ABSTRACT
Protein kinase C(PKC) is a kind of kinase which is widely involved in cell proliferation and development. PKC(Wp-PKC) in Whitmania pigra body belongs to classic PKC. In order to investigate the effect of Wp-PKC on the development of Wh. pigra germ cells, 17β-estradiol(17β-E2)(100 ng·mL~(-1)) and methyltestosterone(MT)(150 μg·L~(-1)), 150 μg·L~(-1)(MT)+0.5 mg·L~(-1) PKC, 0.5 mg·L~(-1) PKC inhibitor were added to Wh. pigra culture water, and no addition group(control group) was added, and the effects on the development of Wh. pigra germ cells and the expression of Wp-PKC were observed. The results showed that: Wp-PKC in male gonads was always higher than that in female gonads; MT promoted the development of male gonads in Wh. pigra, while the expression of Wp-PKC was significantly higher than that in the control; 17β-E2 promoted the development of female gonads in Wh. pigra and Wp-PKC expression significantly lower than that of the control; while the development of the female and male gonads in the PKC inhibitor group was inhibited, the expression of Wp-PKC was significantly lower than that of the control. In summary, Wp-PKC may promote the development of Wh. pigra, especially the development of male gonads.
Subject(s)
Animals , Female , Male , Estradiol , Gonads , Leeches , Methyltestosterone , OvaryABSTRACT
The objectives of study were to explore the effects of exogenous methyltestosterone( MT) on the growth and gonadal development of overwintering Whitmania pigra. Before overwintering,0. 1,1. 0,10. 0,100. 0,150. 0 μg·L-1 of MT were added to the aquaculture water for 6 weeks. The changes of growth performance,gonad index,endogenous steroid hormones level and internal quality were measured after hibernate for 60 days. Then the tissue slice technique was used to observe the spermary( ovary) of Wh. pigra.The results showed that the body weight,survival rate and gonadal index increased first and then decreased with the increase of exogenous MT concentration; the male gland index was found the highest at the concentration of MT 10. 0 μg·L-1 and the female gland index was the highest at the concentration of MT 1. 0 μg·L-1. The survival rate of Wh. pigra peaked at the concentration of MT 10. 0 μg·L-1.The weight reaches a peak at a concentration of MT 100. 0 μg·L-1( P<0. 05). The number of primary spermatocytes in the testis was negatively correlated with the concentration of exogenous MT. The number of secondary spermatocytes and sperm cells increased first and then decreased. The concentration of secondary spermatocytes was the highest when the concentration of MT was 100. 0 μg·L-1.The number and volume of oocytes in the ovary and the yolk granules increased first and then decreased with the increase of exogenous MT concentration,and the highest was observed at the MT concentration of 100. 0 μg·L-1. The endogenous steroid hormone of Wh.pigra increased first and then decreased with the increase of exogenous MT concentration. The concentration of androgen and progesterone was the highest in MT 100. 0 μg·L-1 treatment( P<0. 05),and the concentration of estrogen was found the highest in MT 10. 0 μg·L-1 treatment( P<0. 05). After adding exogenous MT,Wh. pigra moisture content,acid-insoluble ash content,p H and anti-thrombin activity met the quality criterion of medicinal Wh. pigra in Chinese Pharmacopoeia( 2015 edition). In conclusion,the short-term addition of 1. 0-100. 0 μg·L-1 exogenous MT before hibernation can promote the growth,the development of sperm cells and the antithrombin activity of Wh. pigra.
Subject(s)
Animals , Female , Male , Estrogens , Gonads , Leeches/physiology , Methyltestosterone , Ovary , ProgesteroneABSTRACT
Little is known about the effects of the interaction of growth hormone (GH) with 17 a-methyltestosterone (17-MT) during fish growth. We evaluated this in the present study to assess the effect on fish growth. Fish in two batches of juvenile tilapia (Oreochromis niloticus) (approximately 5.0cm in length) were randomly assigned in triplicate to three treatments and a control group, distributed among 12 fiberglass tanks of 1 000L capacity (50 fish per tank) in an experiment covering a period of six weeks. The experimental groups were: a) fish treated with 17-MT and GH in mineral oil (RGH); b) fish treated with 17-MT and mineral oil without the addition of GH (R); c) fish treated with GH in mineral oil but not 17-MT (NGH); and d) fish of the control group, which were treated with mineral oil but not 17-MT or GH (N). The GH was injected into the fish at a rate of 0.625mg/g body weight. Morphometric data were recorded at the beginning of the experiment (T) and at 15, 30 and 45 days (T, T and T), and various indicators of growth were assessed: condition factor (K); survival percentage (S), feed conversion rate (FCR), percentage weight gain (WG) and (v) daily weight gain. The optimum dietary level was calculated assuming 5% food conversion to total weight in each group. During the experiment, the fish were provided with a commercial food containing 45% protein. The data showed that GH injection resulted in a greater weight gain in fish treated with 17-MT (the RGH treatment group), being particularly significant increase in weight during T and T (p<0.05). High values of K were found in the R and RGH treatments during the initial days of the experiment, which may have been a consequence of the better nutritional status affecting both weight gain and growth in body length, as a result of the additive effects of 17-MT and GH. The fish in groups not treated with 17-MT and treated with 17-MT and added GH showed greater increases in WG per day, higher K values and lower FCRs than fish in the other groups, which suggests that greater feed efficiency occurred in the hormone-treated fish. Fish in the RGH treatment showed the most growth, suggesting a possible interaction between 17-MT and injected GH.
