Nucleus replacement in Mammalian oocytes

Our contribution discusses the potential use of cell therapies (nucleus replacement) in mammalian oocytes. It is assumed that these approaches may be used, for example, for the elimination of mutated maternally transmitted mitochondrial DNA (mtDNA) as well as for the reconstruction of normal oocytes from oocytes that are developmentally compromised. Moreover, it is speculated that the replacement of germinal vesicles by somatic cells may result in cells of the haploid genome: the production of germ cells from somatic cells. The preliminary results obtained in our laboratories are discussed in this article.     

Chloride conductance of the Amphiuma red cell membrane

Summary Like most other red cells, the giant erythrocytes ofAmphiuma means possess a system for rapid exchange of chloride across the membrane. Also, there are indications that the net transport of chloride in these cells is slow. The size ofAmphiuma erythrocytes allows direct measurements of membrane potential with microelectrodes. The present work exploits the possibility that such measurements can be used to give a quantitative estimate of the chloride conductance (G _Cl) of the Amphiuma red cell membrane. The membrane potential was measured as a function of extracellular chloride concentration (5–120mM), using an impermeant anion (Para-amino-hippurate) as a substitute. Furthermore, the effect of different pH values (6.0–7.2) was studied. For each extracellular chloride concentration the membrane potential was determined at a pH at which hydroxyl, hydrogen, and bicarbonate ions were in electrochemical equilibrium. From these membrane potentials and the corresponding chloride concentrations in the medium (at constant intracellular ion concentrations), theG _Cl of the membrane was calculated to be 3.9×10^–7 {ie27-1} cm^–2. This value is some six orders of magnitude smaller than that calculated from the rate of tracer exchange under equilibrium conditions. The experimental strategy used gives the value for a partial transference number which takes into account only ions which arenot in electrochemical equilibrium. Whereas this approach gives a value forG _Cl, it does not permit calculation of the overall membrane conductance. From the calculated value ofG _Cl it is possible to estimate that the maximal value of the combined conductances of hydroxyl (or proton) and bicarbonate ions is 0.6×10^–7 {ie27-2} cm^–2. The large discrepancy between the rate of exchange of chloride and its conductance is in agreement with measurements on human and sheep red cells employing the ionophore valinomycin to increase the potassium conductance of the membrane. The results in the present study were, however, obtained without valinomycin and an accompanying assumption of a constant field in the membrane. Therefore, the present measurements give independent support to the above mentioned conclusions.     

Water splitting in the cell membrane. Possible effects on membrane conductance and intracellular pressure

It is shown that hydrogen and hydroxyl ions, produced in protonation and deprotonation reactions between ionisable groups in a cell membrane and water, will leave the reaction sites in opposite direction, rather than recombine with them when the electric field strength is equal to the mean value present in squid nerve at the resting potential. It is calculated that this effect could influence the conductance and swelling of intramembrane and sub-axolemmal protein during an inward current pulse, if the hydrogen ions combine with the acidic groups of the macromolecules.     

Autocatalytic membrane conductance and memory

A basic characteristic of biological memory is that it has a graded duration, which, even for socalled short-term memory, can vary from minutes to days (i.e. over about three orders of magnitude), depending on the training protocol, which one can think of as determining the “strength” of the memory. Furthermore, the molecular analysis of simple learning in invertebrates has revealed many examples where “learning” is produced by adecrease in an appropriate membrane conductance. This paper provides a quantitative analysis of a simple kinetic scheme where by a conductance decrease can be produced by repetitive nerve impulses, with a duration that varies with stimulus frequency. The simplest model considered is based on the actual kinetics of the naturally-occurring ionophore Monazomycin. This model yields durations ranging only over a factor of about 10, for reasonable parameter values. However, a simple modification of the model yields memory durations ranging over three or more orders of magnitude. We also show that Monazomycin-like kinetics can appear as the result of a combination of simple uni- and bi-molecular reactions, thus making more plausible the possibility that the effects described here may operate in actual biological systems.     

