EC:5.99.1.2 - FACTA Search

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Query: EC:5.99.1.2 (topoisomerase)
9,166 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

DNase I-hypersensitivity of rat spermatogenic cells was analyzed 1) to establish overall patterns of hypersensitivity in individual cell types, 2) to correlate these patterns with known changes in chromatin organization and function, and 3) to provide a foundation for further analyses examining DNase I-hypersensitivity and the localization of specific genes during spermatogenesis. Parameters for in situ nick translation, using radioactive and fluorescent probes to visualize DNase I-hypersensitive regions (DHR), were established for fixed and sectioned testicular preparations, permeabilized cells, and isolated germ cell nuclei. As anticipated, the pattern of DHR changed in a cell-type specific manner during the course of spermatogenesis, reflective of known stage-dependent alterations in the composition and structure of both the chromatin and the nuclear lamina/matrix as well as changes in gene expression. DHR in preleptotene spermatocytes were primarily peripheral, while in pachytene spermatocytes they were localized along the condensed chromosomes. The pattern of DHR changed from "checkerboard" in steps 7-8 round spermatid nuclei to "lamellar" in steps 10-11 elongating spermatids. In steps 12-13 elongating spermatids. DHR were localized throughout the nuclei or in a graded manner--increasing from anterior to posterior and mirroring the pattern of chromatin condensation. However, unlike the case in other stages, DNA of steps 12-13 elongating spermatids was exquisitely sensitive to nick translation even in the absence of exogenous DNase I. In contrast to the labeling of earlier stages, steps 16-19 spermatids and mature spermatozoa did not demonstrate DNase I-hypersensitivity under any conditions employed. A variety of agents that interact with topoisomerase II and DNA (teniposide, novobiocin, ethidium bromide, and adenosine triphosphate) were tested to determine the basis for the unique sensitivity to nick translation of steps 12-13 elongating spermatids. None of the agents tested, however, affected this unique labeling. The sensitivity of steps 12-13 elongating spermatids to nick translation in the absence of exogenous nuclease indicators the presence of endogenous nicks, which may relieve torsional stress and aid rearrangement as the chromatin is packaged into a form characteristic of the mature spermatozoon.
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PMID:Localization of DNase I-hypersensitive regions during rat spermatogenesis: stage-dependent patterns and unique sensitivity of elongating spermatids. 131 43

Monoclonal antibodies directed against four different polypeptide epitopes on the Mr approximately 94,000 steroid-binding subunit of the rat liver cytosolic glucocorticoid receptor (GcR) were used to probe Western blots of epididymal spermatozoa from rats and mice. Two sperm polypeptides with apparent molecular weights of 94,000 (indistinguishable in size from the liver GcR subunit) and 150,000 reacted with these antibodies. Other polypeptides that are present in a wide variety of somatic cells [lamin-A, -B, and -C; topoisomerase-I; poly(ADP-ribose) polymerase; the 62-kilodalton internal nuclear matrix protein; the nucleolar protein B23; and histone H1] could not be detected in these preparations of spermatozoa, thus appearing to rule out contamination by somatic cells. Rat and mouse pachytene spermatocytes and round spermatids contained much lower amounts of the Mr approximately 94,000 and 150,000 polypeptides. These results suggested that the steroid-binding subunit of the GcR might be accumulated late in spermatogenesis. Consistent with this view, a 6-kilobase mRNA (identical in size to a mRNA detected in mouse somatic cell lines) was detected when Northern blots of mouse round spermatid RNA were probed with a cDNA to the steroid-binding GcR subunit. Although the results described above suggest the presence of GcR in rodent sperm, high affinity binding of glucocorticoids to epididymal sperm could not be detected in a whole cell binding assay. Further analysis revealed that the Mr approximately 90,000 heat shock protein (hsp90), a component reportedly required for high affinity ligand binding to the GcR, was present in early germ cells, but absent from rodent epididymal sperm. These results suggest that the Mr approximately 94,000 steroid-binding subunit of the GcR and an immunologically related Mr approximately 150,000 polypeptide are specifically accumulated during the later stages of rodent spermatogenesis, but are not assembled into receptor complexes capable of binding steroid. In addition, these results support the view that hsp90 is required for high affinity binding of glucocorticoids to the Mr approximately 94,000 GcR subunit in intact cells.
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PMID:Evidence that rodent epididymal sperm contain the Mr approximately 94,000 glucocorticoid receptor but lack the Mr approximately 90,000 heat shock protein. 157 14