Actualmente, durante el crecimiento de los peces existe poco conocimiento sobre los efectos de la interacción de la hormona del crecimiento (HC) con 17 α-metiltestosterona (17-MT). En el presente estudio los peces en dos lotes de tilapia (Oreochromis niloticus) (5.0cm de longitud), fueron asignados al azar por triplicado a tres tratamientos y un grupo control, distribuidos en 12 tanques de fibra de vidrio de 1 000 litros (50 peces por tanque), en un período de seis semanas. Los tratamientos fueron: a) peces tratados con 17-MT+HC en aceite mineral (RGH), b) peces tratados con 17-MT+aceite mineral sin la adición de HC (R), c) los peces que no fueron tratados con 17-MT-tratado+HC en aceite mineral (NGH), y d) los peces que no fueron tratados con 17-MT+aceite mineral (N). La hormona de crecimiento humano recombinante (Humatrope, Eli Lilly & Co., Windlesham, Inglaterra), se inyectó en el pez con una dosis de 0.625mg por gramo de peso corporal. Los datos morfométricos se registraron al comienzo del experimento (T) y en los días 15, 30 y 45 (T, T y T), Se registraron diversos indicadores de crecimiento: factor de condición (K), porcentaje de supervivencia (S), la tasa de conversión alimenticia (FCR), porcentaje de ganancia de peso (GP) y el aumento de peso al día. El nivel óptimo dietético fue calculado suponiendo 5% de conversión de alimentos al peso total de cada grupo. Durante el experimento fue usada una dieta comercial con el 45% de proteína. De los resultados presentados, es evidente que la inyección de HC dio lugar a una mayor ganancia de peso en el 17-MT-los peces tratados (el grupo de tratamiento RGH), y la diferencia fue significativa, tanto en T y T (p<0.05) para ambas comparaciones. De manera similar, los altos valores de K se presentaron en los tratamientos R y RGH durante los primeros días de cultivo. Esto puede haber sido asociado con un mejor estado nutricional que afectó tanto el desarrollo de peso y la longitud del cuerpo del pez, como resultado del efecto aditivo de 17-MT y GH. Los tratamientos no andrógenos y los grupos tratados con andrógenos y con HC mostraron un mayor incremento en la ganancia de peso por día, los mayores valores de K y menores tasas de conversión del alimento, lo que sugiere una mayor eficiencia de la alimentación en los peces tratados con hormonas. Peces en el tratamiento RGH mostraron el mayor crecimiento, lo que sugiere una posible interacción entre el 17 de α-metiltestosterona (17-MT) y hormona de crecimiento inyectada.
Subject(s)
Animals , Female , Male , Human Growth Hormone/administration & dosage , Methyltestosterone/administration & dosage , Tilapia/growth & development , Weight Gain/drug effects , Aquaculture , Injections, Intramuscular , Random Allocation , Recombinant Proteins/administration & dosageABSTRACT
O objetivo deste trabalho foi avaliar a influência da salinidade da água e suplementação alimentar com Spirulina platensis no crescimento e masculinização de Oreochromis niloticus, tilápia do Nilo. Na primeira fase, além da S. platensis, foi ofertada ração microparticulada (50% PB; 4500 Kcal/kg) contendo o andrógeno 17-α- metiltestosterona. Na segunda etapa, as tilápias foram cultivadas por mais 32 dias em água doce, alimentadas apenas com ração (38% PB; 1900 Kcal/kg). Os delineamentos foram divididos em três tratamentos com cinco repetições cada. Os animais (peso inicial: 0,01 ± 0,02 g, comprimento inicial: 1,0 ± 0,03 cm) ao final de 28 dias apresentaram crescimento médio em peso e crescimento total em comprimento de 1,64 ± 0,10 g e 4,84 ± 0,24 cm; 1,59 ± 0,18 g e 4,94 ± 0,12 cm e 1,58 ± 0,09 g e 4,84 ± 0,02 cm para as salinidades 0, 15 e 25 g.L-1, respectivamente. A masculinização mais satisfatória foi alcançada pelos peixes cultivados a 15 g.L-1, ao qual obtiveram 90% de machos. A análise de variância não evidenciou diferenças significativas (p>0,05) entre os tratamentos para o desenvolvimento em ambas as fases de cultivo e para a taxa de masculinização ao final do experimento. As salinidades testadas não interferiram no desempenho dos peixes, propondo que a microalga S. platensis pode ser utilizada com êxito como suplemento alimentar para tilápias do Nilo nas condições testadas.
