Clinically Defined Mutations in MEN1 Alter Its Tumor-suppressive Function Through Increased Menin Turnover.

Loss of the tumor suppressor protein menin is a critical event underlying the formation of neuroendocrine tumors (NET) in hormone-expressing tissues including gastrinomas. While aberrant expression of menin impairs its tumor suppression, few studies explore the structure-function relationship of clinical multiple endocrine neoplasia, type 1 (MEN1) mutations in the absence of a complete LOH at both loci. Here, we determined whether clinical MEN1 mutations render nuclear menin unstable and lead to its functional inactivation. We studied the structural and functional implications of two clinical MEN1 mutations (R516fs, E235K) and a third variant (A541T) recently identified in 10 patients with gastroenteropancreatic (GEP)-NETs. We evaluated the subcellular localization and half-lives of the mutants and variant in Men1-null mouse embryo fibroblast cells and in hormone-expressing human gastric adenocarcinoma and NET cell lines. Loss of menin function was assessed by cell proliferation and gastrin gene expression assays. Finally, we evaluated the effect of the small-molecule compound MI-503 on stabilizing nuclear menin expression and function in vitro and in a previously reported mouse model of gastric NET development. Both the R516fs and E235K mutants exhibited severe defects in total and subcellular expression of menin, and this was consistent with reduced half-lives of these mutants. Mutated menin proteins exhibited loss of function in suppressing tumor cell proliferation and gastrin expression. Treatment with MI-503 rescued nuclear menin expression and attenuated hypergastrinemia and gastric hyperplasia in NET-bearing mice. Clinically defined MEN1 mutations and a germline variant confer pathogenicity by destabilizing nuclear menin expression. Significance: We examined the function of somatic and germline mutations and a variant of MEN1 sequenced from gastroenteropancreatic NETs. We report that these mutations and variant promote tumor cell growth and gastrin expression by rendering menin protein unstable and prone to increased degradation. We demonstrate that the menin-MLL (mixed lineage leukemia) inhibitor MI-503 restores menin protein expression and function in vitro and in vivo, suggesting a potential novel therapeutic approach to target MEN1 GEP-NETs.

MENIN-mediated regulation of gastrin gene expression and its role in gastrinoma development.

The Multiple Endocrine Neoplasia I (MEN1) locus encodes the protein MENIN, which functions as a tumor suppressor protein in neuroendocrine tissues. Gastrinomas are neuroendocrine neoplasms that overproduce the hormone gastrin and can arise sporadically or as part of the MEN1 syndrome, in which mutations in the MEN1 gene lead to loss or inactivation of MENIN protein. Gastrin is a peptide hormone that is primarily synthesized in the gastric antrum and stimulates the secretion of histamine from enterochromaffin-like (ECL) cells and subsequently acid from parietal cells in the gastric corpus. In addition, gastrin exerts a mitogenic function primarily on ECL cells and progenitor cells in the gastric isthmus. Current studies seek to understand how MEN1 mutations generate a mutant MENIN protein that abrogates its tumor suppressor function. Mutations in the MEN1 gene are broadly distributed throughout its nine protein-coding exons, making it difficult to correlate protein structure with its function. Although disruption of the Men1 locus in mice causes functional neuroendocrine tumors in the pituitary and pancreas, gastrinomas do not develop in these transgenic animal models. Prior studies of human gastrinomas suggest that tissue-specific microenvironmental cues in the submucosal foregut may contribute to tumorigenesis by reprogramming of epithelial cells toward the neuroendocrine phenotype. Accordingly, recent studies suggest that neural crest-derived cells are also sensitive to reprogramming when MEN1 is deleted or mutated. Thus, the goal of this report is to review our current understanding of how MENIN modulates gastrin gene expression while highlighting its role in the prevention/suppression of neuroendocrine cell transformation.

Thyme (Thymus vulgaris [Lamiaceae]) Leaves Inhibit Contraction of the Nonpregnant Mouse Uterus.

Dysmenorrhea is painful menstrual periods, which affects 25% of women within reproductive age and has a prevalence of 67.2-90.0%. Current treatment has several adverse effects and can be ineffective once the pain is initiated. Thymus vulgaris traditionally used for pain management was investigated in this study for its activity on uterine contraction in the nonpregnant uterus, as a parameter for dysmenorrhea. The dried leaves of T. vulgaris were macerated in water, and the resulting aqueous extract was investigated on the isolated mouse uterus. Parameters investigated included spontaneous contractions, oxytocin-induced contractions, and high potassium chloride (KCl; 80 mM)-induced tonic contractions. Mass spectrometric analysis of the thyme extract was also performed using liquid chromatography-high-resolution Fourier Transform mass spectrometry. Thyme extract inhibited the amplitude and frequency of spontaneous and oxytocin-induced uterine contractions. It also inhibited KCl-induced tonic contractions. The activities observed suggest that T. vulgaris inhibits uterine contractions through blockade of extracellular voltage-gated calcium channels. Secondary metabolites detected included compounds belonging to chlorogenic phytochemical class and flavonoids, which are known to have activities on extracellular calcium blockade. This study has shown that aqueous T. vulgaris extract, also known as thyme, inhibits contractions of the nonpregnant uterus and can be a lead plant in the drug discovery process for the management of dysmenorrhea.

A role of alpha-tocopherol and phylloquinone in the modulation of uterine contractility and reproductive function in mouse models.

BACKGROUND AND AIM: Alpha-tocopherol has been implicated in reproduction processes, and deficiency of phylloquinone has been associated with serious complications in pregnancy. This study was therefore aimed at investigating the effects of phylloquinone and alpha-tocopherol on uterine contractility and female reproductive function using mouse models. MATERIALS AND METHODS: Both in vivo and ex vivo animal models were employed and designed to assess changes on uterine contractility and reproductive functions in the non-pregnant uterus. The effect of alpha-tocopherol and phylloquinone on spontaneous uterine contractions, oxytocin-induced uterine contractions (11.82nM) and high KCl-induced tonic uterine contractions (80mM) were assessed. The effect of subcutaneous administration of alpha-tocopherol (10mg/kg) on reproductive hormone levels and reproductive tissues were also determined. RESULTS: Alpha-tocopherol increased the force of contractions while phylloquinone decreased the force of uterine contractions. Plasma levels of luteinizing hormone (P<0.01), estrogen (P<0.01) and progesterone (P<0.001) were elevated in the presence of alpha-tocopherol after 6 days subcutaneous administration. CONCLUSIONS: Alpha-tocopherol and phylloquinone have been shown to directly modulate uterine contractility and reproductive function and may contribute to the management and treatment of reproductive disorders.