Jeffrey McDermott

Inhibition of zebrafish fin regeneration using in vivo electroporation of morpholinos against fgfr1 and msxb

Increased interest in using zebrafish as a model organism has led to a resurgence of fin regeneration studies. This has allowed for the identification of a large number of gene families, including signaling molecules and transcription factors, which are expressed during regeneration. However, in cases where no specific inhibitor is available for the gene product of interest, determination of a functional role for these genes has been difficult. Here we demonstrate that in vivo electroporation of morpholino oligonucleotides is a feasible approach for protein knock‐down during fin regeneration. Morpholino oligonucleotides against fgfr1 and msxb were utilized and knock‐down of both proteins resulted in reduced fin outgrowth. Importantly, Fgfr1 knock‐down phenocopied outgrowth inhibition obtained with an Fgfr1 inhibitor. Furthermore, this method provided direct evidence for a functional role for msxb in caudal fin regeneration. Finally, knock‐down of Fgfr1, but not Msxb, affected the blastemal expression of msxc, suggesting this technique can be used to determine epistasis in genetic pathways affecting regeneration. Thus, this convenient reverse genetic approach allows researchers to quickly (1) assess the function of genes known to be expressed during fin regeneration, (2) screen genes for functional relevance during fin regeneration, and (3) assign genes to the molecular pathways underlying fin regeneration. Developmental Dynamics 235:336–346, 2006.

Cre‐mediated site‐specific recombination in zebrafish embryos

Cre‐mediated site‐specific recombination has become an invaluable tool for manipulation of the murine genome. The ability to conditionally activate gene expression or to generate chromosomal alterations with this same tool would greatly enhance zebrafish genetics. This study demonstrates that the HSP70 promoter can be used to inducibly control expression of an enhanced green fluorescent protein (EGFP) –Cre fusion protein. The EGFP–Cre fusion protein is capable of promoting recombination between lox sites in injected plasmids or in stably inherited transgenes as early as 2 hr post–heat shock induction. Finally, the levels of Cre expression achieved in a transgenic fish line carrying the HSP70‐EGFP–cre transgene are compatible with viability and both male and female transgenic fish are fertile subsequent to induction of EGFP–Cre expression. Hence, our data suggests that Cre‐mediated recombination is a viable means of manipulating gene expression in zebrafish. Developmental Dynamics 233:1366–1377, 2005.

Na,K-ATPase α4 isoform is essential for sperm fertility

Regulation of ion balance in spermatozoa has been shown to be essential for sperm motility and fertility. Control of intracellular ion levels requires the function of distinct ion-transport mechanisms at the cell plasma membrane. Active Na+ and K+ exchange in sperm is under the control of the Na,K-ATPase. Two molecular variants of the catalytic subunit of the Na,K-ATPase, α1 and α4, coexist in sperm. These isoforms exhibit different biochemical properties; however, their function in sperm fertility is unknown. In this work, we show that Na,K-ATPase α4 is essential for sperm fertility. Knockout male mice lacking α4 are completely sterile and spermatozoa from these mice are unable of fertilizing eggs in vitro. Furthermore, α4 deletion results in severe reduction in sperm motility and hyperactivation typical of sperm capacitation. In addition, absence of α4 causes a characteristic bend in the sperm flagellum, indicative of abnormal sperm ion regulation. Accordingly, α4-null sperm present increased intracellular Na+ and cell plasma membrane depolarization. These results are unique in demonstrating the absolute requirement of α4 for sperm fertility. Moreover, the inability of α1 to compensate for α4 suggests that α4 is the Na,K-ATPase-α isoform directly involved in sperm fertility. Our findings show α4 as an attractive target for male contraception and open the possibility for the potential use of this Na,K-ATPase isoform as a biomarker for male fertility.

Analysis of the Cell Adhesion Molecule Sticks-and-Stones Reveals Multiple Redundant Functional Domains, Protein-Interaction Motifs and Phosphorylated Tyrosines That Direct Myoblast Fusion in Drosophila melanogaster

The larval body wall muscles of Drosophila melanogaster arise by fusion of founder myoblasts (FMs) and fusion-competent myoblasts (FCMs). Sticks-and-Stones (SNS) is expressed on the surface of all FCMs and mediates adhesion with FMs and developing syncytia. Intracellular components essential for myoblast fusion are then recruited to these adhesive contacts. In the studies herein, a functional analysis of the SNS cytodomain using the GAL4/UAS system identified sequences that direct myoblast fusion, presumably through recruitment of these intracellular components. An extensive series of deletion and site-directed mutations were evaluated for their ability to rescue the myoblast fusion defects of sns mutant embryos. Deletion studies revealed redundant functional domains within SNS. Surprisingly, highly conserved consensus sites for binding post-synaptic density-95/discs large/zonula occludens-1-domain-containing (PDZ) proteins and serines with a high probability of phosphorylation play no significant role in myoblast fusion. Biochemical studies establish that the SNS cytodomain is phosphorylated at multiple tyrosines and their site-directed mutagenesis compromises the ability of the corresponding transgenes to rescue myoblast fusion. Similar mutagenesis revealed a requirement for conserved proline-rich regions. This complexity and redundancy of multiple critical sequences within the SNS cytodomain suggest that it functions through a complex array of interactions that likely includes both phosphotyrosine-binding and SH3-domain-containing proteins.

