Balint Kacsoh

Involvement of prolactin in the REM sleep-promoting activity of systemic vasoactive intestinal peptide (VIP)

The involvement of pituitary prolactin (PRL) in systemic vasoactive intestinal peptide (VIP)-induced sleep was studied. Male rats were implanted with electrodes for EEG-recording, with brain thermistors to record cortical temperature (Tcrt) and with chronic intracardial catheters to obtain blood samples and to deliver substances. One group of rats (n = 8) received normal rabbit serum (NS)+physiological saline (SAL) on the baseline day and was injected with NS+VIP on the experimental day. In the other group of rats (n = 6), the baseline day was followed by administration of PRL-antiserum (PRL-AS) + VIP on the experimental day. The sera and VIP or SAL were injected 30 min before and at light onset, respectively. Sleep-wake activity was then recorded for the next 12-h light period. Systemic VIP-stimulated PRL secretion as measured by RIA in serial samples obtained hour 1 postinjection. VIP also elicited selective increases in REM sleep (REMS) in the rats pretreated with NS. Tcrt was not affected by VIP. Administration of PRL-AS blocked the increase in circulating levels of free (non-IgG-bound) PRL and prevented VIP-enhanced REMS. Comparisons of the sleep effects of PRL-AS+VIP with the previously reported changes in sleep after PRL-AS alone indicate that PRL has a major role in the mediation of the REMS-promoting activity of systemic VIP. The results suggest that an increased release of endogenous pituitary PRL modulates REMS.

Increase of prolactin mRNA in the rat hypothalamus after intracerebroventricular injection of VIP or PACAP

Vasoactive intestinal peptide (VIP), the structurally homologous pituitary adenylate cyclase-activating peptide (PACAP) and the pituitary hormone, prolactin (PRL) enhance rapid eye movement sleep (REMS). VIP and PACAP are both inducers of PRL gene expression and release in the pituitary gland. Little is known about PRL regulation in the brain although it is hypothesized that the REMS-promoting activity of i.c.v. administered VIP may be mediated via the activation of cerebral PRL. To test whether VIP or PACAP in fact increase intracerebral mRNA, the peptides (VIP: 30 or 300 pmol; PACAP: 220 pmol) were injected i.c.v. into rats at dark onset. 1 h later, cDNA was synthesized from purified hypothalamic mRNA. Standardized amounts were analysed for PRL using the polymerase chain reaction followed by Southern blotting and hybridization. Compared with beta-actin mRNA levels, both VIP and PACAP increased PRL mRNA levels in a dose-dependent fashion though VIP was more effective on a molar basis. The previously reported alternatively spliced PRL mRNA (lacking exon 4) was not detected. The data support the hypothesis that the REMS-promoting activity of central VIP and PACAP might be mediated by cerebral PRL.

Sleep in rats rendered chronically hyperprolactinemic with anterior pituitary grafts

A hyperprolactinemic rat model [rats bearing anterior pituitary grafts under the capsule of the kidney (AP-grafted rats)] was used to study sleep-wake activity and cortical brain temperature (T(crt)). Fisher 344 male rats (n = 24) were implanted with anterior pituitaries from rat pups; the control rats (n = 12) were sham-operated. Sleep-wake activity and T(crt) were recorded for 2 days between weeks 3 and 7 after surgery. The hyperprolactinemic state of the rats was confirmed by plasma prolactin (PRL) assays on week 7 and by determination of PRL mRNA levels in the anterior pituitary of the AP-grafted rats. Neither growth hormone plasma concentration nor pituitary mRNA levels were affected by the pituitary grafts. Duration of non-rapid eye movement sleep (NREMS) was slightly enhanced in the AP-grafted rats. A large increase in rapid eye movement sleep (REMS) during the 12-h light period was the major effect of the implantation of the extra pituitaries. Both the duration and the frequency of the REMS episodes increased and persisted for weeks 4-7 post-implantation. The nocturnal states of vigilance, T(crt), and intensity of NREMS (EEG slow wave activity) were not altered. The results clearly indicate that the enhancements in REMS persist during hyperprolactinemia, and support the hypothesis that PRL possesses REMS-promoting activity.