The consequences of error during meiotic division in spermatogenesis can be serious: aneuploid spermatozoa, embryonic lethality, and developmental abnormalities. Recombination between homologs is essential to ensure normal segregation; thus the spermatocyte must time division precisely so that it occurs after recombination between chromosomes and accumulation of the cell-cycle machinery necessary to ensure an accurate segregation of chromosomes. We use two systems to investigate meiotic division during spermatogenesis in the mouse: pharmacological induction of meiotic metaphase in cultured spermatocytes and transillumination-mediated dissection of stage XII seminiferous tubule segments to monitor progress through the division phase. By these approaches we can assess timing of acquisition of competence for the meiotic division phase and the temporal order of events as division proceeds. Competence for the meiotic division arises in the mid-pachytene stage of meiotic prophase, after chromosomes have synapsed and coincident with the accumulation of the cell-cycle regulatory protein CDC25C. The activity of both MPF and topoisomerase II are required. The earliest hallmarks of the division phase are nuclear envelope breakdown, followed by phosphorylation of histone H3 and chromosome condensation. These events are likely to be monitored by checkpoint mechanisms since checkpoint proteins can be localized in nuclei and DNA-damaging agents delay entry into the meiotic division phase. Understanding how the spermatocyte regulates its entry into the meiotic division phase can help clarify the natural mechanisms ensuring accurate chromosome segregation and preventing aneuploidy. J. Exp. Zool. (Mol. Dev. Evol.) 285:243-250, 1999.
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PMID:What are the spermatocyte's requirements for successful meiotic division? 1049 23

Mouse spermatozoa and androgenetic one-cell embryos (androgenones) at various developmental stages were exposed to etoposide (1 microM), a topoisomerase II (topo II) poison, or to either of two catalytic inhibitors: ICRF-193 (10 microM) or merbarone (50 microM), for 2 h in order to study the clastogenic effects of these drugs on remodeled sperm chromatin. None of the drugs induced structural chromosome aberrations in condensed chromatin of spermatozoa. However, etoposide and merbarone exerted strong clastogenic actions on remodeled chromatin of androgenones. Expanding chromatin was most sensitive to both of these drugs at the time of pronuclear formation, as nearly 100% of androgenones exposed at this stage displayed structural chromosome aberrations. ICRF-193 did not affect sperm chromatin at all remodeling stages. A majority of the aberrations induced by etoposide and merbarone were of the chromosome-type. Chromosome exchanges, including translocation, dicentric, and ring chromosomes, preferentially appeared following exposure at the early stages of chromatin remodeling. Thus, despite their different modes of topo II inhibition, etoposide and merbarone showed similar clastogenic actions on remodeled sperm chromatin. These results suggest that the formation of transient DNA cleavage, mediated by ooplasmic topo II, accompanies the remodeling. The present findings provide insight into the mechanisms by which structural aberrations are generated in paternal chromosomes.
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PMID:Chromosome analysis of mouse one-cell androgenones derived from a sperm nucleus exposed to topoisomerase II inhibitors at pre- and post-fertilization stages. 1549 39