Increased Expression of the Na,K-ATPase alpha4 Isoform Enhances Sperm Motility in Transgenic Mice

The Na,K-ATPase alpha4 (ATP1A4) isoform is specifically expressed in male germ cells and is highly prevalent in spermatozoa. Although selective inhibition of alpha4 activity with ouabain has been shown to affect sperm motility, a more direct analysis of the role of this isoform in sperm movement has not yet been demonstrated. To establish this, we engineered transgenic mice that express the rat alpha4 isoform fused to green fluorescent protein in male germ cells, under the control of the mouse protamine 1 promoter. We showed that the rat Atp1a4 transgene is expressed in mouse spermatozoa and that it is localized to the sperm flagellum. In agreement with increased expression of the alpha4 isoform, sperm from transgenic mice displayed higher alpha4-specific Na,K-ATPase activity and binding of fluorescently labeled ouabain than wild-type mice. In contrast, expression and activity of ATP1A1 (alpha1), the other Na,K-ATPase alpha isoform present in sperm, remained unchanged. Similar to wild-type mice, mice expressing the alpha4 transgene exhibited normal testis and sperm morphology and no differences in fertility. However, compared to wild-type mice, sperm from transgenic mice displayed plasma membrane hyperpolarization and higher total and progressive motility. Other parameters of motility also increased, including straight-line, curvilinear, and average path velocities and amplitude of lateral head displacement. In addition, sperm from the transgenic mice showed enhanced sperm hyperactive motility, but no changes in progesterone-induced acrosome reaction. Altogether, these results provide new genetic evidence for the role of the ATP1A4 isoform in sperm motility, under both noncapacitating and capacitating conditions.

Role of human Na,K‐ATPase alpha 4 in sperm function, derived from studies in transgenic mice

Most of our knowledge on the biological role of the testis‐specific Na,K‐ATPase alpha 4 isoform derives from studies performed in non‐human species. Here, we studied the function of human Na,K‐ATPase alpha 4 after its expression in transgenic mice. Using a bacterial artificial chromosome (BAC) construct containing the human ATP1A4 gene locus, we obtained expression of the human α4 transgene specifically in mouse sperm testis and, in the sperm flagellum. The expressed human alpha 4 was active, and compared to wild‐type sperm, those from transgenic mice displayed higher Na,K‐ATPase alpha 4 activity and greater binding of fluorescently labeled ouabain, which is typical of the alpha 4 isoform. The expression and activity of endogenous alpha 4 and the other Na,K‐ATPase alpha isoform present in sperm, alpha 1, remained unchanged. Male mice expressing the human ATP1A4 transgene exhibited similar testis size and morphology, normal sperm number and shape, and no changes in overall fertility compared to wild‐type mice. Sperm carrying the human transgene exhibited enhanced total motility and an increase in multiple parameters of sperm movement, including higher sperm hyperactive motility. In contrast, no statistically significant changes in sperm membrane potential, protein tyrosine phosphorylation, or spontaneous acrosome reaction were found between wild‐type and transgenic mice. Altogether, these results provide new genetic evidence for an important role of human Na,K‐ATPase alpha 4 in sperm motility and hyperactivation, and establishes a new animal model for future studies of this isoform. Mol. Reprod. Dev. 82: 167–181, 2015.

Ouabain promotes partial epithelial to mesenchymal transition (EMT) changes in human autosomal dominant polycystic kidney disease (ADPKD) cells

Abstract The hormone ouabain has been shown to enhance the cystic phenotype of autosomal dominant polycystic kidney disease (ADPKD). Among other characteristics, the ADPKD phenotype includes cell de‐differentiation and epithelial to mesenchymal transition (EMT). Here, we determined whether physiological concentrations of ouabain induces EMT in human renal epithelial cells from patients with ADPKD. We found that ADPKD cells respond to ouabain with a decrease in expression of the epithelial marker E‐cadherin and increase in the expression of the mesenchymal markers N‐cadherin, &agr; smooth muscle actin (&agr;SMA) and collagen‐I; and the tight junction protein occludin and claudin‐1. Other adhesion molecules, such as ZO‐1, &bgr;‐catenin and vinculin were not significantly modified by ouabain. At the cellular level, ouabain stimulated ADPKD cell migration, reduced cell‐cell interaction, and the ability of ADPKD cells to form aggregates. Moreover, ouabain increased the transepithelial electrical resistance of ADPKD cell monolayers, suggesting that the paracellular transport pathway was preserved in the cells. These effects of ouabain were not observed in normal human kidney (NHK) cells. Altogether these results show a novel role for ouabain in ADPKD, inducing changes that lead to a partial EMT phenotype in the cells. These effects further support the key role that ouabain has as a factor that promotes the cystic characteristics of ADPKD cells. HighlightsOuabain promotes EMT and the mesenchymal phenotype of ADPKD cells.In contrast, ouabain does not affect normal human kidney cells.Ouabain effects in ADPKD cells are essential to exacerbate the ADPKD phenotype.