I. Sabbagh

A biotin-avidin-based enzyme immunoassay to quantify three phytohormones: auxin, abscisic acid and zeatin-riboside

Abstract Avidin-biotin complexes have been used in an ELISA assay of three phytohormones: auxin (IAA), abscisic acid (ABA) and zeatin-riboside (ZR). Anti-hormone antibodies were elicited in rabbits immunized with hormone-bovine serum albumin conjugates. Microtitration plates coated with antigen protein were used in the ELISA method. The competition between plate-bound and free (standards or samples) antigen for a limiting amount of specific antibody results in a variable level of antibody adsorbed to the wells after washes. Such antibodies were labelled in two steps: first, incubation with biotinylated goat anti-rabbit IgG and, second, incubation with avidin-alkaline phosphatase conjugate. Bound ezyme activity was measured spectrophotometrically with p-nitrophenylphosphate and standard curves and ZR. The detection limit was 3–5 pg of plant hormone and the working range was between 10–1000 pg. This compares favourably with the best systems of analysis described in the literature. To avoid unwanted cross-reactions, a rapid and efficient HPLC purification step was included prior to measuring IAA, ABA and ZR in the same plant extract. About 100 mg fresh weight of a tomato sample could be analyzed by this technique.

Immunoelectron-microscopy localization of abscisic acid with colloidal gold on Lowicryl-embedded tissues of Chnopodium polyspermum L.

Further study on the localization of abscisic acid (ABA) has been undertaken at the ultrastructural level in Chenopodium polyspermum L. Axillary-bud-bearing nodes on the main axis were fixed with soluble 1-(3-dimethylaminopropyl)-3 ethyl carbodiimide, then postfixed with paraformaldehyde and embedded in Lowicryl K4M at-20° C. Ultrathin sections mounted on grids were successively incubated with rabbit anti-ABA antibodies and with gold-labelled goat anti-rabbit anti-bodies (40 nm particle size). Control sections treated with preimmune rabbit serum and ABA-preabsorbed antibodies were devoid of label. The background staining was very low with this technique. Quantitative analysis of the immunolabelling showed that two main sites of ABA accumulation could be defined: first, plastids in cortical cells and vascular parenchyma cells associated with sieve elements and xylem vessels; second, the cell cytoplasm and nucleus in the axillary bud tip and in procambial strands. In vascular bundles, the cambial cells showed no immunoreactivity. These observations support the hypothesis for the cytoplasmic synthesis of ABA which is subsequently trapped in plastids as cells mature.

Variations of liver prolactin receptors during the estrous cycle in normal rats and in the genetically hypoprolactinemic IPL nude rat

Ovine prolactin (oPRL) binding to liver membranes was studied during the estrous cycle in normal and in genetically hypoprolactinemic rats. Serum levels of hormones were measured by radioimmunoassay and prolactin (PRL) binding was determined using 125I-ovine PRL in the 100,000 X g pellet. Scatchard plots obtained were curvilinear throughout the estrous cycle in the normal rat. They were analyzed in reference to the co-operativity model and to the Hill model which give the factor delta and Hills coefficient (nH), respectively. During the estrous cycle, delta values varied from 3.77 +/- 0.66 on the day of estrous to 13.48 +/- 1.34 on the day of proestrus at 16.00 h. At the same time, nH were 0.97 +/- 0.033 on the day of estrus and 0.72 +/- 0.025 on the day of proestrus at 16.00 h. On the other hand, the number of PRL receptors did not change significantly throughout the estrous cycle. Moreover, the dissociation of 125I-oPRL from its receptor was accelerated by the presence of native ovine oPRL. These results suggest the presence of a negative co-operativity which reached a maximum on the day of proestrus in the normal rat. This co-operativity during the estrous cycle was not found in liver from genetically hypoprolactinemic (IPL nude) rats, which present a total absence of lactation. The delta values did not vary significantly and were 6.52 +/- 1.30 on the day of estrus and 4.41 +/- 0.52 on the day of proestrus at 16.00 h. The difference between the two rat strains was statistically significant on the day of proestrus at 16.00 h for both delta and nH values.(ABSTRACT TRUNCATED AT 250 WORDS)

Prolactin receptors in the rat mammary gland. Change during the estrous cycle.

