Joseph F. Maher

Potential role of increased iron stores in diabetes.

Diabetes mellitus (DM) is an important risk factor for the development of cardiovascular disease. Extensive clinical, epidemiologic, and basic studies suggest that excessive tissue iron stores may contribute to the occurrence and complications of DM. Secondary diabetes occurs in inherited pathologic iron overload syndromes of European- and African-derived populations and is an established complication of transfusional iron overload. Epidemiologic studies have repeatedly shown positive correlation between levels of serum ferritin and those of fasting glucose, insulin, and glycosylated hemoglobin. Iron reduction therapy in hereditary hemochromatosis and transfusional iron overload is associated with improved glucose tolerance and reduced incidence of secondary diabetes. Trials of iron reduction therapy in diabetes mellitus, although limited and inconclusive, have shown clinical improvement in some patients. The current article reviews evidence suggesting that tissue iron contributes to DM and its complications and presents preliminary data that emphasize the potential importance of iron overload in DM of African Americans.

De novo ACTA2 mutation causes a novel syndrome of multisystemic smooth muscle dysfunction

Smooth muscle cells (SMCs) contract to perform many physiological functions, including regulation of blood flow and pressure in arteries, contraction of the pupils, peristalsis of the gut, and voiding of the bladder. SMC lineage in these organs is characterized by cellular expression of the SMC isoform of α‐actin, encoded by the ACTA2 gene. We report here on a unique and de novo mutation in ACTA2, R179H, that causes a syndrome characterized by dysfunction of SMCs throughout the body, leading to aortic and cerebrovascular disease, fixed dilated pupils, hypotonic bladder, malrotation, and hypoperistalsis of the gut and pulmonary hypertension.

RACK1 downregulates levels of the pro-apoptotic protein Fem1b in apoptosis-resistant colon cancer cells.

Evasion of apoptosis plays an important role in colon cancer progression. Following loss of the Apc tumor suppressor gene in mice, the gene encoding Fem1b is up-regulated early in neoplastic intestinal epithelium. Fem1b is a pro-apoptotic protein that interacts with Fas, TNFR1, and Apaf-1, and increased expression of Fem1b induces apoptosis of cancer cells. Fem1b is a homolog of FEM-1, a protein in Caenorhabditis elegans that is negatively regulated by ubiquitination and proteasomal degradation. To study Fem1b regulation in colon cancer progression, we used apoptotis-sensitive SW480 cells, derived from a primary colon cancer, and their isogenic, apoptosis-resistant counterparts SW620 cells, derived from a subsequent metastatic lesion in the same patient. Treatment with proteasome inhibitor increased Fem1b protein levels in SW620 cells, but not in SW480 cells. In SW620 cells we found that endogenous Fem1b co-immunoprecipitates in complexes with RACK1, a protein known to mediate ubiquitination and proteasomal degradation of other pro-apoptotic proteins and to be up-regulated in colon cancer. Full-length Fem1b, or the N-terminal region of Fem1b, associated with RACK1 when co-expressed in HEK293T cells, and RACK1 stimulated ubiquitination of Fem1b. RACK1 over-expression in SW620 cells led to down-regulation of Fem1b protein levels. Conversely, down-regulation of RACK1 led to up-regulation of Fem1b protein levels, associated with induction of apoptosis, and this apoptosis was inhibited by blocking Fem1b protein up-regulation. In conclusion, RACK1 down-regulates levels of the pro-apoptotic protein Fem1b in metastatic, apoptosis-resistant colon cancer cells, which may promote apoptosis-resistance during progression of colon cancer.

Abnormal Glucose Homeostasis and Pancreatic Islet Function in Mice with Inactivation of the Fem1b Gene

ABSTRACT Type 2 diabetes mellitus is a disorder of glucose homeostasis involving complex gene and environmental interactions that are incompletely understood. Mammalian homologs of nematode sex determination genes have recently been implicated in glucose homeostasis and type 2 diabetes mellitus. These are the Hedgehog receptor Patched and Calpain-10, which have homology to the nematode tra-2 and tra-3 sex determination genes, respectively. Here, we have developed Fem1b knockout (Fem1b-KO) mice, with targeted inactivation of Fem1b, a homolog of the nematode fem-1 sex determination gene. We show that the Fem1b-KO mice display abnormal glucose tolerance and that this is due predominantly to defective glucose-stimulated insulin secretion. Arginine-stimulated insulin secretion is also affected. The Fem1b gene is expressed in pancreatic islets, within both β cells and non-β cells, and is highly expressed in INS-1E cells, a pancreatic β-cell line. In conclusion, these data implicate Fem1b in pancreatic islet function and insulin secretion, strengthening evidence that a genetic pathway homologous to nematode sex determination may be involved in glucose homeostasis and suggesting novel genes and processes as potential candidates in the pathogenesis of diabetes mellitus.

