Spermatogonial asynchrony in Tex14 mutant mice lacking intercellular bridges.

The existence of cytoplasmic passages between germ cells and their potential function in the control of the spermatogenic process has long been an intriguing question. Evidence of the important role of such structures, known as intercellular bridges (ICB), in spermatogenesis has been implicated by the failure of spermatogenesis in testis-expressed gene 14 (Tex14) mutant mice, which lack the ICBs, to progress past the pachytene spermatocyte stage. Using these Tex14 mutants, the present study evaluated, for the first time, the behavior and synchrony of the spermatogonial lineage in the absence of ICBs. Our data suggest that the absence of these cytoplasmic connections between cells affects the expansion of the undifferentiated type A (Aundiff) spermatogonia compartment and their transition to A1, resulting in a significant numerical reduction of differentiating A1 spermatogonia, but did not interfere with cell amplification during subsequent mitotic steps of differentiating spermatogonia from A1 through intermediate (In). However, beginning at the type B spermatogonia, the synchrony of differentiation was impaired as some cells showed delayed differentiation compared to their behavior in a normal seminiferous epithelium cycle. Thus although spermatogonial development is able to proceed, in the absence of ICBs in Tex14-/- mutants, the yield of cells, specific steps of differentiation, the synchrony of the cell kinetics, and the subsequent progression in meiosis are quantitatively lower than normal.

Eggs in the balance.

Polycyclic aromatic hydrocarbons (PAH), found in cigarette smoke and air pollution, interact with the aryl hydrocarbon receptor (Ahr) to cause reproductive defects. Mice lacking either Ahr or the pro-apoptotic protein Bax have an increased number of primordial follicles, and these mutant oocytes are resistant to PAH toxicity. A new study shows that the Bax promoter contains two core Ahr response elements, which are required for PAH stimulation of Bax promoter activity in oocytes. Thus, the toxic effects of PAH in oocytes are mediated directly by Ahr induction of the Bax pathway.

Follicle stimulating hormone is required for ovarian follicle maturation but not male fertility.

Follicle stimulating hormone (FSH) is a member of the glycoprotein hormone family that includes luteinzing hormone (LH), thyroid stimulating hormone, and chorionic gonadotropin. These heterodimeric hormones share a common alpha subunit and differ in their hormone-specific beta subunit. The biological activity is conferred only by the heterodimers. FSH and LH are synthesized in the same cells of the pituitary, the gonadotrophs. FSH receptors are localized to Sertoli cells of the testes and granulosa cells of the ovary. Minimal data has been accumulated so far involving human mutations in the FSH beta, LH beta, or the gonadotropin receptor genes. There are no known mouse strains with mutations in the FSH beta gene. To generate animal models for human diseases involving the gonadotropin signal transduction pathway, we produced mice deficient in the FSH beta subunit and therefore in FSH using ES cell technology. FSH-deficient females are infertile due to a block in folliculogenesis prior to antral follicle formation. Although FSH was predicted to be necessary for spermatogenesis and Sertoli cell growth in males, FSH-deficient males are fertile despite having small testes. Our findings have important implications for male contraceptive development in humans.

Insertion of Inhbb into the Inhba locus rescues the Inhba-null phenotype and reveals new activin functions.

The activins (dimers of betaA or betaB subunits, encoded by the genes Inhba and Inhbb, respectively) are TGF-beta superfamily members that have roles in reproduction and development. Whereas mice homozygous for the Inhba-null allele demonstrate disruption of whisker, palate and tooth development, leading to neonatal lethality, homozygous Inhbb-null mice are viable, fertile and have eye defects. To determine if these phenotypes were due to spatiotemporal expression differences of the ligands or disruption of specific ligand-receptor interactions, we replaced the region of Inhba encoding the mature protein with Inhbb, creating the allele Inhbatm2Zuk (hereafter designated InhbaBK). Although the craniofacial phenotypes of the Inhba-null mutation were rescued by the InhbaBK allele, somatic, testicular, genital and hair growth were grossly affected and influenced by the dosage and bioactivity of the allele. Thus, functional compensation within the TGF-beta superfamily can occur if the replacement gene is expressed appropriately. The novel phenotypes in these mice further illustrate the usefulness of insertion strategies for defining protein function.

Cyclin A1 is required for meiosis in the male mouse.