Rapid Eye Movement Sleep Is Reduced in Prolactin-Deficient Mice

Prolactin (PRL) is implicated in the modulation of spontaneous rapid eye movement sleep (REMS). Previous models of hypoprolactinemic animals were characterized by changes in REMS, although associated deficits made it difficult to ascribe changes in REMS to reduced PRL. In the current studies, male PRL knock-out (KO) mice were used; these mice lack functional PRL but have no known additional deficits. Spontaneous REMS was reduced in the PRL KO mice compared with wild-type or heterozygous littermates. Infusion of PRL for 11-12 d into PRL KO mice restored their REMS to that occurring in wild-type or heterozygous controls. Six hours of sleep deprivation induced a non-REMS and a REMS rebound in both PRL KO mice and heterozygous littermates, although the REMS rebound in the KOs was substantially less. Vasoactive intestinal peptide (VIP) induced REMS responses in heterozygous mice but not in KO mice. Similarly, an ether stressor failed to enhance REMS in the PRL KOs but did in heterozygous littermates. Finally, hypothalamic mRNA levels for PRL, VIP, neural nitric oxide synthase (NOS), inducible NOS, and the interferon type I receptor were similar in KO and heterozygous mice. In contrast, tyrosine hydroxylase mRNA was lower in the PRL KO mice than in heterozygous controls and was restored to control values by infusion of PRL, suggesting a functioning short-loop negative feedback regulation in PRL KO mice. Data support the notion that PRL is involved in REMS regulation.

Structure/function aspects of human 3β-hydroxysteroid dehydrogenase

Separate genes encode the human type 1 (placenta, breast tumors, other peripheral tissues) and type 2 (gonad, adrenal) isoforms of 3 beta-hydroxysteroid dehydrogenase/isomerase (3 beta-HSD1, 3 beta-HSD2). Mutagenesis of 3 beta-HSD1 produced the Y154F, H156Y and K158Q mutant enzymes in the probable Y(154)-P-H(156)-S-K(158) catalytic motif. The H(156)Y mutant of the 3 beta-HSD1 created a chimera of the 3 beta-HSD2 motif (Y(154)-P-Y(156)-S-K(158)) in 3 beta-HSD1. The D241N, D257L, D258L and D265N mutants are in the potential isomerase site of the 3 beta-HSD1 enzyme. Homology modeling with UDP-galactose-4-epimerase predicted that Asp(36) in the Rossmann-fold domain is responsible for the NAD(H) specificity of human 3 beta-HSD1, and our D36A/K37R mutant tested that assignment. The H(156)Y mutant of the 3 beta-HSD1 enzyme shifted the substrate (DHEA) kinetics to the 14-fold higher K(m) value measured for the 3 beta-HSD2 activity. From Dixon analysis, epostane inhibited the 3 beta-HSD1 activity with 17-fold greater affinity compared to 3 beta-HSD2 and H(156)Y. The mutants of Tyr(154) and Lys(158) exhibited no dehydrogenase activity and appear to be catalytic 3 beta-HSD residues. The D257L and D258L mutations eliminated isomerase activity, suggesting that Asp(257) or Asp(258) may be catalytic residues for isomerase activity. The D36A/K37R mutant shifted the cofactor preference of both 3 beta-HSD and isomerase from NAD(H) to NADP(H). In addition to characterizing catalytic residues, these studies have identified the structural basis (His(156)) for an exploitable difference in the substrate and inhibition kinetics of 3 beta-HSD1 and 3 beta-HSD2. Hence, it may be possible to selectively inhibit human 3 beta-HSD1 to slow the growth of hormone-sensitive breast tumor cells and control placental steroidogenesis near term to prevent premature labor.

The higher affinity of human type 1 3β-hydroxysteroid dehydrogenase (3β-HSD1) for substrate and inhibitor steroids relative to human 3β-HSD2 is validated in MCF-7 tumor cells and related to subunit interactions