Geometric characterization of cell membrane of mouse oocytes for ICSI

Intracytoplasmic sperm injection (ICSI) is a broadly utilized assisted reproductive technology. A number of technologies for this procedure have evolved lately, such as the most commonly utilized piezo-assisted ICSI technique (P-ICSI). An important problem with this technique, however, is that it requires a small amount of mercury to stabilize the tip of the penetration micropipette. A completely different and mercury-free injection technology, called the rotationally oscillating drill (Ros-Drill) (RD-ICSI), was recently developed. It uses microprocessor-controlled rotational oscillations of a spiked micropipette after the pipette deforms the membrane to a certain tension level. Inappropriate selection of this initiation instant typically results in cell damage, which ultimately leads to unsuccessful ICSI. During earlier manual clinical tests of Ros-Drill, the technicians' expertise determined this instant in an ad hoc fashion. In this paper, we introduce a computer-vision-based tool to mechanize this process with the objective of maintaining the repeatability and introducing potential automation. Computer images are used for monitoring the membrane deformations and curvature variations as the basis for decision making. The main contribution of this paper is in the specifics of the computer logic to perform the monitoring. These new tools are expected to provide a practicable means for automating the Ros-Drill-assisted ICSI operation.     

Monovalent cation conductance in Xenopus laevis oocytes expressing hCAT-3

hCAT-3 (human cationic amino acid transporter type three) was investigated with both the two-electrode voltage clamp method and tracer experiments. Oocytes expressing hCAT-3 displayed less negative membrane potentials and larger voltage-dependent currents than native or water-injected oocytes did. Ion substitution experiments in hCAT-3-expressing oocytes revealed a large conductance for Na+ and K+. In the presence of L-Arg, voltage-dependent inward and outward currents were observed. At symmetrical (inside/outside) concentrations of L-Arg, the conductance of the transporter increased monoexponentially with the L-Arg concentrations; the calculated Vmax and KM values amounted to 8.3 microS and 0.36 mM, respectively. The time constants of influx and efflux of [3H]L-Arg, at symmetrically inside/outside L-Arg concentrations (1 mM), amounted to 79 and 77 min, respectively. The flux data and electrophysiological experiments suggest that the transport of L-Arg through hCAT-3 is symmetric, when the steady state of L-Arg flux has been reached. It is concluded that hCAT-3 is a passive transport system that conducts monovalent cations including L-Arg. The particular role of hCAT-3 in the diverse tissues remains to be elucidated.     

MOESIN crosslinks actin and cell membrane in Drosophila oocytes and is required for OSKAR anchoring

In Drosophila, development of the embryonic germ cells depends on posterior transport and site-specific translation of oskar (osk) mRNA and on interdependent anchoring of the osk mRNA and protein within the posterior subcortical region of the oocyte. Transport of the osk mRNA is mediated by microtubules, while anchoring of the osk gene products at the posterior pole of the oocyte is suggested to be microfilament dependent. To date, only a single actin binding protein (TropomyosinII) has been identified with a putative role in osk mRNA and protein anchoring. This communication demonstrates that mutations in the Drosophila moesin (Dmoe) gene that encodes another actin binding protein result in delocalization of osk mRNA and protein from the posterior subcortical region and, as a consequence, in failure of embryonic germ cell development. In Dmoe mutant oocytes, the subcortical actin network is detached from the cell membrane, while the polarized microtubule cytoskeleton is unaffected. In line with the earlier observations, colocalization of ectopic actin and OSK protein in Dmoe mutants suggests that the actin cytoskeleton anchors OSK protein to the subcortical cytoplasmic area of the Drosophila oocyte.     

On the mechanism of conductance control of the arthropod visual cell membrane

It is assumed that dark channels determine a permanent dark conductance of the arthropod visual cell membrane. The light stimulus causes a transient opening of light channels. The ion selectivity of dark channels and light channels is roughly described. Factors influencing the activation of light channels, as membrane energy metabolism, membrane potential and adjusted calcium ion concentration are specified. The mechanism of the action of calcium ions on the conductance of the visual cell membrane is discussed.These considerations are mainly concerned with photoreceptor cells of Limulus, Astacus and Balanus Presented at the EMBO-Workshop on Transduction Mechanism of Photoreceptors, Jülich, Germany, October 4–8, 1976     

ATP crossing the cell plasma membrane generates an ionic current in xenopus oocytes