The mammalian A-type cyclin family consists of two members, cyclin A1 (encoded by Ccna1) and cyclin A2 (encoded by Ccna2). Cyclin A2 promotes both G1/S and G2/M transitions, and targeted deletion of Ccna2 in mouse is embryonic lethal3. Cyclin A1 is expressed in mice exclusively in the germ cell lineage and is expressed in humans at highest levels in the testis and certain myeloid leukaemia cells. To investigate the role of cyclin A1 and possible redundancy among the cyclins in vivo, we generated mice bearing a null mutation of Ccna1. Ccna1-/- males were sterile due to a block of spermatogenesis before the first meiotic division, whereas females were normal. Meiosis arrest in Ccna1-/- males was associated with increased germ cell apoptosis, desynapsis abnormalities and reduction of Cdc2 kinase activation at the end of meiotic prophase. Cyclin A1 is therefore essential for spermatocyte passage into the first meiotic division in male mice, a function that cannot be complemented by the concurrently expressed B-type cyclins.

Social amnesia in mice lacking the oxytocin gene.

The development of social familiarity in rodents depends predominantly on olfactory cues and can critically influence reproductive success. Researchers have operationally defined this memory by a reliable decrease in olfactory investigation in repeated or prolonged encounters with a conspecific. Brain oxytocin (OT) and vasopressin (AVP) seem to modulate a range of social behaviour from parental care to mate guarding. Pharmacological studies indicate that AVP administration may enhance social memory, whereas OT administration may either inhibit or facilitate social memory depending on dose, route or paradigm. We found that male mice mutant for the oxytocin gene (Oxt-/-) failed to develop social memory, whereas wild-type (Oxt+/+) mice showed intact social memory. Measurement of both olfactory foraging and olfactory habituation tasks indicated that olfactory detection of non-social stimuli is intact in Oxt-/- mice. Spatial memory and behavioural inhibition measured in a Morris water-maze, Y-maze, or habituation of an acoustic startle also seemed intact. Treatment with OT but not AVP rescued social memory in Oxt-/- mice, and treatment with an OT antagonist produced a social amnesia-like effect in Oxt+/+ mice. Our data indicate that OT is necessary for the normal development of social memory in mice and support the hypothesis that social memory has a neural basis distinct from other forms of memory.

The role of the asparagine-linked oligosaccharides of the alpha subunit in the secretion and assembly of human chorionic gonadotrophin.

Human chorionic gonadotropin (hCG) is a member of a family of heterodimeric glycoprotein hormones that have a common alpha subunit but differ in their hormone-specific beta subunit. Site-directed mutagenesis of the two asparagine-linked glycosylation sites of hCG alpha was used to study the function of the individual oligosaccharide chains in secretion and subunit assembly. Expression vectors for the alpha genes (wild-type and mutant) and the hCG beta gene were constructed and transfected into Chinese hamster ovary cells. Loss of the oligosaccharide at position 78 causes the mutant subunit to be degraded quickly and less than 20% is secreted. However, the presence of hCG beta stabilizes this mutant and allows approximately 45% of the subunit in the form of a dimer to exit the cell. Absence of carbohydrate at asparagine 52 does not perturb the stability or transport of the alpha subunit but does affect dimer secretion; under conditions where this mutant or hCG beta was in excess, less than 30% is secreted in the form of a dimer. Mutagenesis of both glycosylation sites affects monomer and dimer secretion but at levels intermediate between the single-site mutants. We conclude that there are site-specific functions of the hCG alpha asparagine-linked oligosaccharides with respect to the stability and assembly of hCG.

Mutagenesis and chimeric genes define determinants in the beta subunits of human chorionic gonadotropin and lutropin for secretion and assembly.

Chorionic gonadotropin (CG) and lutropin (LH) are members of a family of glycoprotein hormones that share a common alpha subunit but differ in their hormone-specific beta subunits. The glycoprotein hormone beta subunits share a high degree of amino acid homology that is most evident for the LH beta and CG beta subunits having greater than 80% sequence similarity. However, transfection studies have shown that human CG beta and alpha can be secreted as monomers and can combine efficiently to form dimer, whereas secretion and assembly of human LH beta is less efficient. To determine which specific regions of the LH beta and CG beta subunits are responsible for these differences, mutant and chimeric LH beta-CG beta genes were constructed and transfected into CHO cells. Expression of these subunits showed that both the hydrophobic carboxy-terminal seven amino acids and amino acids Trp8, Ile15, Met42, and Asp77 together inhibit the secretion of LH beta. The carboxy-terminal amino acids, along with Trp8, Ile15, Met42, and Thr58 are implicated in the delayed assembly of LH beta. These unique features of LH beta may also play an important role in pituitary intracellular events and may be responsible for the differential glycosylation and sorting of LH and FSH in gonadotrophs.

