Sexual differentiation of gonads as a function of temperature in the turtle Emys orbicularis: endocrine function, intersexuality and growth.

Emys orbicularis is a freshwater turtle with temperature-dependent sex determination. Estrogens play a major role in gonadal differentiation; when they are produced at high levels during the thermosensitive period (TSP), ovaries differentiate; when their synthesis is very low, testes differentiate. Estrogens are synthesized from androgens through the activity of aromatase. We examine here two aspects of gonadal differentiation, intersexuality and growth, in E. orbicularis. For gonadal intersexuality, we studied the relationship between gonadal aromatase activity and gonadal structure at 28.5 degrees C (pivotal temperature), from the beginning of TSP to hatching, and compared results to those obtained at 30 degrees C (producing 100% females) and 25 degrees C (producing 100% males). At 28.5 degrees C, both males and females are obtained. However, histological differentiation of gonads is delayed compared to that at 25 degrees C and 30 degrees C, and an ovarian-like cortex of various thicknesses often develops at the surface of the male gonads; thus, several individuals display ovotestes at hatching. Despite important individual variations, the aromatase activity in ovaries differentiating at 28.5 degrees C increases during development as in ovaries differentiating at 30 degrees C. In most cases, however, activity is slightly lower than at 30 degrees C, and at the end of embryonic life, it becomes similar to that at 30 degrees C. In testes or ovotestes differentiating at 28.5 degrees C, aromatase activity remains low but is generally slightly higher than in testes at 25 degrees C; however, at the end of embryonic development, it becomes similar to that at 25 degrees C. Oocytes in the cortex of ovotestes begin to degenerate around hatching and continue to degenerate after hatching. Therefore, ovotestes evolve as testes. However, some oocytes may persist at the surface of testes up to the adult age. To estimate gonadal growth, the protein content was measured at different embryonic stages at 25 degrees C and at 30 degrees C. Testis growth is fast during TSP, somewhat slower after TSP, and decreases around hatching. Ovary growth is much slower than testis growth during TSP and then accelerates up to the end of embryonic development. This differential growth is well correlated with gonadal aromatase activity--much higher at 30 degrees C than at 25 degrees C--and can be explained by the fact that during TSP, testicular cords develop at 25 degrees C whereas they are inhibited at 30 degrees C; the ovarian cortex begins to form during this period but grows chiefly after TSP. Both inhibition of testicular cord development and stimulation of cortex development are under the control of endogenous estrogens. In the case of ovotestes, slight increases in estrogen synthesis, compared to that in typical testes, are sufficient to induce the transient formation of an ovarian-like cortex although they do not inhibit the development of testicular cords.

Endocrine sex reversal of gonads by the aromatase inhibitor Letrozole (CGS 20267) in Emys orbicularis, a turtle with temperature-dependent sex determination.

In embryos of Emys orbicularis, the sexual differentiation of gonads is influenced by the incubation temperature of eggs. Estrogens administered during the thermosensitive period result in the feminization of gonads at 25 degrees (male-producing temperature), whereas an antiestrogen or aromatase inhibitors masculinize the gonads at 30 degrees (female-producing temperature). The nonsteroidal aromatase inhibitor Letrozole induces gonads with different degrees of masculinization, from ovary-like to testis-like. The present study examines the endocrine function of such masculinized gonads, at the end of embryonic life. Aromatase activity (which is involved in estrogen synthesis in ovary) and the status of Müllerian ducts (the regression of which reflects the secretion of a putative anti-Müllerian hormone by the Sertoli cells) were examined. One month after treatment with Letrozole, the gonads of embryos presented various levels of aromatase activity. There was a strong correlation among aromatase activity, gonadal structure, and Müllerian duct status; high levels of aromatase (similar or close to those in control females) were found in ovary-like gonads; intermediate levels were found in gonads (masculinized ovaries or ovotestes?) exhibiting a cortex and a composite medulla containing a mixture of ovarian lacunae and testicular cord-like structures; low levels (similar or close to those in control males) were found in strongly masculinized gonads (testis-like or ovotestes). Müllerian ducts were regressing in the majority of embryos with gonads containing low levels of aromatase activity. In these individuals, gonads functioned as embryonic testes. These results confirm the implication of estrogens in gonadal differentiation. The origin of these hormones is controversial, so that the aromatase activity was compared in gonads, in the undissociated adrenal-mesonephric complex (AM), and in different parts of this complex during the thermosensitive period. At the female-producing temperature, the aromatase activity per unit of tissue increased in differentiating ovaries but it was low in AM and similar to that found in AM at male-producing temperature. In embryos whose gonads had been masculinized by early treatment with Letrozole, aromatase activity was unchanged in AM. These results suggest that the main source of estrogens involved in ovarian differentiation is the gonad itself.

