The localization of messenger ribonucleic acids for somatostatin receptors 1, 2, and 3 in rat testis.

Somatostatin (SRIF) exerts multiple inhibitory actions throughout the body by binding to specific SRIF receptors (sst). In recent years, five subtypes of SRIF receptors (sst1-5) have been cloned. In this study, 35S-labeled complementary RNA probes were used for in situ hybridization to localize the sst1-5 messenger RNAs (mRNAs) in the rat testis and examine the changes in their distribution during the cycle of the seminiferous epithelium. We found that sst 1-3 mRNAs were visualized in rat testes and were mainly localized within the seminiferous tubules. The signal for sst3 mRNA was also found in interstitial cells. sst4 and 5 mRNAs were not detected in rat testes with the method used in this study. In Sertoli cells, the most intense labeling for sst1 and 3 mRNAs was in stages IV-VII of the cycle of the seminiferous epithelium, which coincided with the lowest labeling intensity for sst2. In germ cells, sst1-3 mRNAs showed similar patterns of distribution. In these cells, sst1-3 mRNA was not observed at the early steps of spermatogenesis. Positive signals for sst1-3 mRNAs were first apparent in the pachytene spermatocytes at stage VII and last until stage XII and in the diplotene spermatocyte at stage XIII. Positive signals for sst1-3 were also detected in round spermatids at stages I-VIII. Labeling of spermatids dramatically decreased at stage IX, when these cells began their elongating changes. The presence of three sst in testis suggests that SRIF may play an essential role in testicular function.

Distribution of somatostatin receptor messenger RNAs in the rat gastrointestinal tract.

BACKGROUND & AIMS: The gastrointestinal (GI) tract is a major source and target of somatostatin (SRIF). Recently, five pharmacologically different SRIF receptors (sst1-5) were cloned. The cellular and tissue distribution of the sst1-5 messenger RNAs (mRNAs) were studied in the rat GI tract using in situ hybridization histochemistry (ISHH). METHODS: Two sets of (35)S-uridine triphosphate (UTP)-labeled antisense and sense riboprobes were prepared for each sst. ISHH was conducted on frozen tissue samples from rat stomach, duodenum, jejunum, ileum, colon, and pancreas. RESULTS: mRNAs of all five sst-s are widely expressed in the rat GI tract. The distribution pattern for each sst mRNA was identical with both antisense probes. No specific signal was found with any of the sense probes. Each layer of the different parts of the gut expressed mRNAs of multiple sst subtypes. All organs expressed sst3 mRNA very intensely. The lowest levels of mRNA expression for all five subtypes within the GI tract were found in the pancreas. CONCLUSIONS: The widespread expression of sst mRNAs suggests a significant role for SRIF in the regulation of GI function.

Effect of posterior pituitary denervation (PPD) on prolactin (PRL) and alpha-melanocyte-stimulating hormone (alpha-MSH) secretion of lactating rats.

Previous data have clearly suggested that the posterior pituitary (PP), consisting of neural lobe (NL) and intermediate lobe (IL), has a role in the control of anterior pituitary PRL secretion. However, basic aspects of this regulatory mechanism like (1), the role of an intact hypothalamic innervation of the PP as well as (2) the site of production of previously found PRL releasing substance(s) have not yet been characterized. Denervation of the PP (PPD) is an effective method for having a selective lesion of the innervation of PP, indeed, PPD results in a disappearance of neurosecretory materials from NL and tyrosine hydroxylase (TH) immunoreactivity from IL, leaving blood supply of all three lobes intact. Blood samples were taken from freely moving sham an PP-denervated lactating rats before and after 4-h separation from their pups and during the suckling stimulus. PPD blocks separation-induced depletion but only attenuates suckling induced release of PRL. Furthermore, it doubles plasma level of alpha-MSH during the entire sampling period, which has been used as a marker for in vivo secretory activity of IL cells. Lack of the separation-induced depression in plasma PRL of PPD animals can be partially restored by normalizing the diabetes insipidus with treatment of a vasopressin analogue, 1-desamino-8-D-arginine-vasopressin (dDAVP). In contrast, dDAVP, neither alone nor in combination with oxytocin (OXY), can change PPD-induced elevation of plasma alpha-MSH as well as attenuation of PRL response induced by suckling. It is concluded that: (1) contribution of the THDA system parallel to the confirmed role in the regulation of alpha-MSH seems to be crucial for the depletion of plasma PRL induced by separation but not for the elevation due to suckling stimulus, (2) intact hypothalamic innervations of both NL and IL, regulating water intake and the secretion of alpha-MSH, respectively, are necessary for normal secretory responses of AL during lactation, (3) as well as for the presence of PRF activity in PP, (4) which does not solely responsible for suckling-induced PRL release. Therefore, an interplay between several substances produced by NIL of the pituitary gland must have been responsible for the intact regulation of PRL secretion during lactation.