The Fem1c genes: conserved members of the Fem1 gene family in vertebrates.

The fem-1 gene of Caenorhabditis elegans functions in a signaling pathway that controls sex determination. Homologs of fem-1 in mammals have been characterized, consisting of two family members, Fem1a and Fem1b. We report here on Fem1c, a third member of the Fem1 gene family, in three vertebrate species: human, mouse, and zebrafish. The proteins encoded by these Fem1c genes share >99% amino acid identity between human and mouse, 79% amino acid identity between mouse and zebrafish, and end with a C-terminal Arginine residue, which distinguishes them from other FEM-1 proteins reported thus far. The human and mouse Fem1c coding regions show conservation of intron-exon structure and expression pattern in adult tissues. Human FEM1C maps to 5q22, mouse Fem1c maps to chromosome 18, and zebrafish fem1c maps to Linkage Group 8. The Fem1c genes in vertebrates may play a conserved role in the development and/or physiologic function of these organisms.

Fem1b, a proapoptotic protein, mediates proteasome inhibitor‐induced apoptosis of human colon cancer cells

In the treatment of colon cancer, the development of resistance to apoptosis is a major factor in resistance to therapy. New molecular approaches to overcome apoptosis resistance, such as selectively upregulating proapoptotic proteins, are needed in colon cancer therapy. In a mouse model with inactivation of the adenomatous polyposis coli (Apc) tumor suppressor gene, reflecting the pathogenesis of most human colon cancers, the gene encoding feminization‐1 homolog b (Fem1b) is upregulated in intestinal epithelium following Apc inactivation. Fem1b is a proapoptotic protein that interacts with apoptosis‐inducing proteins Fas, tumor necrosis factor receptor‐1 (TNFR1), and apoptotic protease activating factor‐1 (Apaf‐1). Increasing Fem1b expression induces apoptosis of cancer cells, but effects on colon cancer cells have not been reported. Fem1b is a homolog of feminization‐1 (FEM‐1), a protein in Caenorhabditis elegans that is regulated by proteasomal degradation, but whether Fem1b is likewise regulated by proteasomal degradation is unknown. Herein, we found that Fem1b protein is expressed in primary human colon cancer specimens, and in malignant SW620, HCT‐116, and DLD‐1 colon cancer cells. Increasing Fem1b expression, by transfection of a Fem1b expression construct, induced apoptosis of these cells. We found that proteasome inhibitor treatment of SW620, HCT‐116, and DLD‐1 cells caused upregulation of Fem1b protein levels, associated with induction of apoptosis. Blockade of Fem1b upregulation with morpholino antisense oligonucleotide suppressed the proteasome inhibitor‐induced apoptosis of these cells. In conclusion, the proapoptotic protein Fem1b is downregulated by the proteasome in malignant colon cancer cells and mediates proteasome inhibitor‐induced apoptosis of these cells. Therefore, Fem1b could represent a novel molecular target to overcome apoptosis resistance in therapy of colon cancer.

Fem1b promotes ubiquitylation and suppresses transcriptional activity of Gli1.

The mammalian Fem1b gene encodes a homolog of FEM-1, a protein in the sex-determination pathway of the nematode Caenorhabditis elegans. Fem1b and FEM-1 proteins each contain a VHL-box motif that mediates their interaction with certain E3 ubiquitin ligase complexes. In C. elegans, FEM-1 negatively regulates the transcription factor TRA-1, and functions as an E3 ubiquitin ligase substrate recognition subunit to target TRA-1 for ubiquitylation. TRA-1 is homologous to the mammalian Gli1 protein, a transcription factor that mediates Hedgehog signaling as well as having Hedgehog-independent functions. Whether the interaction between nematode FEM-1 and TRA-1 proteins is conserved, between corresponding mammalian homologs, has not been reported. Herein, we show that Fem1b interacts with Gli1 within cells, and directly binds Gli1. Fem1b also promotes ubiquitylation of Gli1, suppresses transcriptional activation by Gli1, and attenuates an oncogenic Gli1 autoregulatory loop in cancer cells, all dependent on the VHL-box of Fem1b. These findings have implications for understanding the cellular functions of Fem1b, and the regulation of Gli1 oncoprotein activity.