Gonadotropin beta subunits determine the rate of assembly and the oligosaccharide processing of hormone dimer in transfected cells.

The glycoprotein hormones lutropin (LH) and chorionic gonadotropin (CG) share a common structure consisting of an identical alpha subunit noncovalently linked to a hormone-specific beta subunit. While LH is produced in the anterior pituitary, CG is synthesized in placenta. To compare the assembly, processing, and secretion of human LH and CG in the same cell type, we have expressed their subunits, individually and together, in mouse C-127 mammary tumor cells. Analysis of transfected clones revealed an unexpected difference in the secretion of individually expressed subunits. Whereas alpha and CG beta subunits were rapidly and quantitatively secreted, only 10% of newly synthesized LH beta subunit reached the medium. The remaining subunit was found in an intracellular, endoglycosidase H (endo H)-sensitive pool that had a turnover rate of approximately 8 h. Coexpression with alpha subunit resulted in "rescue" of LH beta subunit by formation of LH dimer, which was efficiently secreted. However, combination of LH beta with alpha was slow, with an overall efficiency of only 50% despite the presence of excess alpha. In contrast, CG beta was rapidly assembled with the alpha subunit after synthesis. The two beta subunits also differed in their influence on the N-linked oligosaccharide processing of combined alpha. The oligosaccharides of LH dimer were endo H resistant, while those of CG dimer remained partially endo H sensitive. Thus, despite a high degree of homology between LH beta and CG beta, the two subunits differ in their secretion as free subunits, their rate of assembly with alpha subunit, and in their effect on the N-linked oligosaccharide processing of combined alpha.

Continuous fatty acid oxidation and reduced fat storage in mice lacking acetyl-CoA carboxylase 2.

Malonyl-coenzyme A (malonyl-CoA), generated by acetyl-CoA carboxylases ACC1 and ACC2, is a key metabolite in the regulation of energy homeostasis. Here, we show that Acc2-/- mutant mice have a normal life span, a higher fatty acid oxidation rate, and lower amounts of fat. In comparison to the wild type, Acc2-deficient mice had 10- and 30-fold lower levels of malonyl-CoA in heart and muscle, respectively. The fatty acid oxidation rate in the soleus muscle of the Acc2-/- mice was 30% higher than that of wild-type mice and was not affected by addition of insulin; however, addition of insulin to the wild-type muscle reduced fatty acid oxidation by 45%. The mutant mice accumulated 50% less fat in their adipose tissue than did wild-type mice. These results raise the possibility that pharmacological manipulation of ACC2 may lead to loss of body fat in the context of normal caloric intake.

Nine genes abundantly expressed in the epididymis are not essential for male fecundity in mice.

BACKGROUND: Spermatozoa become competent for fertilization during transit through the epididymis. As spermatozoa from the proximal caudal epididymis can fertilize eggs, proteins from the caput and corpus epididymis are required for sperm maturation. OBJECTIVES: Microarray analysis identified that more than 17,000 genes are expressed in the epididymis; however, few of these genes demonstrate expression restricted to the epididymis. To analyze epididymis-enriched gene function in vivo, we generated knockout (KO) mutations in nine genes that are abundantly expressed in the caput and corpus region of the epididymis. MATERIALS AND METHODS: KO mice were generated using the CRISPR/Cas9 system. The histology of the epididymis was observed with hematoxylin and eosin staining. KO males were caged with wild-type females for 3-6 months to check fertility. RESULTS: We generated individual mutant mouse lines having indel mutations in Pate1, Pate2, or Pate3. We also deleted the coding regions of Clpsl2, Epp13, and Rnase13, independently. Finally, the 150 kb region encoding Gm1110, Glb1l2, and Glb1l3 was deleted to generate a triple KO mouse line. Histology of the epididymis and sperm morphology of all KO lines were comparable to control males. The females mated with these KO males delivered pups at comparable numbers as control males. DISCUSSION AND CONCLUSION: We revealed that nine genes abundantly expressed in the caput and corpus epididymis are dispensable for sperm function and male fecundity. CRISPR/Cas9-mediated KO mice generation accelerates the screening of epididymis-enriched genes for potential functions in reproduction.

Activin betaC and betaE genes are not essential for mouse liver growth, differentiation, and regeneration.

