Superoxide and its derivatives are increasingly implicated in the regulation of physiological functions from oxygen sensing and blood pressure regulation to lymphocyte activation and sperm-oocyte fusion. Here we describe a novel superoxide-generating NADPH oxidase referred to as NADPH oxidase 5 (NOX5). NOX5 is distantly related to the gp91 phox subunit of the phagocyte NADPH oxidase with conserved regions crucial for the electron transport (NADPH, FAD and heme binding sites). However, NOX5 has a unique N-terminal extension that contains three EF hand motifs. The mRNA of NOX5 is expressed in pachytene spermatocytes of testis and in B-and T-lymphocyte-rich areas of spleen and lymph nodes. When heterologously expressed, NOX5 was quiescent in unstimulated cells. However, in response to elevations of the cytosolic Ca 2؉ concentration it generated large amounts of superoxide. Upon Ca 2؉ activation, NOX5 also displayed a second function: it became a proton channel, presumably to compensate charge and pH alterations due to electron export. In summary, we have identified a novel NADPH oxidase that generates superoxide and functions as a H ؉ channel in a Ca 2؉ -dependent manner. NOX5 is likely to be involved in Ca 2؉ -activated, redox-dependent processes of spermatozoa and lymphocytes such as sperm-oocyte fusion, cell proliferation, and cytokine secretion.
NOX1, an NADPH oxidase expressed predominantly in colon epithelium, shows a high degree of similarity to the phagocyte NADPH oxidase. However, superoxide generation by NOX1 has been difficult to demonstrate. Here we show that NOX1 generates superoxide when co-expressed with the p47 phox and p67 phox subunits of the phagocyte NADPH oxidase but not when expressed by itself. Since p47 phox and p67 phox are restricted mainly to myeloid cells, we searched for their homologues and identified two novel cDNAs. The mRNAs of both homologues were found predominantly in colon epithelium. Differences between the homologues and the phagocyte NADPH oxidase subunits included the lack of the autoinhibitory domain and the protein kinase C phosphorylation sites in the p47 phox homologue as well as the absence of the first Src homology 3 domain and the presence of a hydrophobic stretch in the p67 phox homologue. Co-expression of NOX1 with the two novel proteins led to stimulus-independent high level superoxide generation. Stimulus dependence of NOX1 was restored when p47 phox was used to replace its homologue. In conclusion, NOX1 is a superoxide-generating enzyme that is activated by two novel proteins, which we propose to name NOXO1 (NOX organizer 1) and NOXA1 (NOX activator 1).Superoxide generation by phagocytes plays a crucial role in the elimination of invading microorganisms. It is catalyzed by the phagocyte NADPH oxidase, an enzyme consisting of two transmembrane subunits, p22 phox and gp91 phox , and at least three cytosolic subunits, p47 phox , p67 phox , and Rac2 (1). Upon activation, the NADPH oxidase subunits assemble, and electrons are transported from intracellular NADPH to extracellular oxygen by the flavo-heme gp91 phox subunit (2). Recently six gp91 phox homologues have been described in mammals: NOX1 1 (3, 4), NOX3 (5, 6), and NOX4 (7, 8) with an overall structure similar to gp91 phox (alias NOX2), NOX5 with an N-terminal EF hand-containing extension (9), and DUOX1 and DUOX2 with an additional peroxidase homology domain (10 -12). NOX1 is found mainly in colon epithelium (3, 4); NOX3 in embryonic kidney (5, 6), NOX4 in the kidney cortex (7, 8), NOX5 in lymphoid organs and testis (9), DUOX1 in thyroid and lung, and DUOX2 in thyroid and colon (10 -12).Based on their primary structure all members of the NOX/ DUOX family should be flavo-heme electron transporters. However, it is not established whether all NOX enzymes transfer electrons to oxygen or whether some of them may use other electron acceptors as has been shown for a yeast homologue of gp91phox that functions as a ferric reductase (13). Among NOX enzymes, only gp91 phox and NOX5 have appeared capable of generating large amounts of superoxide, both of them in a stimulus-dependent manner (1, 9).Based on data gained with NOX1-transfected NIH 3T3 cell clones NOX1 has been suggested to be a subunit-independent, low capacity superoxide-generating enzyme involved in the regulation of mitogenesis (4, 14). However, we have not been able to measure any superoxide generat...
