On the mechanism of stimulation of the Na/K pump of LK sheep erythrocytes by anti-L antibody

Studies were undertaken to explore the mechanism of stimulation of the Na/K pump in LK sheep erythrocytes by anti-L antibody. First, the numbers of functioning pump sites were determined by correlating [3H]ouabain binding with levels of inhibition of the pump. Untreated (control) cells had approximately 41 pumps per cell, and anti-L treatment caused an increase in the number of functioning pumps to approximately 85 per cell. Reducing the intracellular K concentration, [K]c, to near zero caused an increase in the number of pumps in control cells, but not in anti-L cells, such that the numbers of pumps per cell were about the same in the two cell types. These results led to the prediction that Kc is a noncompetitive inhibitor of the pump in control cells, and that anti-L stimulates the pump and increases number of functioning pumps by reducing noncompetitive inhibition by Kc. Kinetic studies were undertaken to test this prediction: activation of the pump by increasing [Na]c was measured at three fixed levels of [K]c. In control cells, the apparent maximum velocity of the pump (J'max) was reduced approximately threefold by raising [K]c from 0.2 to 9 mmol/liter cells, demonstrating noncompetitive inhibition by Kc. In anti-L cells, J'max did not vary with [K]c, which shows that, as predicted, anti-L abolishes the noncompetitive inhibition by Kc. The modification of the kinetic properties of the pumps by the antibody is highly specific in that affinities for Nac and Ko as substrates are unaffected. However, the effect of the antibody on noncompetitive inhibition by Kc does not explain the stimulation of the pump fully since there is significant stimulation at near-zero [K]c.     

Passive potassium transport in LK sheep red cells. Effects of anti-L antibody and intracellular potassium

The passive K influx in low K(LK) red blood cells of sheep saturates with increasing external K concentration, indicating that this mode of transport is mediated by membrane-associated sites. The passive K influx, iMLK, is inhibited by external Na. Isoimmune anti-L serum, known to stimulate active K transport in LK sheep red cells, inhibits iMLK about twofold. iMLK is affected by changes in intracellular K concentration, [K]i, in a complex fashion: increasing [K]i from near zero stimulates iMLK, while further increases in [K]i, above 3 mmol/liter cells, inhibit iMLK. The passive K influx is not mediated by K-K exchange diffusion. The effects of anti-L antibody and [K]i on passive cation transport are specific for K: neither factor affects passive Na transport. The common characteristics of passive and active K influx suggest that iMLK is mediated by inactive Na-K pump sites, and that the inability to translocate Na characterizes the inactive pumps. Anti-L antibody stimulates the K pump in reticulocytes of LK sheep. However, anti-L has no effect on iMLK in these cells, apparently because reticulocytes do not have the inactive pump sites which, in mature LK cells, are a consequence of the process of maturation of circulating LK cells. The results also indicate that anti-L alters the maximum velocity of both active and passive K fluxes by converting pumps sites from a form mediating passive K influx to an actively transporting form.     

The effect of anti-L on ouabain binding to sheep erythrocytes.

Binding of 3H-ouabain was studied in high potassium (HK) and low potassium (LK) sheep red cells. In particular, we investigated the effect of anti-L, an antibody raised in HK sheep against L-positive LK sheep red cells, on 3H-oubain binding and its relation to K+ -pump flux inhibition in LK cells. HK cells were found to have about twice as many 3H-ouabain binding sites and a higher association rate for 3H-ouabain than homozygous LL-type LK cells. The number of 3H-ouabain molecules bound to heterozygous LM-type LK cells is lower than that on LL cells, but the rate of ouabain binding is between that of HK and LL red cells. A close correlation was observed between the rates of 3H-oubain binding and fraction K+-pump inhibition. Exposure of LM and LL cells to anti-L did not affect the number of 3H-ouabain molecules bound at saturation, but increased the rates of glycoside binding and K+ -pump inhibition proportionately, so that for LK cells in the presence of anti-L, the rates of the two processes approximate those of HK cells. These data exclude the possibility that anti-L generates entirely new pump sites in LK sheep cells, but suggest that the antibody increases the affinity of the existing -a+ -K+ pumps for the glycoside.     