FEM1A is a candidate gene for polycystic ovary syndrome.

Polycystic ovary syndrome (PCOS) is the most common endocrine disorder among women of reproductive age, and is characterized by infertility, hyperandrogenism and insulin resistance in skeletal muscle. There is evidence for a PCOS gene localized to chromosome 19p13.3. The FEMIA gene maps to chromosome 19p13.3 and is highly expressed in skeletal muscle. FEMIA is a homolog of fem-1, a sex-determination gene of Caenorhabditis elegans that controls masculinization. In a pilot study of Caucasian PCOS patients from our local clinic, we found that one of these five patients exhibited a heterozygous germline missense mutation in FEM1A, designated FEM1A*H500Y. This mutation alters an amino acid conserved from human to C. elegans, and was not found in any of 198 control chromosomes. This missense allele was not found in any of a separate group of 30 PCOS patients from a different regional/ethnic background. Immunostaining of mouse ovary demonstrated that the mouse homolog of FEM1A is expressed in androgen-producing secondary interstitial cells, with a marked increase in expression after puberty, consistent with a key feature of PCOS – ovarian hyperandrogenism. In conclusion, FEM1A should be considered a candidate gene for PCOS, and more extensive analysis of FEM1A, both coding and regulatory sequences, is warranted in patients and families with PCOS.

Gene-environment interaction between SCN5A-1103Y and hypokalemia influences QT interval prolongation in African Americans: The Jackson Heart Study

BACKGROUND African-American ancestry, hypokalemia, and QT interval prolongation on the electrocardiogram are all risk factors for sudden cardiac death (SCD), but their interactions remain to be characterized. SCN5A-1103Y is a common missense variant, of African ancestry, of the cardiac sodium channel gene. SCN5A-1103Y is known to interact with QT-prolonging factors to promote ventricular arrhythmias in persons at high risk for SCD, but its clinical impact in the general African-American population has not been established. METHODS We genotyped SCN5A-S1103Y in 4,476 participants of the Jackson Heart Study, a population-based cohort of African Americans. We investigated the effect of SCN5A-1103Y, including interaction with hypokalemia, on QT interval prolongation, a widely-used indicator of prolonged myocardial repolarization and predisposition to SCD. We then evaluated the two sub-components of the QT interval: QRS duration and JT interval. RESULTS The carrier frequency for SCN5A-1103Y was 15.4%. SCN5A-1103Y was associated with QT interval prolongation (2.7 milliseconds; P < .001) and potentiated the effect of hypokalemia on QT interval prolongation (14.6 milliseconds; P = .02). SCN5A-1103Y had opposing effects on the two sub-components of the QT interval, with shortening of QRS duration (-1.5 milliseconds; P = .001) and prolongation of the JT interval (3.4 milliseconds; P < .001). Hypokalemia was associated with diuretic use (78%; P < .001). CONCLUSIONS SCN5A-1103Y potentiates the effect of hypokalemia on prolonging myocardial repolarization in the general African-American population. These findings have clinical implications for modification of QT prolonging factors, such as hypokalemia, in the 15% of African Americans who are carriers of SCN5A-1103Y.

The Fem1a Gene Is Downregulated in Rhabdomyosarcoma

Rhabdomyosarcoma (RMS) is the most common soft tissue neoplasm of children, and those metastatic at presentation have a poor prognosis. RMS development is related to defective skeletal muscle differentiation, involving a variety of cell signaling and transcriptional control pathways, including aberrant hedgehog signaling. Here we evaluate Fem1a, a gene highly expressed in skeletal muscle, as a candidate for involvement in RMS. Fem1a is a homolog of fem-1, which controls cell fate decisions in the sex determination pathway of Caenorhabditis elegans, a pathway with homology to mammalian hedgehog signaling. We show that Fem1a expression is activated during myocyte differentiation of C2C12 myoblasts, and this expression is largely confined to the terminally differentiating pool, not to the satellite-cell-like quiescent reserve cell pool. We find that the human homolog, FEM1A, is downregulated in all of 8 different human RMS cell lines, including those derived from embryonal and alveolar RMS. Using mouse genetic models of RMS development, we further show that Fem1a is consistently downregulated in primary RMS from Ptch1+/– mice, from p53–/– mice, from p53+/–; Ptch1+/– mice, and from HGF/SF-Ink4a/Arf–/– mice. Therefore, Fem1a downregulation may be involved in, and/or a marker of, an early cell fate defect fundamental to RMS pathogenesis.