In experiments involving different germ-cell stages, we had previously found meiotic prophase of the male mouse to be vulnerable to the induction of several types of genetic damage by the topoisomerase-II inhibitor etoposide. The present study of etoposide effects involved two end points of meiotic events known to occur in primary spermatocytes--chromosomal crossing-over and segregation. By following assortment of 13 microsatellite markers in two chromosomes (Ch 7 and Ch 15) it was shown that etoposide significantly affected crossing-over, but did not do so in a uniform fashion. Treatment generally changed the pattern for each chromosome, leading to local decreases in recombination, a distal shift in locations of crossing-over, and an overall decrease in double crossovers; at least some of these results might be interpreted as evidence for increased interference. Two methods were used to explore etoposide effects on chromosome segregation: a genetic experiment capable of detecting sex-chromosome nondisjunction in living progeny; and the use of FISH (fluorescence in situ hybridization) technology to score numbers of Chromosomes X, Y, and 8 in spermatozoa. Taken together these two approaches indicated that etoposide exposure of pachytene spermatocytes induces malsegregation, and that the findings of the genetic experiment probably yielded a marked underestimate of nondisjunction. As indicated by certain segregants, at least part of the etoposide effect could be due to disrupted pairing of achiasmatic homologs, followed by precocious sister-centromere separation. It has been shown for several organisms that absent or reduced levels of recombination, as well as suboptimally positioned recombination events, may be associated with abnormal segregation. Etoposide is the only chemical tested to date for which living progeny indicates an effect on both male meiotic crossing-over and chromosome segregation. Whether, however, etoposide-induced changes in recombination patterns are direct causes of the observed malsegregation requires additional investigation.
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PMID:Etoposide exposure during male mouse pachytene has complex effects on crossing-over and causes nondisjunction. 1557 40

We previously demonstrated that mammalian spermatozoa contain a nuclease activity that cleaves DNA into loop-sized fragments. We show here that this activity is mediated by a nuclear matrix-associated topoisomerase IIB (TOP2B) interacting with an extracellular Mn2+/Ca2+-dependent nuclease. Together, these enzymes cleave all of the DNA into fragments of 50 kb, and this cleavage can be reversed by EDTA. If dithiothreitol is included, the nuclease digests the DNA, and if the protamines are removed the DNA is completely digested. A similar, TOP2B-mediated, chromatin fragmentation, which is reversible, followed by digestion of the DNA by an intracellular nuclease occurs in somatic cells during apoptosis. The extracellular location of the sperm nuclease made it possible to reconstitute the fragmentation activity in isolated spermatozoa, thus allowing us to identify two novel aspects of the mechanism. First, the fragmentation of all of the DNA to 50 kb by TOP2B required the addition of the extracellular nuclease or factor. Second, the subsequent, complete digestion of the DNA by the nuclease could be inhibited by etoposide, suggesting that the nuclease digestion requires TOP2B religation of the cleaved DNA. These data are the first demonstration of an active TOP2B in spermatozoa, suggesting this inert chromatin may be more active than previously thought. They also show that the unique chromatin structure of spermatozoa may provide an important model to study the regulated degradation of chromatin by TOP2B and associated nucleases.
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PMID:Topoisomerase IIB and an extracellular nuclease interact to digest sperm DNA in an apoptotic-like manner. 1691 90

We have demonstrated that mouse spermatozoa can cleave their DNA into 50-kb fragments when treated with Triton X-100, MnCl(2), and CaCl(2). This cleavage, which is termed sperm chromatin fragmentation (SCF), is mediated by topoisomerase IIB (TOP2B) following stimulation by a factor in the epididymal fluid, most likely a nuclease, and can be at least partially religated by EDTA. When the protamines are removed, this DNA breakage is followed by digestion of the DNA by a nuclease(s). We tested whether the oocyte could repair TOP2B-induced sperm DNA breaks and whether partial religation by EDTA would allow spermatozoa to fertilize the oocytes normally. Oocytes injected with untreated spermatozoa developed normally. However, oocytes injected with spermatozoa treated with MnCl(2) and CaCl(2) to induce SCF, with or without subsequent EDTA treatment, failed to develop. In both of these treatment groups, the maternal pronuclei developed normally and replicated their DNA. However the paternal pronuclei did not replicate their DNA and this DNA began to disappear 6 h postinjection, which corresponded approximately to the time at which maternal DNA replication was initiated. These data suggest that when TOP2B is induced to cleave sperm DNA before fertilization, the paternal DNA is subsequently degraded by a highly regulated mechanism that does not affect the maternal chromatin. Furthermore, partial religation by EDTA of TOP2B-induced breaks prevents neither the inhibition of DNA synthesis nor DNA degradation.
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PMID:Topoisomerase II-mediated breaks in spermatozoa cause the specific degradation of paternal DNA in fertilized oocytes. 1718 90

