Identification and sequence analysis of prolactin receptor and its differential expression profile at various developmental stages in striped hamsters

Prolactin (PRL) plays critical roles in regulation of biological functions with the binding of specific prolactin receptor (PRLR). Revealing the expression patterns of PRLR at different developmental stages is beneficial to better understand the role of PRL and its mechanism of action in striped hamsters. In this study, the cDNA sequence of PRLR (2866-base-pairs) was harvested from the pituitary of mature female striped hamsters (Cricetulus barabensis) that contains an 834-base-pair 5′-untranslated region (1-834 bp), a 1848-base-pair open reading frame (835-2682 bp), and a 184-base-pair 3′-untranslated region (2683-2866). The 1848-base-pair open reading frame encodes a mature prolactin-binding protein of 592 amino acids. In the mature PRLR, two prolactin-binding motifs, 12 cysteines, and five potential Asn-linked glycosylation sites were detected. Our results showed that the PRLR mRNA quantity in the hypothalamus, pituitary, ovaries, or testis was developmental-stage-dependent, with the highest level at sub-adult stage and the lowest level at old stage. We also found that PRLR mRNAs were highest in pituitary, medium level in hypothalamus, and lowest in ovaries or testis. PRLR mRNAs were significantly higher in males than in females, except in the hypothalamus and pituitary from 7-week-old striped hamsters. Moreover, the PRLR mRNAs in the hypothalamus, pituitary, and ovaries or testis were positively correlated with the expression levels of GnRH in the hypothalamus. These results indicated that the PRLR has conserved domain in striped hamster, but also possesses specific character. PRLR has multiple biological functions including positively regulating reproduction in the striped hamster.

Interactions between prolactin and kisspeptin to control reproduction

ABSTRACT Prolactin is best known for its effects of stimulating mammary gland development and lactogenesis. However, prolactin is a pleiotropic hormone that is able to affect several physiological functions, including fertility. Prolactin receptors (PRLRs) are widely expressed in several tissues, including several brain regions and reproductive tract organs. Upon activation, PRLRs may exert prolactin’s functions through several signaling pathways, although the recruitment of the signal transducer and activator of transcription 5 causes most of the known effects of prolactin. Pathological hyperprolactinemia is mainly due to the presence of a prolactinoma or pharmacological effects induced by drugs that interact with the dopamine system. Notably, hyperprolactinemia is a frequent cause of reproductive dysfunction and may lead to infertility in males and females. Recently, several studies have indicated that prolactin may modulate the reproductive axis by acting on specific populations of hypothalamic neurons that express the Kiss1 gene. The Kiss1 gene encodes neuropeptides known as kisspeptins, which are powerful activators of gonadotropin-releasing hormone neurons. In the present review, we will summarize the current knowledge about prolactin’s actions on reproduction. Among other aspects, we will discuss whether the interaction between prolactin and the Kiss1-expressing neurons can affect reproduction and how kisspeptins may become a novel therapeutic approach to treat prolactin-induced infertility.

Prolactin receptors in uterine leiomyomas

To identify the location of prolactin receptors in patients with uterine leiomyomas and their host myometrium as well as normal myometrium. A case control study was conducted at the College of Medicine Al-Nahrain University, Baghdad, Iraq during the period from 2004-2006. The samples were collected at Obstetrics and Gynecological Departments of 4 hospitals in Baghdad City [Al-Khadimiya Teaching Hospital, Al-Noor, Al-Kharch, and Al-Saadoon Hospital]. Sections from large and small tumors [n=53] with their host myometriums and from normal myometriums [n=40] were stained immunohistochemically for prolactin receptors. Prolactin receptors were positively seen in all cases examined including patient and comparison tissues, in the form of dark brown staining. Staining was heterogenous and varied in intensity from one case to another and sometimes from one area to another in the same section. The increase in prolactin receptors in leiomyoma is expected given that the underlying host myometrium is abnormal

La prolactina en el sistema inmunológico: aspectos de síntesis y efectos biológicos / Prolactin in the immune system: synthesis and biological effects

Prolactin (PRL) Is a 23 κDa protein hormone that is produced and secreted by the pituitary lactotrophs. Although PRL was initially regarded as an exclusive pituitary hormone, many nonpituitary tissues were later found to contain and produce this hormone. The most established extrapituitary sites that produce PRL are the decidua, the immune system, brain and endometrium. In the immune system, PRL acts as a cytokine where it plays an important role in human immune responses, including in autoimmune diseases. Here, we will discuss the regulation of PRL gene expression in human lymphocytes and review the functions of PRL made by the immune cells, including its involvement in autoimmunity.

La prolactina es una hormona que fue considerada durante mucho tiempo de origen exclusivamente hipofisario, y cuya función más importante era la promoción de la lactancia. Sin embargo, la prolactina no sólo se sintetiza en diversos sitios del organismo, sino que también participa en una amplia variedad de procesos biológicos. Dentro de los sitios de síntesis extrahipofisarios de esta hormona se encuentran diversas células del sistema inmunológico. A este nivel, la prolactina actúa afectando desde la proliferación celular hasta el estado inmune del individuo. En esta revisión presentamos algunos aspectos relativos a la prolactina de origen linfocitario tales como su síntesis, su participación en el sistema inmunológico y su relación con estados de autoinmunidad.