The presence of ATP within cells is well established. However, ATP also operates as an intercellular signal via specific purinoceptors. Furthermore, nonsecretory cells can release ATP under certain experimental conditions. To measure ATP release and membrane currents from a single cell simultaneously, we used Xenopus oocytes. We simultaneously recorded membrane currents and luminescence. Here, we show that ATP release can be triggered in Xenopus oocytes by hyperpolarizing pulses. ATP release (3.2 +/- 0.3 pmol/oocyte) generated a slow inward current (2.3 +/- 0.1 microA). During hyperpolarizing pulses, the permeability for ATP(4-) was more than 4000 times higher than that for Cl(-). The sensitivity to GdCl(3) (0. 2 mm) of hyperpolarization-induced ionic current, ATP release and E-ATPase activity suggests their dependence on stretch-activated ion channels. The pharmacological profile of the current inhibition coincides with the inhibition of ecto-ATPase activity. This enzyme is highly conserved among species, and in humans, it has been cloned and characterized as CD39. The translation, in Xenopus oocytes, of human CD39 mRNA encoding enhances the ATP-supported current, indicating that CD39 is directly or indirectly responsible for the electrodiffusion of ATP.     

Involvement of calcium-dependent potassium conductance in membrane hyperpolarization processes at the pyramidal cell membrane in the cat sensorimotor cortex

In acute experiments on cats immobilized with myorelaxants intracellular injection of Cs ions reduced IPSP amplitude and postburst hyperpolarization of pyramidal cells in the sensorimotor cortex. Intracellular injection of ethylene glycol tetra-acetic acid produced a similar effect. The latter substance barely altered the lead front of neuronal after-hyperpolarization arising after a single action potential, while the lag front was inhibited. In conclusion, calcium-dependent potassium conductance may play an important part in the genesis of IPSP and of post-burst and after-hyperpolarization at the membrane of pyramidal cells of the cat sensorimotor cortex.I. S. Beritashvili Institute of Physiology, Academy of Sciences of the Georgian SSR, Tbilisi. Translated from Neirofiziologiya, Vol. 20, No. 3, pp. 383–389, May–June, 1988.     

Actin-plasma membrane associations in mouse eggs and oocytes

Using rhodamine-phalloidin stained preparations and extracted specimens labeled with heavy meromyosin or run on polyacrylamide gels, actin-plasma membrane associations in mouse mature eggs at the second metaphase of meiosis and oocytes at meiotic prophase have been examined. Cortices of extracted oocytes possessed numerous actin filaments that emanated from the plasma membrane delimiting regions between microvilli and from microvillar apices. The membrane anchorage sites of actin filaments were marked by an electron dense material on the inner leaflet of the plasma membrane. The free ends of filaments emanating from the plasma membrane of oocytes intermeshed to form a dense, cortical layer. With meiotic maturation, changes in the organization of cortical actin were first noted approximately 3 hr after the chromosomes had become localized at the oocyte's periphery. Fewer and shorter actin filaments, which did not form a well-defined layer as in oocytes, were connected with electron-dense material to the inner leaflet of the plasma membrane of extracted egg cortices in regions other than that associated with the meiotic spindle. Cortical actin adjacent to the meiotic spindle, however, was organized into a dense, cresentic aggregation in which clusters of filaments emanated from electron-dense regions associated with both the inner and outer leaflets of the plasma membrane. These observations indicate that mouse oocyte maturation not only involves changes in the distribution of cortical actin but also local alterations in the association of actin with the plasma membrane.     

Enzymatic suppression of the membrane conductance associated with the glutamine transporter SNAT3 expressed in Xenopus oocytes by carbonic anhydrase II

The transport activity of the glutamine/neutral amino acid transporter SNAT3 (former SN1, SLC38A3), expressed in oocytes of the frog Xenopus laevis is associated with a non-stoichiometrical membrane conductance selective for Na⁺ and/or H⁺ (Schneider, H.P., S. Bröer, A. Bröer, and J.W. Deitmer. 2007. J. Biol. Chem. 282:3788–3798). When we expressed SNAT3 in frog oocytes, the glutamine-induced membrane conductance was suppressed, when carbonic anhydrase isoform II (CAII) had been injected into the oocytes. Transport of substrate, however, was not affected by CAII. The reduction of the membrane conductance by CAII was dependent on the presence of CO₂/HCO₃ ⁻, and could be reversed by blocking the catalytic activity of CAII by ethoxyzolamide (10 μM). Coexpression of wild-type CAII or a N-terminal CAII mutant with SNAT3 also reduced the SNAT3- associated membrane conductance. The catalytically inactive CAII mutant V143Y coexpressed in oocytes did not affect SNAT3-associated membrane conductance. Our results reveal a new type of interaction between CAII and a transporter-associated cation conductance, and support the hypothesis that the transport of substrate and the non-stoichiometrical ion conductance are independent of each other. This study also emphasizes the importance of carbonic anhydrase activity and the presence of CO₂-bicarbonate buffers for membrane transport processes.     

