Andrea Wagenfeld

The Cause of Infertility of Male c-ros Tyrosine Kinase Receptor Knockout Mice

Abstract Male homozygous transgenic c-ros knockout mice are sterile by natural mating, lack a part of their epididymis, and the epididymal sperm exhibit tail angulation in vivo and in vitro. To ascertain if this abnormal tail form caused the infertility, the number and nature of sperm in the tract of females mated to knockout and wild-type mice were determined. Percentage motility and numbers of sperm in the uterus 1 h after mating were similar between genotypes. The majority of the uterine sperm from the wild-type males had straight flagella, whereas 46–86% of knockout sperm were bent at the cytoplasmic droplet even when motile. Motile knockout sperm showed a 54 and 37% reduction in the straightline and curvilinear velocities compared with straight wild-type sperm. Sequential flushings of the oviduct 4 h after mating with the wild-type males contained sperm: 591 ± 119 free, 371 ± 70 loosely, and 122 ± 47 tightly bound to the epithelium, but no knockout sperm were recovered from the oviduct or observed within the uterotubal junction in tissue sections. The infertility of c-ros knockout male mice can be explained by the sperms inability to enter the oviduct, as a result of their bent tails forming the entangled sperm mass and their compromised flagellar vigor within the uterus.

Sperm Volume Regulation: Maturational Changes in Fertile and Infertile Transgenic Mice and Association with Kinematics and Tail Angulation

Abstract Laser light scatter analyzed by flow cytometry was used to monitor the volume of viable maturing murine spermatozoa. Upon release, dispersion, and dilution, epididymal sperm from fertile heterozygous c-ros knockout mice were smallest in the cauda region and largest in the corpus region. Cauda sperm from both infertile homozygous c-ros knockout and GPX5-Tag2 transgenic mice were abnormally large. When incubated, corpus and cauda sperm from normal mice became slightly enlarged and later returned to a smaller size. This suggests an immediate swelling due to high intracellular osmolality, which triggers a regulatory volume decrease (RVD) that results in a net volume reduction. Normal caput sperm increased in size continuously and became larger than the more mature sperm, indicating a lack of RVD. The ion-channel blocker quinine induced dose-dependent size increases in normal cauda sperm but not in caput sperm. Dose-dependent quinine action on mature sperm also included induction of tail angulation, and suppression of straight-line velocity and linearity. The kinematic effects were more sensitive, with a quicker onset, but they diminished with time in contrast to tail angulation, which intensified. These results suggest that kinematic changes are an early phenomenon of swelling, which gradually accumulates at the cytoplasmic droplet to cause flagellar angulation. Disruption of the epididymal maturation of sperm volume regulation capacity would hinder the transport of sperm in the female tract, and may thereby explain infertility under certain conditions, but may also provide a novel approach to male contraception.

Mouse models of infertility due to swollen spermatozoa

Transgenic mice with male infertility, the c-ros knockout (KO) and GPX5-Tag2 transgenic mouse models, are compared. Both exhibit severely angulated sperm flagella explaining the infertility. As angulated spermatozoa are swollen cells, a failure in volume regulation is indicated. Differences between genotypes were also found: caudal spermatozoa from c-ros KO, but not GPX5-Tag2, could fertilise eggs in vitro; flagellar angulation occurred more within the epididymis of GPX5-Tag2 than c-ros KO mice; the osmotic pressure of cauda epididymidal fluid was lower only in GPX5-Tag2 mice; angulation of caudal sperm from c-ros KO, but not GPX5-Tag2 mice, decreased upon demembranation. These observations indicate that GPX5-Tag2 mice express an earlier, more severe defect. Gene chip analyses of the epididymides revealed decreased expression of the CRES (cystatin-related epididymal-spermatogenic) and MEP17 (murine epididymal protein 17) genes in both genotypes. Further analysis could pinpoint genes essential for epididymal regulation of sperm volume, explain infertility and suggest modes of male contraception.

Sodium-Inorganic Phosphate Cotransporter NaPi-IIb in the Epididymis and Its Potential Role in Male Fertility Studied in a Transgenic Mouse Model

Abstract Analysis by cDNA microarrays showed that in the murine epididymis, NaPi-IIb was the predominantly expressed epithelial isoform of the sodium-inorganic phosphate cotransporter and was markedly overexpressed in the proximal region in the infertile knockout (KO) compared to the fertile heterozygous (HET) c-ros transgenic mouse. The apparent up-regulation in the KO mouse confirmed by Northern and Western blot analyses could be explained by the absence of NaPi-IIb from the initial segment of the HET epididymis, as revealed by immunohistochemistry, and its presence on the epithelial brush border throughout the proximal epididymis of KO mice, where differentiation of the initial segment fails to occur. Both NaPi-IIb mRNA and protein were scarce or absent from the cauda epididymidis of both genotypes. A high content of inorganic phosphate was measured enzymatically in the HET cauda luminal fluid, with a 27% decrease in the KO mice. This decrease, presumably from a greater reabsorption of inorganic phosphate, particularly in the initial part of the KO epididymis, may disturb the normal process of sperm maturation in these infertile males. By contrast, no apparent consequences were observed for the transport of Na+ and Ca2+, the concentrations of which (∼26 mM and ∼30 μM, respectively) were measured by microelectrodes to be identical in the caudal fluid from both genotypes.

Gene and Protein Expression in the Epididymis of Infertile c-ros Receptor Tyrosine Kinase-Deficient Mice

Abstract Transgenic male mice bearing inactive mutations of the receptor tyrosine kinase c-ros lack the initial segment of the epididymis and are infertile. Several techniques were applied to determine differences in gene expression in the epididymal caput of heterozygous fertile (HET) and infertile homozygous knockout (KO) males that may explain the infertility. Complementary DNA arrays, gene chips, Northern and Western blots, and immunohistochemistry indicated that some proteins were downregulated, including the initial segment/proximal caput-specific genes c-ros, cystatin-related epididymal-spermatogenic (CRES), and lipocalin mouse epididymal protein 17 (MEP17), whereas other caput-enriched genes (glutathione peroxidase 5, a disintegrin and metalloproteinase [ADAM7], bone morphogenetic proteins 7 and 8a, A-raf, CCAAT/enhancer binding protein β, PEA3) were unchanged. Genes normally absent from the initial segment (γ-glutamyltranspeptidase, prostaglandin D2 synthetase, alkaline phosphatase) were expressed in the undifferentiated proximal caput of the KO. More distally, lipocalin 2 (24p3), CRISP1 (formerly MEP7), PEBP (MEP9), and mE-RABP (MEP10) were unchanged in expression. Immunohistochemistry and Western blots confirmed the absence of CRES in epididymal tissue and fluid and the continued presence of CRES in spermatozoa of the KO mouse. The glutamate transporters EAAC1 (EAAT3) and EAAT5 were downregulated and upregulated, respectively. The genes of over 70 transporters, channels, and pores were detected in the caput epididymidis, but in the KO, only three were downregulated and six upregulated. The changes in these genes could affect sperm function by modifying the composition of epididymal fluid and explain the infertility of the KO males. These genes may be targets for a posttesticular contraceptive.