The liver is an essential organ that produces several serum proteins, stores vital nutrients, and detoxifies many carcinogenic and xenobiotic compounds. Various growth factors positively regulate liver growth, but only a few negative regulators are known. Among the latter are the transforming growth factor beta (TGF-beta) superfamily members TGF-beta1 and activin A. To study the function of novel activin family members, we have cloned and generated mice deficient in the activin betaC and betaE genes. Expression analyses demonstrated that these novel genes are liver specific in adult mice. Here, we show by RNase protection that activin betaC transcripts are present in the liver beginning at embryonic day 11.5 (E11.5) whereas activin betaE expression is detected starting from E17.5. Gene targeting in embryonic stem cells was used to generate mice with null mutations in either the individual activin betaC and betaE genes or both genes. In contrast to the structurally related activin betaA and betaB subunits, which are necessary for embryonic development and pituitary follicle-stimulating hormone homeostasis, mice deficient in activin betaC and betaE were viable, survived to adulthood, and demonstrated no reproductive abnormalities. Although activin betaC and betaE mRNAs are abundantly expressed in the liver of wild-type mice, the single and double mutants did not show any defects in liver development and function. Furthermore, in the homozygous mutant mice, liver regeneration after >70% partial hepatectomy was comparable to that in wild-type mice. Our results suggest that activin betaC and betaE are not essential for either embryonic development or liver function.

Disruption of gamma-glutamyl leukotrienase results in disruption of leukotriene D(4) synthesis in vivo and attenuation of the acute inflammatory response.

To study the function of gamma-glutamyl leukotrienase (GGL), a newly identified member of the gamma-glutamyl transpeptidase (GGT) family, we generated null mutations in GGL (GGL(tm1)) and in both GGL and GGT (GGL(tm1)-GGT(tm1)) by a serial targeting strategy using embryonic stem cells. Mice homozygous for GGL(tm1) show no obvious phenotypic changes. Mice deficient in both GGT and GGL have a phenotype similar to the GGT-deficient mice, but approximately 70% of these mice die before 4 weeks of age, at least 2 months earlier than mice deficient only in GGT. These double-mutant mice are unable to cleave leukotriene C(4) (LTC(4)) to LTD(4), indicating that this conversion is completely dependent on the two enzymes, and in some organs (spleen and uterus) deletion of GGL alone abolished more than 90% of this activity. In an experimental model of peritonitis, GGL alone is responsible for the generation of peritoneal LTD(4). Further, during the development of peritonitis, GGL-deficient mice show an attenuation in neutrophil recruitment but not of plasma protein influx. These findings demonstrate an important role for GGL in the inflammatory response and suggest that LTC(4) and LTD(4) have distinctly different functions in the inflammatory process.

Cloning of the human activin receptor cDNA reveals high evolutionary conservation.

The entire coding region of the human activin receptor was obtained from a human testis cDNA library. Analysis of the 1539 nucleotide (513 amino acid) sequence of the receptor reveals that there are only 83 nucleotide differences compared to the coding sequence of the mouse activin receptor. Similar to its ligands, the amino acid sequence of the activin receptor is highly conserved with only two conservative amino acid differences (Lys-39 and Val-92 in human versus Arg-39 and Ile-92 in the mouse). This high degree of conservation of the activin receptor illustrates a strong evolutionary selection and confirms that activin and its receptor play an important role in development.

Structural analysis of the mouse activin beta C gene.

Using a mouse activin beta C cDNA probe, we have cloned over 38 kb of genomic DNA encompassing the mouse activin beta C gene. Mouse activin beta C is encoded by 2 exons separated by a large 12.1 kb intron. Exon 1 encodes the 17 amino acid signal peptide and 88 amino acids of the propeptide. Exon 2 encodes the remaining 130 amino acids of the propeptide and the entire 117 amino acid mature peptide. Unlike the activin beta A and beta B expression patterns, Northern blot analysis of adult mouse tissues shows that the activin beta C mRNA is expressed only in the liver as a major species of approximately 2.1 kb. The liver-specific expression of activin beta C suggests an important role of dimeric activin beta C in normal liver function. These studies allow us to address the function of activin beta C in mammalian development.

Structure of the mouse growth/differentiation factor 9 gene.

Using a mouse GDF-9 cDNA as a probe, over 20 kb of sequence encompassing the GDF-9 gene was isolated from a mouse 129SvEv genomic library. Sequence analysis of the exons, exon-intron boundaries, and 5'- and 3'-non-translated regions was used to establish the structure of the mouse GDF-9 gene. The GDF-9 gene is encoded by two exons separated by a 2.9 kb intron. Multiple putative transcription start sites are detected between 31 and 57 bp upstream of the start site of translation and a putative polyadenylation signal lies 342 bp 3' of the end of translation. Knowledge of the GDF-9 gene structure will enable us to further understand the role of GDF-9 in ovarian physiology and development.

Smad5 is required for mouse primordial germ cell development.