Reactive oxygen species (ROS) play a major role in drug-, noise-, and age-dependent hearing loss, but the source of ROS in the inner ear remains largely unknown. Herein, we demonstrate that NADPH oxidase (NOX) 3, a member of the NOX/dual domain oxidase family of NADPH oxidases, is highly expressed in specific portions of the inner ear. As assessed by real-time PCR, NOX3 mRNA expression in the inner ear is at least 50-fold higher than in any other tissues where its expression has been observed (e.g. fetal kidney, brain, skull). Microdissection and in situ hybridization studies demonstrated that NOX3 is localized to the vestibular and cochlear sensory epithelia and to the spiral ganglions. Transfection of human embryonic kidney 293 cells with NOX3 revealed that it generates low levels of ROS on its own but produces high levels of ROS upon co-expression with cytoplasmic NOX subunits. NOX3-dependent superoxide production required a stimulus in the absence of subunits and upon co-expression with phagocyte NADPH oxidase subunits p47 phox and p67 phox , but it was stimulus-independent upon co-expression with colon NADPH oxidase subunits NOX organizer 1 and NOX activator 1. Pre-incubation of NOX3-transfected human embryonic kidney 293 cells with the ototoxic drug cisplatin markedly enhanced superoxide production, in both the presence and the absence of subunits. Our data suggest that NOX3 is a relevant source of ROS generation in the cochlear and vestibular systems and that NOX3-dependent ROS generation might contribute to hearing loss and balance problems in response to ototoxic drugs.The inner ear is a highly complex structure involved in hearing and balancing. The conversion of sound into electrical signals occurs within the cochlea, in the organ of Corti, and the electrical signals are conducted by the axons of spiral ganglion neurons to the brain. The linear movement of the head is sensed by the otolith organs (utricle and saccule) and the rotation movements by the ampulla of the semicircular canals. The signals generated in the vestibular system are transmitted by the vestibular ganglion neurons to the central nervous system.Hearing impairment caused by loss of cochlear function occurs frequently, if not invariably, over a lifetime. Noise and ototoxic chemicals may lead to a precocious, rapid hearing loss, whereas aging leads to a more insidious, chronic loss of hearing. Research over the last decades has identified reactive oxygen species (ROS) 1 as the major factor mediating hearing loss (1). ROS is generated within the cochlea after exposure to ototoxic drugs (e.g. cisplatin (2, 3), aminoglycoside antibiotics (3)) or to noise (4). Signs of oxidative stress, such as DNA damage and lipid peroxidation, have been documented in vivo in response to those challenges (5, 6), as well as in cochlear aging (7). The vestibular system is also damaged by ototoxic drugs (8, 9) in a process that includes excessive ROS production (10, 11).Although the role of oxidative stress in inner ear damage is well established, its source ...
During the haploid phase of mammalian spermatogenesis, nucleosomal chromatin is ultimately repackaged by small, highly basic protamines to generate an extremely compact, toroidal chromatin architecture that is critical to normal spermatozoal function. In common with several species, however, the human spermatozoon retains a small proportion of its chromatin packaged in nucleosomes. As nucleosomal chromatin in spermatozoa is structurally more open than protamine-packaged chromatin, we considered it likely to be more accessible to exogenously applied endonucleases. Accordingly, we have used this premise to identify a population of endonuclease-sensitive DNA sequences in human and murine spermatozoa. Our results show unequivocally that, in contrast to the endonuclease-resistant sperm chromatin packaged by protamines, regions of increased endonuclease sensitivity are closely associated with gene regulatory regions, including many promoter sequences and sequences recognized by CCCTC-binding factor (CTCF). Similar differential packaging of promoters is observed in the spermatozoal chromatin of both mouse and man. These observations imply the existence of epigenetic marks that distinguish gene regulatory regions in male germ cells and prevent their repackaging by protamines during spermiogenesis. The ontology of genes under the control of endonuclease-sensitive regulatory regions implies a role for this phenomenon in subsequent embryonic development.