We recently demonstrated that mouse spermatozoa contain a mechanism to degrade their DNA into loop-sized fragments of about 50 kb, mediated by topoisomerase IIB, termed sperm chromatin fragmentation (SCF). SCF is often followed by a more complete digestion of the DNA with a sperm nuclease. When SCF-induced spermatozoa are injected into oocytes, the paternal pronuclei degrade their DNA after the initiation of DNA synthesis, but the maternal pronuclei are unaffected and replicate normally. Here, we tested whether the nuclease activity changes in spermatozoa of different maturation stages, and whether there is a functional relationship between the initiation of DNA synthesis and paternal DNA degradation induced by SCF in the zygote. We found that spermatozoa from the vas deferens have a much higher level of SCF activity than those from the cauda epididymis, suggesting that spermatozoa may acquire this activity in the vas deferens. Furthermore, paternal pronuclei formed in zygotes from injecting oocytes with SCF-induced vas deferens spermatozoa degraded their DNA, but this degradation could be inhibited by the DNA synthesis inhibitor, aphidicolin. Upon release from a 4 h aphidicolin-induced arrest, DNA synthesis was initiated in maternal pronuclei, while the paternal pronuclei degraded their DNA. Longer aphidicolin arrest resulted in the paternal pronuclei replicating their DNA, suggesting that delaying the initiation of DNA synthesis allowed the paternal pronuclei to overcome the SCF-induced DNA degradation pathway. These results suggest that the paternal DNA degradation, in oocytes fertilized with SCF-induced spermatozoa, is coupled to the initiation of DNA synthesis in newly fertilized zygotes.
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PMID:Paternal pronuclear DNA degradation is functionally linked to DNA replication in mouse oocytes. 1749 13

We have recently demonstrated that mammalian spermatozoa have the ability to degrade their DNA by a mechanism that is similar to apoptosis in somatic cells. When this mechanism is activated, the DNA is first degraded into loop-sized fragments by TOP2B (topoisomerase IIB). This degradation, termed sperm chromatin fragmentation, can be reversed by EDTA, which causes TOP2B to religate the double-stranded breaks it originally produced. Under certain conditions, a nuclease then degrades the sperm DNA further, digesting the entire sperm genome. When mouse spermatozoa which have been treated to induce TOP2B-mediated DNA breaks are injected into oocytes, the paternal DNA is specifically and completely degraded. This total digestion of paternal DNA occurs at the time of DNA synthesis initiation. In the present study, we explore the significance of an active TOP2B in the nucleus for mouse sperm function.
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PMID:Sperm DNA fragmentation: awakening the sleeping genome. 1751 66

We demonstrated that mouse spermatozoa cleave their DNA into approximately 50 kb loop-sized fragments with topoisomerase IIB when treated with MnCl(2) and CaCl(2) in a process we term sperm chromatin fragmentation (SCF). SCF can be reversed by EDTA. A nuclease then further degrades the DNA in a process we term sperm DNA degradation (SDD). MnCl(2) alone could elicit this activity, but CaCl(2) had no effect. Here, we demonstrate the existence of a nuclease in the vas deferens that can be activated by ethylene glycol tetraacetic acid (EGTA) to digest the sperm DNA by SDD. Spermatozoa were extracted with salt and dithiothreitol to remove protamines and then incubated with EGTA. Next, the EGTA was removed and divalent cations were added. We found that Mn(2+), Ca(2+), or Zn(2+) could each activate SDD in spermatozoa but Mg(2+) could not. When the reaction was slowed by incubation on ice, EGTA pretreatment followed by incubation in Ca(2+) elicited the reversible fragmentation of sperm DNA evident in SCF. When the reactions were then incubated at 37 degrees C they progressed to the more complete degradation of DNA by SDD. EDTA could also be used to activate the nuclease, but required a higher concentration than EGTA. This EGTA-activatable nuclease activity was found in each fraction of the vas deferens plasma: in the spermatozoa, in the surrounding fluid, and in the insoluble components in the fluid. These results suggest that this sperm nuclease is regulated by a mechanism that is sensitive to EGTA, possibly by removing inhibition of a calcium binding protein.
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PMID:Mouse spermatozoa contain a nuclease that is activated by pretreatment with EGTA and subsequent calcium incubation. 1787 59

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