The aim of this study was evaluate the influence of water salinity and diet supplemented with Spirulina platensis on growth and masculinization of Nile tilapia. In the first phase, in addition to S. platensis, was offered microparticulate diet (50% CP, 4500 Kcal/kg) containing 17-α-methyltestosterone androgen. In the second phase, the tilapias were cultivated for 32 days in fresh water, fed only with ration (38% CP, 1900 kcal/kg). The designs were divided into three treatments with five replicates each. The animals (initial weight: 0,01 ± 0,02 g, initial length: 1,0 ± 0,03 cm) after 28 days showed average weight growth and total length growth of 1,64 ± 0,10 g; 4,84 ± 0,24 cm, 1,59 ± 0,18 g; 4,94 ± 0,12 cm, 1,58 ± 0,09 g; 4,84 ± 0,02 cm, in salinities 0, 15 and 25 g.L-1, respectively. The indices of improvement sexual inducing were achieved by animals cultured at 15 g.L-1, which reached 90% of masculinization. Analysis of variance showed no significant differences (p>0,05) among treatments for development in cultivation phases both and the masculinization rate in the experiment final. The salinities tested did not interfere with the performance of fish, suggesting that the microalgae S. platensis can be successfully used as a food supplement for Nile tilapia in the tested conditions.
Subject(s)
Cichlids , Dietary Supplements , Methyltestosterone , Sex Differentiation , Spirulina , Transsexualism/metabolism , Saline Waters , Spirulina/metabolismABSTRACT
The objective of this research was to evaluate the sex reversal technique using 17α--methyltestosterone (MT) hormone, submitted to temperature modification of fry Nilo tilapia storage, aiming to get the data of sex reversal combined with growth performance and fry survival. The experiment was performed at UFLA Fish Culture Station, using tilapia fry (0,008 ± 0.002 g e 0,9 ± 0.1 cm) obeying a totally randomized experimental delineation in a factorial scheme 4x4, in 4 temperatures (26º, 28º, 30º, 32ºC) and 4 hormonal doses (0, 20, 40, 60mg of MT/kg of ration) during 28 days, with 5 repetitions. As temperature raised, weight gain rate, size and survival increased (p<0.01); however, this temperature raise was not effective in modifying males ratio (p>0.01), which occurred only due to the used hormone treatment. The dose of 40 mg of MT/kg of ration provided similar results to those of 60mg of MT/kg of ration. Hence, the temperature band from 26º to 32ºC does not affect sex reversal rate, but temperatures around 30ºC improves the performance of tilapias related to the growth and survival, and the dose of 40 mg of MT/kg of ration is enough to achieve monosex populations.
Objetivou-se, neste trabalho, avaliar a técnica de inversão sexual utilizando hormônio 17α-metiltestosterona (MT), submetidas à modificação da temperatura de estocagem das pós-larvas de tilápia, visando obter os melhores dados de inversão sexual aliado à performance de crescimento e sobrevivência das pós-larvas. O experimento foi conduzido na Estação de Piscicultura da UFLA, utilizando pós-larvas (0,008 ± 0,002 g e 0,9 ± 0,1 cm) de tilápia em delineamento experimental inteiramente casualizado em esquema fatorial 4x4, com 4 temperaturas (26º, 28º, 30º e 32ºC) e 4 doses hormonais (0, 20, 40 e 60mg de MT/kg de ração) durante 28 dias, com 5 repetições. À medida que se elevou a temperatura, a taxa de ganho de peso, o tamanho e a sobrevivência foram maiores (p<0,01); entretanto, esse aumento na temperatura não foi suficiente para alterar a proporção de machos (p>0,01), que ocorreu apenas em função do hormônio utilizado. A dose de 40 mg de MT/kg de ração proporcionou resultados semelhantes aos da dose de 60 mg de MT/kg de ração. Portanto, a faixa de temperatura entre 26º e 32ºC não influencia na taxa de inversão sexual, mas temperaturas em torno de 30ºC melhoram o desempenho das tilápias quanto ao crescimento e à sobrevivência, e a dose de 40 mg de MT/kg de ração é suficiente para a obtenção de populações monossexo.