Ovine prolactin (o-PRL) binding to mammary gland membranes was studied during the estrous cycle in the rat. Groups of rats were decapitated throughout the 4-day estrous cycle at 10 h00 on the days of diestrus I, diestrus II and estrus and at 10 h00, 12 h00, 16 h00 during the day of proestrus. Daily vaginal smears were taken to determine the stage of the estrous cycle which was also controlled by PRL and LH serum levels. Prolactin receptors were quantified in the 100 000 g pellet. For one Scatchard analysis, mammary gland membranes from 5 animals were pooled. Results given are the mean of 4 or 5 pools. Results obtained showed that the apparent affinity constant (KA) remained unchanged during the days of diestrus II and at all the times studied of proestrus and showed a slight but significant decrease on the days of estrus and diestrus I (or metestrus). The binding capacity did not vary from the day of diestrus II to the proestrus 16h00 (11.3 +/- 2.8 fmoles/mg protein) but sharply increased on the day of estrus (190.4 +/- 35.9 fmoles/mg protein). Binding capacity remained elevated on the day of diestrus I. This increase of PRL receptors on the day of estrous would appear to be an important step in preparing mammary gland for pregnancy and lactation.

Prolactin receptors in the hypoprolactinemic male rat (IPL nude rat): Measurement in testis and induction in liver

In order to evaluate the importance of PRL in the regulation of its own receptors, characteristics of specific binding for PRL were studied in membrane preparations from liver and testis of a new hypoprolactinemic male rat, the IPL nude male rat, and this was compared to those found for normal male rats. Under basal conditions, hepatic specific binding of PRL in IPL nude rats, as in normal rats was not detectable. Following castration, it became detectable in both groups, and was 6.99 +/- 0.78% and 6.34 +/- 0.87% for IPL nude and normal rats respectively. Under such conditions, the apparent affinity constant (Ka) and the binding capacity (Nmax) obtained were also similar for both groups (Ka) = 1.36 +/- 0.14.10(9) M-1, Nmax = 102 +/- 14 fmol/mg protein in IPL and Ka = 1.34 +/- 0.28.10(9) M-1, Nmax = 97 +/- 11 fmol/mg protein in normal rats) although a decrease in serum levels of PRL was observed in both groups. This decrease was greater for IPL nude rats. As already reported, estradiol injection following castration was able to further increase the percentage of PRL hepatic specific binding (4 times). Furthermore, our results demonstrated that the affinity constant was significantly increased by estradiol injection in both groups. On the other hand, for testicular PRL binding characteristics, a statistically significant difference was found between IPL nude and normal rats. The PRL specific binding percentage was 7.01 +/- 0.85% for the IPL nude rat and 10.07 +/- 0.64% for the normal rat. By Scatchard analysis, the Ka of testicular membranes for labelled oPRL was similar in both groups, while the capacity differed (Nmax = 9.82 +/- 1.25 fmol/mg protein for IPL nude rat and Nmax = 26.06 +/- 4.39 fmol/mg protein for normal rats). These data established the fact that IPL nude male rats presented characteristics of hepatic PRL receptors similar to those of normal rats, while their testicular oPRL binding significantly differed. These findings therefore suggest that in genetic hypoprolactinemic rats (IPL nude rats), PRL might be more involved in the regulation of testicular PRL receptors than in that of hepatic receptors.

Variations of liver prolactin receptors during pregnancy in normal rats and in the genetically hypoprolactinemic IPL nude rat

Ovine prolactin (oPRL) binding to liver membranes was studied during pregnancy in normal and in genetically hypoprolactinemic rats. Prolactin (PRL) binding was determined using 125I-oPRL in the 100,000 x g pellet. Scatchard plots obtained changed throughout the pregnancy in the normal rat, being almost linear from days 2 to 10, becoming curvilinear (convex) on day 16, and linear again at the end of pregnancy. They were analyzed with reference to the co-operativity and Hill models, which give delta and nH, respectively. During pregnancy, delta values varied and were respectively 2.48 +/- 0.66, 1.84 +/- 0.64, 0.52 +/- 0.06 and 1.69 +/- 0.25 on days 3, 10, 16 and 22, and the delta value on day 16 was significantly different from other days; the nH value estimated on day 16 was 1.10 +/- 0.031. These results suggest the presence of a positive co-operativity on day 16 of pregnancy. Over the same period, a huge increase in the capacity occurred on day 10 and reached a maximum on day 14. It remained elevated until the day before parturition. In the IPL nude rat, the delta value (0.92 +/- 0.45) on day 16 was significantly different from that of normal rats and indicated an absence of positive co-operativity on this day in the IPL nude rat liver. This finding was confirmed by an nH value (0.99 +/- 0.39) close to 1. The PRL-binding capacity was similar to that of normal rats, except on day 14, where it was significantly decreased. These results are discussed in relation to hormonal variations during pregnancy, particularly with regard to serum PRL and placental lactogen values.(ABSTRACT TRUNCATED AT 250 WORDS)

Thyroid-Hypophyso-Hypothalamic Axis of the Genetically Hypoprolactinemic Rats (IPL Nude Rats)