Smad5, together with Smad1 and Smad8, have been implicated as downstream signal mediators for several bone morphogenetic proteins (BMPs). Recent studies have shown that primordial germ cells (PGCs) are absent or greatly reduced in Bmp4 or Bmp8b mutant mice. To define the role of Smad5 in PGC development, we examined PGC number in Smad5 mutant mice by Oct4 whole-mount in situ hybridization and alkaline phosphatase staining. We found ectopic PGC-like cells in the amnion of some Smad5 mutant mice, however, the total number of PGCs was greatly reduced or completely absent in Smad5 mutant embryos, similar to Bmp4 or Bmp8b mutant embryos. Therefore, Smad5 is an important factor involved in PGC generation and localization.

Functional analysis of mammalian members of the transforming growth factor-beta superfamily.

Analysis of growth factor function has come from studies both in vitro and in vivo. However, the generation of mice deficient in a specific growth factor via gene targeting (for example, "knockout") strategies in embryonic stem (ES) cells will often evaluate the essential roles of the protein in vivo and, in many cases, discover new functions. In this review, studies to date are discussed on the generation and analysis of mice deficient in members of the transforming growth factor (TGF-beta) superfamily. Among the genes targeted via ES cell strategies are the TGF-beta1, Müllerian-inhibiting substance (MIS), inhibin alpha, activin betaA, and activin betaB genes. In addition, the mouse short ear and brachypodism mutants and insertional mutant 413-d have been identified as mutations in the BMP-5, GDF-5, and nodal loci, respectively. These studies have led to critical insights into the functions of these gene products and have further emphasized the importance of members of the TGF-beta superfamily in mammalian development, reproduction, and oncogenesis.

Expression of recombinant human choriogonadotropin in Chinese hamster ovary glycosylation mutants.

Human CG, a member of the glycoprotein hormone family that includes LH, FSH, and TSH, is composed of two nonidentical subunits each containing two asparagine linked (N-linked) oligosaccharides. The role of the oligosaccharides in the action of these hormones is unclear. To examine the structure-activity relationships of the glycoprotein hormone oligosaccharides using nonenzymatic and nonchemical methods, we transfected CG subunit genes into mutant cell lines derived from Chinese hamster ovary cells. Two mutant cell lines that synthesize truncated oligosaccharides were used. Cell line 15B, lacking N-acetylglucosaminyltransferase I, synthesizes N-linked carbohydrates containing Man5 oligomannosyl structures, and 1021, defective in transporting CMP-sialic acid into the Golgi, results in sialic-acid deficient glycoproteins. The binding of these derivatives to the LH/CG receptor did not differ significantly from purified CG (CR119), but the ability of the mutant hormones to stimulate cAMP biosynthesis in vitro is reduced compared to wild-type CG or CR119. Since the amino acid sequence of CG from the mutant and wild-type cells is identical, these data indicate that oligosaccharide structures, while not influencing receptor binding, directly affect signal transduction.

Insulin-like growth factor I regulates gonadotropin responsiveness in the murine ovary.

The present study shows that insulin-like growth factor I (IGF-I) and FSH receptor (FSHR) mRNAs are selectively coexpressed in a subset of healthy-appearing follicles in murine ovaries, irrespective of cycle stage. Aromatase gene expression, a prime marker for FSH effect, is found only in IGF-I/FSHR-positive follicles, showing that these are healthy, gonadotropin-responsive follicles. Given the striking coexpression of FSHR and IGF-I, we hypothesized that FSH was responsible for follicular IGF-I expression. We found, however, that granulosa cell IGF-I mRNA levels are not reduced in hypophysectomized (+/-PMSG) or FSH knockout mice, indicating that FSH does not have a major role in regulation of granulosa cell IGF-I gene expression. To test the alternative hypothesis that IGF-I regulates FSHR gene expression, we studied ovaries from IGF-I knockout mice. FSHR mRNA was significantly reduced in ovaries from homozygous IGF-I knockout compared with wild type mice and was restored to control values by exogenous IGF-I treatment. The functional significance of the reduced FSHR gene expression in IGF-I knockout ovaries is suggested by reduced aromatase expression and by the failure of their follicles to develop normally beyond the early antral stage. In fact, IGF-I knockout and FSH knockout ovaries appear very similar in terms of arrested follicular development. In summary, we have shown that IGF-I and FSHR are selectively coexpressed in healthy, growing murine follicles and that FSH does not affect IGF-I expression but that IGF-I augments granulosa cell FSHR expression. These data suggest that ovarian IGF-I expression serves to enhance granulosa cell FSH responsiveness by augmenting FSHR expression.