ABSTRACT
ObjectiveTo evaluate the therapeutic efficacy of low-dosage methyltestosterone or andriol in men with senile osteoporosis. MethodsA total of 134 male patients with senile osteoporosis and the decreased serum level of free testosterone were divided into three groups. 45 patients were treated with low-dosage methyhestosterone(100 mg, once a day, sublingual) and 46 patients were treated with low-dosage andriol (40 mg, once a day, orally), while 43 patients were treated with placebo. The duration of treatment in each group was 1 year. The bone density, blood and urine biochemical indexes related to bone metaholites,the quality of life indexes, ultrasonography for prostate,serum prostate specific antigen,blood routine, urine routine, hepatic and renal function were detected before and after the treatment. ResultsBoth low-dosage methyltestosterone and low-dosage andriol could prevent the decrease of bone mineral density and improve patients' general health, role-emotional function and vitality (all P<0.05). The difference values of femoral neck bone mineral density before and after treatment with low-dosage andriol and low-dosage methyltestosterone were (0.14+0.18)g/cm2 and (0.12±0.09)g/cm2 , respectively(P<0.05). Low-dosage andriol hadstronger effects in increasing the level of estradiol (32.5±14.2 )ng/L than low-dosage methyltestosterone(19.3±9.2)ng/L(P<0.05) and showed more notable effects in improving the physical functioning and role-physical function than low-dosage methyhestosterone. The use of the two androgenic hormones at low dosage showed safety. ConclusionsBoth low-dosage methyltestosterone and low-dosage andriol can be used to treat senile osteoporosis in men and to improve life quality. Both of them are effective and safe therapeutic choices.
ABSTRACT
Detrimental effects of tributyltin (TBT) chloride on the reproductive system were investigated in pubertal male rats. Sixty Sprague-Dawley rats aged with 35 days were assigned to six different groups; negative control receiving vehicle, positive control receiving methyltestosterone (10 mg/kg B.W.), TBT chloride (5 mg/kg B.W., 10 mg/kg B.W., and 20 mg/kg B.W.), and a combination of TBT chloride (10 mg/kg B.W.) and flutamide (10 mg/kg B.W). The animals were treated with test compounds by oral gavage daily for 10 days and sacrificed on the next day of the final treatment. The treatment with TBT chloride at the doses of 10 and 20 mg/kg B.W. significantly decreased seminal vesicle weights, compared to the negative control. The combined treatment of TBT chloride and flutamide caused a significant decrease in accessory sex organ weights, compared to the control and TBT chloride treatments. The treatment with TBT chloride or in the combination with flutamide increased detached debris and sloughed cells in the tubules of epididymis and narrowed seminal vesicles. In addition, the combined treatment with TBT chloride and flutamide caused a noticeable increase in serum androgen level, compared to the negative control.These results suggest that TBT chloride exposed during pubertal period cause partial reproductive disorders in male rats.
Subject(s)
Animals , Male , Rats , Body Weight , Epididymis/drug effects , Flutamide/pharmacology , Genitalia, Male/drug effects , Methyltestosterone/pharmacology , Organ Size , Prostate/drug effects , Rats, Sprague-Dawley , Seminal Vesicles/drug effects , Sexual Maturation/drug effects , Testis/drug effects , Trialkyltin Compounds/pharmacologyABSTRACT
Objective To establish an LC-MS method for identification of testosterone and methyltestosterone in cosmetic.Methods Testosterone and methyltestosterone in cosmetic were determined by liquid chromatography mass spectrometry system which can incorporate electrospray ionization interface,post-column addition agent of formic acid.Results The condition of determination was investigated and optimized.The structure of testosterone and methyltestosterone were identified by direct comparison of the observed mass spectra or by the characteristic ions in the selected-ion monitoring as well as MS2 mode.A doubtful testosterone positive cosmetic was identified by this method,it was negative.Conclusion This method has a high sensitivity and a good reproducibility.It is proved that the method is especially suitable for detection of testosterone and methyltestosterone in cosmetics.