Chris Ford

Drosophila Shaking-B protein forms gap junctions in paired Xenopus oocytes

In most multicellular organisms direct cell–cell communication is mediated by the intercellular channels of gap junctions. These channels allow the exchange of ions and molecules that are believed to be essential for cell signalling during development and in some differentiated tissues. Proteins called connexins, which are products of a multigene family, are the structural components of vertebrate gap junctions,. Surprisingly, molecular homologues of the connexins have not been described in any invertebrate. A separate gene family, which includes the Drosophila genes shaking-B and l(1)ogre, and the Caenorhabditis elegans genes unc-7 and eat-5, encodes transmembrane proteins with a predicted structure similar to that of the connexins. shaking-B and eat-5 are required for the formation of functional gap junctions,. To test directly whether Shaking-B is a channel protein, we expressed it in paired Xenopus oocytes. Here we show that Shaking-B localizes to the membrane, and that its presence induces the formation of functional intercellular channels. To our knowledge, this is the first structural component of an invertebrate gap junction to be characterized.

Appearance of DNA polymerase activities during early development of Xenopus laevis

Abstract Extracts of large oocytes of Xenopus laevis contain high levels of one major DNA polymerase activity. After maturation into eggs, the overall level of DNA polymerase activity in extracts increases fourfold and a second major activity appears on Sephadex G-200 or DEAE cellulose columns. Although intense DNA synthesis occurs as the number of cells increase from one to over 100,000, no further increases in the level of either DNA polymerase activity are observed in cleavage, gastrula or early neurula stage embryos. In extracts of late neurulae or hatched embryos, however, a third major DNA polymerase activity appears coincident with an increase in the ability of the extracts to utilise native DNA templates in vitro .

DNA synthesis in oocytes and eggs of Xenopus laevis injected with DNA

Abstract Single-stranded calf thymus DNA injected into preovulation oocytes, postovulation oocytes or eggs of Xenopus laevis induces synthesis of double-stranded DNA of similar base composition. In contrast, native (double-stranded) calf thymus DNA injected into oocytes does not stimulate DNA synthesis, though it does do so in eggs. The buoyant density of normal or IUdR-substituted newly-synthesized DNA on neutral or alkaline CsCl gradients suggests that the injected DNA is replicated. The amount of synthesis induced by injecting single-stranded DNA is five times greater in eggs than in oocytes. The maximum synthesis observed in eggs injected with native DNA is 50 pg/hr; this is sufficient for nuclear DNA replication in uninjected fertilised eggs, but not in midcleavage. However in vitro studies (reported elsewhere) indicate the presence of a large store of DNA polymerase activity in eggs. We conclude that only a small proportion of the total DNA polymerase activity in an egg is available for DNA synthesis during the first 2 hr of development.

Mobilisation of Ca2+ stores and flagellar regulation in human sperm by S-nitrosylation: a role for NO synthesised in the female reproductive tract.

Generation of NO by nitric oxide synthase (NOS) is implicated in gamete interaction and fertilisation. Exposure of human spermatozoa to NO donors caused mobilisation of stored Ca2+ by a mechanism that did not require activation of guanylate cyclase but was mimicked by S-nitroso-glutathione (GSNO; an S-nitrosylating agent). Application of dithiothreitol, to reduce protein -SNO groups, rapidly reversed the actions of NO and GSNO on [Ca2+]i. The effects of NO, GSNO and dithiothreitol on sperm protein S-nitrosylation, assessed using the biotin switch method, closely paralleled their actions on [Ca2+]i. Immunofluorescent staining revealed constitutive and inducible NOS in human oviduct and cumulus (the cellular layer investing the oocyte). 4,5-diaminofluorescein (DAF) staining demonstrated production of NO by these tissues. Incubation of human sperm with oviduct explants induced sperm protein S-nitrosylation resembling that induced by NO donors and GSNO. Progesterone (a product of cumulus cells) also mobilises stored Ca2+ in human sperm. Pre-treatment of sperm with NO greatly enhanced the effect of progesterone on [Ca2+]i, resulting in a prolonged increase in flagellar excursion. We conclude that NO regulates mobilisation of stored Ca2+ in human sperm by protein S-nitrosylation, that this action is synergistic with that of progesterone and that this synergism is potentially highly significant in gamete interactions leading to fertilisation.