Two distinct genes encode the tissue‐specific expression of the two isoforms of human 3β‐hydroxysteroid dehydrogenase: 3β‐HSD1 (placenta, mammary gland, breast tumors) and 3β‐HSD2 (gonads, adrenals). Purified 3β‐HSD1 utilizes DHEA as a substrate with 13‐fold lower Km than 3β‐HSD2. Using homogenates of human MCF‐7 Tet‐off breast tumor cells stably transfected with human 3β‐HSD1 or 3β‐HSD2, DHEA is utilized as substrate by 3β‐HSD1 (Km = 4.8 µM) much more avidly than by 3β‐HSD2 (Km = 43 µM). In addition, the 3β‐HSD inhibitor, epostane, binds to purified 3β‐HSD1 with a 17‐fold higher affinity compared to 3β‐HSD2. In the MCF‐7 cells, two 3β‐HSD inhibitors block 3β‐HSD1 activity (Ki = 0.06 µM, epostane; 0.08 µM, trilostane) with 12‐ to 14‐fold higher affinities compared to the inhibition of 3β‐HSD2 (Ki = 0.85 µM, epostane; 1.01 µM, trilostane). Thus, the substantially higher affinities of human 3β‐HSD1 for substrate and inhibitor steroids measured using the pure isoenzymes have been validated using microsome‐bound 3β‐HSD1 and 3β‐HSD2 in the MCF‐7 cells. Similar to our previously reported H156Y mutant of 3β‐HSD1, the Q105M mutant of 3β‐HSD1 shifts the substrate and inhibitor kinetic profiles to those of wild‐type 3β‐HSD2. However, the Q105M mutant of 3β‐HSD2 retains the substrate and inhibitor kinetic profiles of wild‐type 3β‐HSD2. Our structural homology model of human 3β‐HSD predicts that Gln105 on one enzyme subunit hydrogen‐binds to His156 on the other subunit of the enzyme homodimer. The higher affinity of 3β‐HSD1 for the steroids may be related to different subunit interactions in the quaternary structures of the two isoenzymes. It may be possible to exploit these kinetic differences to selectively inhibit the conversion of DHEA ultimately to estradiol by 3β‐HSD1 and slow the growth of breast tumor cells.

Selective inhibition of human 3β-hydroxysteroid dehydrogenase type 1 as a potential treatment for breast cancer.

Human 3β-hydroxysteroid dehydrogenase/isomerase type 1 (3β-HSD1) is a critical enzyme in the conversion of DHEA to estradiol in breast tumors and may be a target enzyme for inhibition in the treatment of breast cancer in postmenopausal women. Human 3β-HSD2 participates in the production of cortisol and aldosterone in the human adrenal gland in this population. In our recombinant human breast tumor MCF-7 Tet-off cells that express either 3β-HSD1 or 3β-HSD2, trilostane and epostane inhibit the DHEA-induced proliferation of MCF-7 3β-HSD1 cells with 12-16-fold lower IC(50) values compared to the MCF-7 3β-HSD2 cells. Trilostane and epostane also competitively inhibit purified human 3β-HSD1 with 12-16-fold lower K(i) values compared to the noncompetitive K(i) values measured for human 3β-HSD2. Using our structural model of 3β-HSD1, trilostane was docked in the active site of 3β-HSD1, and Arg195 in 3β-HSD1 or Pro195 in 3β-HSD2 was identified as a potentially critical residue. The R195P-1 mutant of 3β-HSD1 and the P195R-2 mutant of 3β-HSD2 were created, expressed and purified. Kinetic analyses of enzyme inhibition suggest that the high-affinity, competitive inhibition of 3β-HSD1 by trilostane may be related to the presence of Arg195 in 3β-HSD1 versus Pro195 in 3β-HSD2. In addition, His156 in 3β-HSD1 may play a role in the higher affinity of 3β-HSD1 for substrates and inhibitors compared to 3β-HSD2 containing Try156. Structural modeling of the 3β-HSD1 dimer identified a possible interaction between His156 on one subunit and Gln105 on the other. Kinetic analyses of the H156Y-1, Q105M-1 and Q105M-2 support subunit interactions that contribute to the higher affinity of 3β-HSD1 for the inhibitor, epostane, compared to 3β-HSD2. Article from the Special issue on Targeted Inhibitors.