Induction of membrane excitability in Xenopus oocytes

Immature oocytes from the African toad Xenopus laevis are not known to be excitable cells, which means that they do not generate an action potential in response to small depolarizations. However, a regenerative response is produced if successive depolarizing currents of large magnitude are applied to the oocyte membrane. This response is characterized by the occurrence of a positive transmembrane potential that can last for several minutes. The opening of voltage-dependent channels, highly selective for sodium ions, underlies the depolarization thus obtained. These channels exhibit unconventional electrophysiological and pharmacological properties, which set them apart from other types of voltage-dependent sodium channels found in excitable tissues. The opening of the oocyte sodium channels is a complex process, which includes an induction phase. During this phase, the channels change from an electrical state of inexcitability into an excitable voltage-dependent state. The induction mechanism is modulated by the temperature of the bathing medium, by the activation of enzymes (namely a phospholipase C and a protein kinase C) and by the release of calcium ions from intracellular phosphatidyl-inositol trisphosphate stores. The results summarized in this review point out the possible role that these sodium channels may play in the physiology of the oocyte.     

Bilirubin increases mitochondrial inner membrane conductance

Bilirubin accumulates within, and induces loose coupling in, rat liver mitochondria. This state, characterized by a normal protonmotive force, but increased oxygen consumption and inner membrane conductance, could impair cellular energy metabolism. Loose coupling is observed at bilirubin concentrations (12-24 microM) attained in tissues of kernicteric animals.     

K+-valinomycin and chloride conductance of the human red cell membrane. Influence of the membrane protonophore carbonylcyanide m-chlorophenylhydrazone

The major form of microsomal cytochrome P-450 induced by trans-stilbene oxide in the liver of male Sprague-Dawley rats was purified and characterized, and compared with the isolated cytochrome P-450 B2 forms from phenobarbital- and 3-methylcholanthrene-pretreated animals. The apparent subunit molecular weight of the trans-stilbene oxide-induced cytochrome was found to be 53 000 using sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and the absorbance maximum of the carbon monoxide complex of the ferrous cytochrome was 450 nm. Reconstitution of the N-demethylase activity towards three different substrates showed high and similar activities with the cytochrome P-450 B2 forms from trans-stilbene oxide or phenobarbital-treated rats, with one exception. Amino-acid analysis also showed a very high degree of similarity between these two forms. Upon proteinase treatment with three different proteinases the trans-stilbene oxide-induced cytochrome demonstrated in each case a peptide pattern identical to that obtained with the phenobarbital-induced B2 form. Furthermore, both forms are completely immunologically cross-reactive. We therefore conclude from these experiments that the liver microsomal P-450 B2 from trans-stilbene oxide and phenobarbital-treated rats are very closely related, if not identical.     

Monovalent cation conductance in Xenopus laevis oocytes expressing hCAT-3

hCAT-3 (human cationic amino acid transporter type three) was investigated with both the two-electrode voltage clamp method and tracer experiments. Oocytes expressing hCAT-3 displayed less negative membrane potentials and larger voltage-dependent currents than native or water-injected oocytes did. Ion substitution experiments in hCAT-3-expressing oocytes revealed a large conductance for Na⁺ and K⁺. In the presence of l-Arg, voltage-dependent inward and outward currents were observed. At symmetrical (inside/outside) concentrations of l-Arg, the conductance of the transporter increased monoexponentially with the l-Arg concentrations; the calculated V_max and K_M values amounted to 8.3 μS and 0.36 mM, respectively. The time constants of influx and efflux of [³H]l-Arg, at symmetrically inside/outside l-Arg concentrations (1 mM), amounted to 79 and 77 min, respectively. The flux data and electrophysiological experiments suggest that the transport of l-Arg through hCAT-3 is symmetric, when the steady state of l-Arg flux has been reached. It is concluded that hCAT-3 is a passive transport system that conducts monovalent cations including l-Arg. The particular role of hCAT-3 in the diverse tissues remains to be elucidated.