DNA replication and cell cycle control in Xenopus egg extracts

Summary Aspects of the regulation of DNA replication and mitosis have been studied using a cell-free extract of Xenopus eggs. The extract is characterized by repeated cycles of DNA replication and mitosis, which are accompanied by periodic synthesis and degradation of cyclins as well as fluctuations in the level of Histone H1 kinase activity. DNA replication in this system is dependent upon the formation of a nucleus. However, while nuclear structures are clearly required for initiation, a complete nuclear membrane does not appear to be necessary. Indirect immunofluorescence and DIC microscopy indicate that nuclear reformation from chromosomes occurs asynchronously around individual chromatids. Lamin polymerization, biotin-11-dUTP incorporation and association of polymerases with chromatin occur before membrane formation is complete. S phase nuclei are typified by the co-distribution of both anti-DNA polymerase α and anti-PCNA antibodies as discrete spots of fluorescence which align the chromatin. However, as DNA replication is terminated, PCNA fluorescence fades and DNA polymerase α dissociates from the chromatin and is redistributed throughout the nucleoplasm. By inhibiting DNA replication with aphidicolin, both DNA polymerase α and PCNA remain associated with the chromatin throughout prolonged incubation. Under these conditions mitosis is delayed by up to 70 min, although both the general rate of protein synthesis and more importantly the rate of cyclin synthesis and histone kinase activation are unaffected. Upon nuclear envelope breakdown and lamin dispersal, cyclins degrade; however, no chromosomes are formed, and both PCNA and DNA polymerase α remain associated with the chromatin. Also, histone kinase activity is maintained at elevated levels.

Template preferences of DNA polymerase and nuclease activities appearing during early development of Xenopus laevis

Abstract The three DNA polymerase activities identified in early embryos of Xenopus laevis (Benbow et al., 1975) were further distinguished by their template preferences, pH optima and sensitivity to monovalent cations. In addition, endo and exonuclease activities at pH 7.5 were identified and monitored through early development. Endonuclease activity increased throughout early development while exonuclease activity remained nearly constant. These nuclease activities were not responsible for the different template preferences of the partially purified DNA polymerase activities.

NAD turnover during early development of Xenopus laevis

The NAD pools of Xenopus laevis oocytes and early embryos can be radioactively labelled by microinjection of [adenine-3H]NAD. This technique is used to study the metabolism of NAD in oocytes and during early development. The rate at which NAD is degraded in vivo has been monitored by determining the rate of transfer of adenine residues from the NAD pool into other nucleotides and polynucleotides. In oocytes, NAD turnover is extremely slow, with a half-life of about 400 h. NAD turnover increases dramatically after fertilisation, and the half-life of the compound decreases to 37 h in 5-h-old embryos and to 10 h in 40-h-old embryos. 2 mM 3-aminobenzamide, a specific inhibitor of poly(ADP-ribose) polymerase, reduces the NAD turnover rate by about 20%, whereas 5 mM isonicotinic acid hydrazide, a specific inhibitor of NAD glycohydrolase, produces no significant inhibition. This indicates that a significant fraction of the considerable NAD turnover observed involves poly(ADP-ribose) polymerase. Our results indicate that poly(ADP-ribose) polymerase is active during early development and suggest that this activity may be involved in one or more aspects of the nuclear metabolism of the embryo.

Communication between female tract and sperm: Saying NO* when you mean yes.

Signaling through [Ca2+]i is central to regulation of sperm activity and is likely to be the mechanism by which signal from the female tract regulate motility of sperm. In a recent paper1 we showed that exposure of sperm to nitric oxide mobilizes stored Ca2+ in human sperm, an effect that occurs through nitrosylation of protein thiols. Not only did we find that NO• production by cells of the human female tract would be sufficient to elicit this effect, but progesterone, which is also present in the female tract and is synthesized by the oocyte vestments, acted synergistically with NO• to mobilize Ca2+ and enhance flagellar beating. Here we argue that a Ca2+ store at the junction of the sperm head and flagellum is subject to regulation by both progesterone and NO• and that ryanodine receptors at the store may be the point at which coincidence detection and synergistic interaction occurs.

NAD-glycohydrolase activity in Xenopus laevis oocytes and early embryos

Abstract NAD-glycohydrolase was first detected in Xenopus laevis embryos 20 hours after fertilisation. This activity increased at least 50-fold by 70 hours after fertilisation. Enzyme activity per cell increased 5-fold between 20 and 50 hours. This increase represents a much larger variation in NAD-glycohydrolase activity than has been reported in any other tissue. The NAD-glycohydrolase activity of stage VI oocytes was at least 6-fold greater than that of eggs. Most, or all, of this activity was localised in the follicle cells which make up only a few per cent of the weight of the oocyte.

DNA Replication: Almost licensed

Exact duplication of all the DNA in a cell occurs during each S phase, and only once in each cell cycle. Recent results show that conserved proteins of the MCM family contribute to these precisely regulated events.