Structural basis for the selective inhibition of human 3β-hydroxysteroid dehydrogenase 1 in human breast tumor MCF-7 cells

Human 3beta-hydroxysteroid dehydrogenase/isomerase type 1 (3beta-HSD1) is a critical enzyme in the conversion of DHEA to estradiol in breast tumors and may be a target enzyme for inhibition in the treatment of breast cancer in postmenopausal women. Human 3beta-HSD2 participates in the production of cortisol and aldosterone in the human adrenal gland in this population. In our recombinant human breast tumor MCF-7 Tet-off cells that express either 3beta-HSD1 or 3beta-HSD2, trilostane and epostane inhibit the DHEA-induced proliferation of MCF-7 3beta-HSD1 cells with 12- to 16-fold lower IC(50) values compared to the MCF-7 3beta-HSD2 cells. The compounds also competitively inhibit purified human 3beta-HSD1 with 12- to 16-fold lower K(i) values compared to the noncompetitive K(i) values measured for human 3beta-HSD2. Using our structural model of 3beta-HSD1, trilostane or 17beta-acetoxy-trilostane was docked in the active site of 3beta-HSD1, and Arg195 in 3beta-HSD1 or Pro195 in 3beta-HSD2 was identified as a potentially critical residue (one of 23 non-identical residues in the two isoenzymes). The P195R mutant of 3beta-HSD2 were created, expressed and purified. Kinetic analyses of enzyme inhibition suggest that the high affinity, competitive inhibition of 3beta-HSD1 by trilostane and epostane may be related to the presence of Arg195 in 3beta-HSD1 vs. Pro195 in 3beta-HSD2.

Sleep in spontaneous dwarf rats

Spontaneous dwarf rats (SDRs) display growth hormone (GH) deficiency due to a mutation in the GH gene. This study investigated sleep in SDRs and their somatotropic axis and compared to Sprague-Dawley rats. SDRs had almost undetectable levels of plasma GH. Hypothalamic GH-releasing hormone (GHRH) mRNA was increased, whereas GHRH-receptor (GHRH-R) and somatostatin mRNAs were decreased in SDRs. Hypothalamic GHRH and somatostatin peptide content decreased in SDRs. Quantitative immunohistochemistry for GHRH and GHRH-R corroborated and extended these findings. In the arcuate nucleus, the number of GHRH-positive cells was significantly higher, whereas GHRH-R-positive perikarya were diminished in SDRs. Cortical GHRH and GHRH-R measurements showed similar expression characteristics as those found in the hypothalamus. SDRs had less rapid eye movement sleep (REMS) and more non-REMS (NREMS) than the control rats during the light period. The electroencephalogram (EEG) delta and theta power decreased during NREMS in the SDRs. After 4-h of sleep deprivation, SDRs had a significantly reduced REMS rebound compared to the controls, whereas NREMS rebound was normal in SDRs. The enhancement in delta power was significantly less than in the control group during recovery sleep. Intracerebroventricular (icv) administration of GHRH promoted NREMS in both strains of rats; however, increased REMS and EEG delta activity was observed only in control rats. Icv injection of insulin-like growth factor 1 increased NREMS in control rats, but not in the SDRs. These results support the ideas that GHRH is involved in NREMS regulation and that GH is involved in the regulation of REMS and in EEG slow wave activity regulation during NREMS.

Prolactin-like biological activity in the pituitary glands of the marsupial Monodelphis domestica and of the amphibian Rana pipiens detected by a colorimetric Nb2 lymphoma cell proliferation assay.

Abstract An inexpensive and reliable colorimetric microplate version of the Nb2 lymphoma cell proliferation bioassay for prolactin (PRL) was developed and optimized. The useful range of the assay is between 0.1 and 12.8 ng/ml in terms of rat pituitary PRL. The assay can accommodate up to 20 μl sample/well. The physiological relevance of the assay was verified by measuring thyrotropin-releasing hormone (TRH)-induced secretion of PRL in pituitary cultures and in serum samples of neonatal rats. Through the use of the colorimetric Nb2 assay, PRL-like bioactivities were demonstrated in pituitary extracts of the marsupial, Monodelphis domestica (1.47 ng PRL/μg protein) and of the amphibian, Rana pipiens (1.86 ng PRL/μg protein). Marsupial and amphibian PRLs are predicted to have low specific activities in the Nb2 assay. Since the PRL values were calculated in terms of a rat PRL standard, they probably underestimate the amounts of PRL present. Parallel dose-response curves were obtained with these pituitary extracts and standard rat PRL over a wide range of dilutions. The Nb2 bioassay may serve as a tool for the purification of PRL from these species. The colorimetric version of the Nb2 bioassay may be a useful alternative to traditional Nb2 assays that rely on direct cell count or [3H]thymidine uptake.