In order to evaluate thyrotropin function in the genetically hypoprolactinemic rat, (IPL nude), we measured by radioimmunoassay TRH hypothalamic content, pituitary TSH content and serum TSH, T3, T4, both in IPL nude and control rats at various times over the 24-hour period. Compared to normal rats, the hypothalamic TRH content in the IPL nude rat showed similar variations during the day, whereas a slight increase was observed during the night characterized by a significant difference at 20.00 h. Pituitary weight and TSH content were doubled in IPL nude rats; however, when expressed as micrograms TSH/micrograms protein or DNA, a significant increase was found only at 17.00 and 20.00 h. Serum TSH and total serum T3, T4 depicted similar variations although they were minute but nonetheless significant modifications, i.e. an increase of TSH at 17.00 and 23.00 h and a decrease of T4 at 11.00 h. However, only FT4 concentrations (and not-FT3) were slightly but significantly decreased in IPL rats over the experimental times. In conclusion, the slight increase in hypothalamic TRH and pituitary TSH contents and the absence of main associated variations of serum TSH, T3 and T4 do not lend support to the hypothesis that TRH could be the cause of the hypoprolactinemia of these rats. On the contrary, the observed thyrotropin axis variations might be rather interpreted as the consequence of it.

Prolactin receptor regulation by LH in the rat mammary gland.

The aim of this study was to investigate hormonal factors responsible for the huge increase in PRL receptors on the day of estrus in the rat mammary gland. For this purpose, ovariectomized rats were primed with E2 so as to reach a physiological serum concentration of E2 (21.5 +/- 1.2 pg/ml) and high PRL serum values (72.8 +/- 21.9 ng/ml). In these conditions, PRL specific binding and capacity were respectively 22.8 +/- 8.3%/mg protein and 96 +/- 29 fm/mg protein. An injection of either LHRH (500 ng/rat) or LH (60 micrograms LH-RP1/rat) was capable of increasing significantly both PRL specific binding and capacity. Capacity reached the values of 498 +/- 103 and 507 +/- 240 fm/mg protein for LHRH and LH respectively. LHRH action appeared to be mainly mediated through LH secretion, since no difference was found between LHRH and LH. LHRH and LH injections alone were unable to modify PRL binding, suggesting that they only potentiate E2 and PRL action. These results show for the first time that LH is involved in the regulation of PRL receptors in the rat mammary gland.

Beta-endorphin in genetically hypoprolactinemic rat: IPL nude rat

Beta-endorphin has been reported to regulate not only stress- and suckling-induced but also basal prolactin secretion. In the aim to better evaluate the endogenous beta-endorphin-prolactin interrelation, we measured beta-endorphin levels in a new rat strain, genetically hypoprolactinemic and characterized by a total lack of lactation: IPL nude rat. Beta-endorphin was measured using a specific anti-h-beta endorphin in plasma and extracts of anterior and neurointermediate lobes of the pituitary, hypothalamus and brain. Pituitary extracts were also chromatographed on Sephadex G50 column. Results obtained showed that in IPL nude females on diestrus and males, the beta-endorphin contents of the neurointermediate lobe was significantly lower than in normal rats, while the values found in the other organs and plasma were similar. However, elution pattern of the anterior pituitary extract from male rats showed greater immunoactivity eluting as I125 h-beta-endorphin than in normal rat; this was not the case for the female rat. These results are consistent with a differential regulation of beta-endorphin levels of anterior and neurointermediate lobe by catecholamines. Moreover they suggest that PRL secretion was more related to neurointermediate beta-endorphin.

Steroid regulation of gonadotropins in genetically hypoprolactinemic females (IPL nude rats)

IPL nude females present an absence of lactation with hypoprolactinemia. While males present a slight but significant decrease in serum testosterone and gonadotropins, females show normal values of estradiol, progesterone, LH and FSH during all estrus cycle stages. In this work, we observed that the postovariectomy rise of LH and FSH was significantly lower in the IPL nude females. We studied also the effect of acute (1 injection of 25 micrograms/rat E2Bz) or long-term (E2Bz capsule for 8 days) estradiol benzoate (E2Bz) treatment, with or without progesterone injection (5 mg/rat) in ovariectomized (OVX) IPL and normal females. The sensitivity of gonadotropins to E2 negative feedback is decreased in the IPL nude rats, result in agreement with previous reports and which could be linked to both hypoprolactinemia and decreased beta-endorphin observed in the IPL nude rat. The responsiveness of LH to LHRH was also tested in OVX and OVX + E2Bz or OVX + E2B + P treated. In OVX females responsiveness of LH to LHRH was similar in IPL nude to that of normal females. However, LH responsiveness in acute and long-term steroid-treated OVX IPL nude was significantly depressed. Since the mechanism whereby PRL interacts with steroids to modify gonadotropin secretion is still unexplained, IPL nude rat could be a good model to study it.