The predominant testicular gap junctional protein connexin43 (cx43) is located between neighboring Sertoli cells (SCs) and between SCs and germ cells. It is assumed to be involved in testicular development, cell differentiation, initiation, and maintenance of spermatogenesis with alterations of its expression being correlated with various testicular disorders. Because total disruption of the cx43 gene leads to perinatal death, we generated a conditional cx43 knockout (KO) mouse using the Cre/loxP recombination system, which lacks the cx43 gene solely in SCs (SCCx43KO), to evaluate the SC-specific functions of cx43 on spermatogenesis in vivo. Adult SCCx43KO(-/-) mice showed normal testis descent and development of the urogenital tract, but testis size and weight were drastically lower compared with heterozygous and wild-type littermates. Histological analysis and quantitation of mRNA expression of germ cell-specific marker genes revealed a significant reduction in the number of spermatogonia but increased SC numbers/tubule with only a few tubules left showing normal spermatogenesis. Thus, SC-specific deletion of cx43 mostly resulted in an arrest of spermatogenesis at the level of spermatogonia or SC-only syndrome and in intratubular SC clusters. Our data demonstrate for the first time that cx43 expression in SCs is an absolute requirement for normal testicular development and spermatogenesis.
Reactive oxygen species (ROS) generated by the NOX family of NADPH oxidases have been described to act as second messengers regulating cell growth and differentiation. However, such a function has hitherto not been convincingly demonstrated. We investigated the role of NOX-derived ROS in cardiac differentiation using mouse embryonic stem cells. ROS scavengers prevented the appearance of spontaneously beating cardiac cells within embryoid bodies. Downregulation of NOX4, the major NOX isoform present during early stages of differentiation, suppressed cardiogenesis. This was rescued by a pulse of low concentrations of hydrogen peroxide 4 d before spontaneous beating appears. Mechanisms of ROS-dependent signaling included p38 mitogen-activated protein kinase (MAPK) activation and nuclear translocation of the cardiac transcription factor myocyte enhancer factor 2C (MEF2C). Our results provide first molecular evidence that the NOX family of NADPH oxidases regulate vertebrate developmental processes. INTRODUCTIONReactive oxygen species (ROS) are generated either in a nonregulated manner as side products of several enzymatic systems (e.g., cyclooxygenases, nitric oxide [NO] synthases, mitochondrial cytochromes) or in a regulated way as main products of superoxide producing enzymes, the NADPH oxidases. In the mouse, the family of NADPH oxidases includes NOX1, NOX2 (gp91 phox ), NOX3, and NOX4.Excessive cellular generation of ROS, such as superoxide anions (O 2 Ϫ ) and hydrogen peroxide (H 2 O 2 ), is potentially destructive and is used by phagocytes to kill invading microorganisms. Under normal conditions, scavenging mechanisms (e.g., superoxide dismutase, catalase, glutathioneglutathione peroxidase system) remove excessive amounts of ROS. Under stress conditions, however, the production of ROS may exceed the reducing capacity of the cell and damage cellular functions. Small amounts of ROS, on the other hand, can function as intracellular second messengers and activate signaling cascades involved in growth and differentiation of many cell types (for review see Rhee, 1999;Laloi et al., 2004). For example, the MAP kinase-signaling pathway is sensitive to ROS (Torres and Forman, 2003). Moreover, distinct signaling pathways have differential sensitivity to oxidative stress, leading to dose-dependent effect on, for example, cardiomyocytes on which ROS can induce hypertrophy or apoptosis (Kwon et al., 2003). Transcription factors such as NF-B, p53, and AP-1 are redox-sensitive and can be directly modified by ROS, providing a link with the control of gene expression (Morel and Barouki, 1999).Cardiac differentiation can be studied by differentiating mouse embryonic stem cells (ESC) into embryoid bodies (EB), where the appearance of spontaneously beating cardiomyocytes is observed after 7-8 d of culture. This system thus provides a unique experimental model to study the role of ROS and ROS-generating enzymes in the regulation of cardiomyocyte growth and differentiation in vitro. Previous reports have shown a link between ROS and...
Nucleosome-to-protamine exchange during mammalian spermiogenesis is essential for compaction and protection of paternal DNA. It is interesting that, depending on the species, 1% to 15% of nucleosomes are retained, but the generalizability and biological function of this retention are unknown. Here, we show concordantly in human and bovine that nucleosomes remained in sperm chromatin predominantly within distal intergenic regions and introns and associated with centromere repeats and retrotransposons (LINE1 and SINEs). In contrast, nucleosome depletion concerned particularly exons, 5'-UTR, 3'-UTR, TSS, and TTS and was associated with simple and low-complexity repeats. Overlap of human and bovine genes exhibiting nucleosome preservation in the promoter and gene body revealed a significant enrichment of signal transduction and RNA- and protein-processing factors. Our study demonstrates the genome-wide uniformity of the nucleosome preservation pattern in mammalian sperm and its connection to repetitive DNA elements and suggests a function in preimplantation processes for paternally derived nucleosomes.
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