Aromatase activity in larval gonads of Pleurodeles waltl (Urodele Amphibia) during normal sex differentiation and during sex reversal by thermal treatment effect.

Estrogens are involved in gonadal differentiation in birds and in reptiles with temperature-dependent sex determination, suggesting a key role for aromatase, the enzyme complex converting androgens to estrogens. Pleurodeles waltl is an amphibian with ZZ/ZW genotypic sex determination but gonadal differentiation is thermosensitive. The sexual phenotype is in conformity with the sexual genotype at ambient temperature (20 +/- 2 degrees), but ZW animals are sex-reversed in functional males when larvae are reared at 32 degrees from stage 42 to stage 54 (thermosensitive period). Histological sexual differentiation of gonads begins at stage 53. Aromatase activity was measured either in the gonadmesonephric complexes (stages 47 to 52) or in the gonads (stages 53 to 56) of ZZ and ZW larvae reared at ambient temperature or at 32 degrees and of ZW larvae shifted at stages 53, 55, or 56 from ambient temperature to 32 degrees for 48 hr. At ambient temperature, aromatase activity was detected, at low levels, in gonad-mesonephric complexes of both ZZ and ZW larvae at stages 47 and 50. At stage 52, it was significantly higher in ZW individuals than in ZZ ones. Then it remained low in gonads of ZZ males, whereas it markedly increased in gonads of ZW females. At 32 degrees, the gonad-mesonephric complexes (stage 52) and the gonads (stages 53 to 56) of ZW larvae had low aromatase activity similar to that in ZZ individuals. The exposure to 32 degrees for 48 hr of ZW individuals significantly decreased gonadal aromatase activity during the thermosensitive period (shift at stage 53) but not after the thermosensitive period (shifts at stages 55 and 56).(ABSTRACT TRUNCATED AT 250 WORDS)

Sensitive stages for the effects of temperature on gonadal aromatase activity in embryos of the marine turtle Dermochelys coriacea.

Many data suggest an involvement of estrogens in gonadal differentiation in reptiles with temperature-dependent sex determination (TSD). However, the site of estrogen synthesis in two species of freshwater turtles is unclear. In Emys orbicularis, estrogens were shown to be produced by the gonads, whereas in Trachemys scripta, gonadal steroids were not detected. The marine turtle Dermochelys coriacea exhibits TSD but in gonadal development, ovarian differentiation is delayed. Gonadal aromatase activity and estrogen content in this species were measured in embryos incubated at 27 degrees and in embryos incubated at 30.5 degrees, respectively, masculinizing and feminizing temperatures within the range of temperatures found in natural nests. At all stages studied, aromatase activity was present and found to be higher at 30.5 degrees than at 27 degrees. Estrogens were only found at 30.5 degrees. The effects of temperature shifts on gonadal aromatase activity were then examined. Eggs were shifted from 27 to 35 degrees (feminizing temperature) at different embryonic stages and exposed to 35 degrees for 6 days. An increase in gonadal aromatase activity, although with significant individual variations, was seen only when eggs were shifted between stages 23 and 27. These stages are in the range of the thermosensitive stages for sexual differentiation of the gonads determined in other turtles. These results are similar to those previously obtained in E. orbicularis and agree with a key role for endogenous estrogens in gonadal differentiation of reptiles with TSD.(ABSTRACT TRUNCATED AT 250 WORDS)

Aromatase activity in gonads of turtle embryos as a function of the incubation temperature of eggs.