Immunohistochemical signal amplification by catalyzed reporter deposition and its application in double immunostaining.

The biotinyl-tyramide substrate of the horseradish peroxidase enzyme has been recently introduced to amplify immunohistochemical signals. We applied either fluorochromeor biotin-conjugated tyramine to improve the detection of different antigens in sections of rat stomach, pancreas, and hypothalamus. A ten- to 100-fold increase in staining efficiency was achieved, depending on the antibody, with either fluorescent or peroxidase detection systems. The amplification method was particularly useful for increasing a weak signal of conventional immunostaining caused by suboptimal tissue fixation. At a very low concentration of the primary antibody, the antigen can no longer be detected by a conventional fluorescent secondary antibody but is still detectable after amplification. When an antibody is used at this very low concentration and is detected by a fluorescent amplification method, another primary antibody, raised in the same host species, can be used and demonstrated with a different fluorochrome in subsequent conventional immunostaining of the same section. In this way it becomes possible to immunostain the same section with two different primary antibodies raised in the same host species. Samples for such double immunostaining are demonstrated here using pairs of monoclonal antibodies (to tyrosine hydroxylase and oxytocin) in the hypothalamus and polyclonal antibodies (to glucagon and neurofilament M) in sections of rat pancreas. Because in many cases the availability of antibodies is limited, the amplification method can be a quick and efficient tool for double immunostaining with antibodies from the same host species.

PACAP acts through VIP type 2 receptors in the rat testis.

Pituitary adenylate cyclase-activating peptide (PACAP) is present and synthesized in the testis in large amounts. Messenger RNA encoding the peptide is expressed in a stage specific manner in the developing germ cells. PACAP regulates a variety of physiological actions, among them, paracrine modulation of spermatogenesis. The PACAP peptides are potential ligands of at least three receptor types, the type I PACAP receptor, VIP1 and VIP2 receptors. Although PACAP27 binding sites have found in the testis, the receptor at which it acts has not been identified. We used in situ hybridization with riboprobes to identify the PACAP binding receptor present in the testis. Neither type I PACAP receptor, nor VIP1 receptor mRNA was present within the germ cells. Using the VIP2 receptor probe there was strong labelling within some cross sections of the seminiferous tubuli, while others were not labelled. The in situ results were also confirmed using reverse-transcription PCR (RT-PCR). Our data suggest that PACAP mediates its possible paracrine effect in the testis through the VIP2 receptor.

Widespread distribution of somatostatin receptor messenger ribonucleic acids in rat pituitary.

The expression of five somatostatin receptor subtypes, rsstr1-5, was examined in rat pituitary by in situ hybridization histochemistry. The anterior lobe of the pituitary expressed mRNA encoding all five rsstr subtypes. Relatively high levels of rsstr3 mRNA expression were also observed in the intermediate lobe of the pituitary. If all five rsstr proteins are expressed in the pituitary, the effects of somatostatin and somatostatin-28 on pituitary function may therefore represent the composite activation of more than one sstr. Co-localization studies on the same pituitary sections revealed a widespread distribution of rsstr mRNA in the major endocrine cell groups. Somatotrophs showed a relatively high level of rsstr4 and -5 mRNA expression while thyrotrophs predominantly expressed rsstr2 mRNA. These data may point to the potential roles for sstr subtypes in mediating SRIF physiology in the pituitary.