being achieved with a 1-cm T capsule. We conclude that T affects hair by specifically stimulating growth of individual hairs physically under the sebaceous gland. As the whole flank organ enlarges more hairs are recruited to become larger but no new follicles appear. These studies also confirm that there are different sensitivities to androgen within the various androgen-dependent components of the hamster flank organ, with increase in hair diameter being highly sensitive. This model should be useful for the specific and quantitative assessment of androgenic and antiandrogenic substances on hair growth and ultimately by useful for therapy of hirsutism.