In embryos of the European pond turtle, sexual differentiation of gonads is temperature-dependent. Production of oestrogens appears to play a key role in this phenomenon. Gonadal aromatase activity was measured in embryos incubated at 25 degrees C (masculinizing temperature) and at 30 degrees C (feminizing temperature). At the beginning of the thermosensitive period, the aromatase activity was low at both temperatures but was somewhat higher at 30 than at 25 degrees C. Afterwards, it remained low in differentiating testes at 25 degrees C, whereas it increased in differentiating ovaries at 30 degrees C to form a marked peak when germ cells underwent meiotic prophase. Eggs were shifted either from 25 to 30 degrees C (highly feminizing) or from 30 to 35 degrees C for 6 days at different stages of embryonic development. The 25-35 degrees C shifts performed during the thermosensitive period strongly increased the aromatase activity but were ineffective after this period. The 30-35 degrees C shifts increased the aromatase activity at all stages. Altogether, results indicate that, in differentiating gonads of turtle embryos, temperature acts on the regulation of synthesis (and therefore activity) of cytochrome P-450 aromatase (P-450-aro). The expression of the P-450-aro gene itself could be temperature-dependent. However, temperature could also act upon the expression of another gene involved in P-450-aro regulation.

Steroid metabolism in gonads of turtle embryos as a function of the incubation temperature of eggs.

In embryos of many reptiles, the sexual differentiation of gonads is temperature-dependent. In the turtle Emys orbicularis, all individuals become phenotypic males at 25 degrees C, whereas 100% phenotypic females are obtained at 30 degrees C. Steroid metabolism in embryonic gonads was studied at both temperatures, during and after the thermosensitive period for sexual differentiation. Pools of gonads were incubated for various times, with 3 beta-hydroxy-5-pregnen-20-one (pregnenolone), progesterone, dehydroepiandrosterone or 4-androstene-3,17- dione as substrates. The analysis of metabolites combined two successive chromatographies (HPLC and TLC) and autoradiography. Conversion of pregnenolone to progesterone and of dehydroepiandrosterone to 4-androstene-3,17-dione was more important in testes at 25 degrees C than in ovaries at 30 degrees C. In ovaries, a large amount of 5-pregnene- 3 beta,20 beta-diol was formed from pregnenolone, and 5-androstene-3 beta,17 beta-diol was produced from dehydroepiandrosterone. In both testes and ovaries, 5 alpha-pregnane and 5 alpha-androstane derivatives were the main metabolites obtained from progesterone and 4-androstene-3,17-dione, respectively. Progesterone was also converted to 20 beta-hydroxy-4-pregnen-3-one. Dehydroepiandrosterone and 4-androstene-3,17-dione were also metabolized into 11 beta-hydroxy-4-androstene-3,17-dione (only in testes), testosterone, 11 beta,17 beta-dihydroxy-4-androstene-3-one, 17 beta-hydroxy-4-androstene-3,11-dione (low amounts in testes, traces in ovaries), 17 alpha-hydroxy-4-androstene-3-one, estrone and estradiol-17 beta (traces).

Inactivation of human high- and low-molecular-weight urokinases. Analysis of their active site.

We previously demonstrated that 3,4-dihydro-3,4-dibromo-6-bromomethylcoumarin (dihydrocoumarin I) inhibited high-molecular-weight urokinase through a mechanism-based (suicide) inactivation (M. Reboud-Ravaux, G. Desvages and F. Chapeville (1982) FEBS Lett. 140, 58-62). In order to define the site of alkylation, peptic peptides were prepared from urokinase (heavy form) treated first by tritiated dihydrocoumarin I. After separation by reverse-phase HPLC, the labelled fragments were sequenced. His-46 in the B-chain of urokinase (heavy form) had been selectively alkylated, proving that this amino acid forms part of the active site. 3,4-Dihydro-3-benzyl-6-chloromethylcoumarin (dihydrocoumarin II) was more reactive than dihydrocoumarin I against urokinase (heavy form) by a factor of 130. Low-molecular-weight urokinase was inactivated by dihydrocoumarin II slightly more slowly than urokinase (heavy form), showing a decrease of 30% in the corresponding second-order rate constant. In contrast, dihydrocoumarin I displayed an analogous reactivity against light and heavy forms of urokinase. As expected, in the absence of the alkylating moiety, such as in 3,4-dihydro-3-benzylcoumarin (dihydrocoumarin III), no inactivation was observed. It is note-worthy that dihydrocoumarin II which carried an extra-aromatic group fitted well within the active site of light and heavy urokinases, suggesting a nonpolar character for their primary binding site.

Structural studies on yeast 3-phosphoglycerate kinase. Identification by immuno-affinity chromatography of one glutamyl residue essential for yeast 3-phosphoglycerate kinase activity. Its location in the primary structure.

3-Phosphoglycerate kinase is inactivated by 1-cyclohexyl-3-(2-morpholinoethyl)carbodiimide metho-p-toluenesulfonate and nitrotyrosine ethyl ester. The coupling of 1 mol nitrotyrosine/mol enzyme is sufficient to inactivate the protein completely. A weak protection against inactivation is observed with each substrate added separately. In contrast, the complex ATP--3-phosphoglycerate--enzyme or ATP--Mg--3-phosphoglycerate--enzyme affords a considerable protection. The critical residue is identified as a glutamyl residue after isolation by immuno-affinity chromatography of nitrotyrosyl peptide resulting from exhaustive proteolytic digestion of the modified protein. In addition, the determination of the primary sequence of the C-terminal part of the protein leads to the location of the glutamyl residue at position eight from the C-terminus. We conclude that this glutamyl residue is situated in the domain which does not bind the nucleotide substrates [Bryant, T.N., Watson, H.C. and Wendell, P.L. (1974) Nature (Lond.) 247, 14--17]. Its role in the catalysis process is discussed.

Structural studies on yeast 3-phosphoglycerate kinase. Isolation by affinity chromatography and characterization of the peptides produced by cyanogen bromide cleavage. Location of the single cysteinyl residue in the primary structure.

Cyanogen bromide cleavage of yeast 3-phosphoglycerate kinase yielded four fragments which account for the amino acid composition of the entire molecule. These results are consistent with a single polypeptide chain of molecular weight 42 000. Affinity chromatography on Sepharose-mercurial followed by gel filtration on Sephadex was used with success for separation of peptides. The carboxyl and N-terminal fragments were characterized. The N-terminal fragment contained the single cysteinyl residue of the protein. After cyanylation and subsequent cleavage, this cysteinyl residue was located near position 100.

[Location of cysteine in primary structure of yeast 3-phosphoglycerate kinase]. / Position de la cystéine dans la structure primaire de la 3-phosphoglycérate kinase de lavure.

In order to study the location of the single cysteinyl residue in the primary structure of yeast 3-phosphoglycerate kinase, cyanylation by 2-nitro-5-thiocyanobenzoic acid has bben carried out. Analysis of the two fragments obtained shows that the--SH group is located near position 100.

[Identification of an essential glutamate residue in the 3-phosphoglycerate kinase of yeast]. / Identification du groupement glutamique essentiel de la 3-phosphoglycérate kinase de levure.

The incorporation of nitrotyrosine into 3-phosphoglycerate kinase activated by carbodiimide results in the chemical modification of a single essential residue. After total proteolytic digestion, isolation of the dipeptide gamma Glu-NO2 Tyr by immuno-affinity chromatography indicates the implication of a glutamyl residue. It is interesting to point out the applicability of the method described for the purification of peptides containing carboxyl residues.