The effect of sheep anti-L and certain cattle S-system reagents on active potassium transport in sheep and cattle red blood cells

Certain anti-sheep L antisera stimulated active potassium transport in cattle red cells. All cattle red cells tested (red cells from 21 Jersey cows) which had an internal K level of less than 70 mmol/1 were stimulated but those with more than 75 mmol/1 of K (red cells from 7 Jersey cows) were not stimulated. Cattle S-system reagents and isoimmune cattle sera produced by injecting red cells of low-potassium type into cows with cells of high-potassium type failed to stimulate active potassium transport in either cattle or sheep red cells.     

Effect of sheep and human follicular fluid on the maturation of sheep oocytes in vitro

This study examines the effect of sheep and human follicular fluid on the in vitro maturation (IVM) of sheep follicular oocytes. Oocyte cumulus complexes recovered post mortem were matured for 24 to 26 h at 38.6 degrees C, 5% CO(2) in air, in TCM-199 bicarbonate medium supplemented with 20% fetal calf serum (FCS) and, where stated, with maturation hormones, including FSH (5.0 ug/ml), LH (5.0 ug/ml) and estradiol (1 ug/ml), or with sheep follicular fluid recovered from large (>5mm) or small (2 to 5mm) ovarian follicles post mortem, or with human periovular follicular fluid obtained during routine IVF procedures. The matured oocytes were then denuded, and their maturation stage and developmental capacity were assessed by in vitro fertilization (IVF) and culture (IVC). It was found that inclusion of sheep or human follicular fluid or hormone supplements in the IVM media more than doubled the number of oocytes completing maturation (FCS alone 33%, compared with 76.2% for maturation hormones, 84.2% for fluid from large and 69.6% for fluid from small sheep follicles and 82.6% for human follicular fluid), and significantly increased fertilization rates (FCS alone 51.6%, compared with 71.9% for maturation hormones, 78.4% for fluid from the large and 75.7% for fluid from small sheep follicles and 73.1% for human follicular fluid) without discernible adverse effects on the development of the cleaving embryos to the morula or blastocyst stage in culture. Omission of FCS and supplements from the IVM medium resulted in a marked reduction (56%) in the number of oocytes maturing. This reduction could be offset to a large part, but not completely, by inclusion of human follicular fluid or human follicular fluid plus LH (5 ug/ml) in the medium. The results of this study show that addition of sheep or human follicular fluid to maturation medium can enhance rather than inhibit the maturation and fertilizability of sheep follicular oocytes in vitro.     

Ouabain-insensitive sodium/lithium exchange and the effect of anti-L in low potassium sheep erythrocytes

The activity of the ouabain-insensitive Na⁺/Na⁺ exchange system was assessed by measurements of Li⁺ net-uptake in LK and HK sheep erythrocytes in the absence and presence of the L-antibody and various inhibitors. N-ethylmaleimide, p-chloromercuribenzoic sulfonate and phloretin inhibited the exchange by about 50%. Anti-L, while stimulating the K⁺ pump flux in LK cells, did not alter Na⁺/Li⁺ countertransport. The activity of the exchange system with fully saturated internal and external loading sites was estimated to be identical in LK and HK sheep red cells. Hence the Na⁺/Na⁺ exchange system seems to be molecularly unrelated to the ouabain-sensitive Na⁺K⁺ pump in these cells and not under genetic control of the HK/LK and M/L genes.     

The presence of cumulus cells on nuclear maturation of sheep oocytes during in vitro maturation

This study was carried out to investigate the role of maturation by cumulus cells and the initial bond between the cumulus cells and the oocyte on nuclear maturation of sheep oocytes. Ovaries collected from the local abattoir were transported to the laboratory in saline at 30–35 °C within 1–3 h after collection. The oocytes of follicles, 2–6 mm in diameter, were recovered by aspiration and collected in a pre-incubated (at 38.6 °C, 5% CO₂, and 100% humidity) Hepes-modified TCM 199 medium. After preliminary evaluation, the oocytes with evenly granulated cytoplasm and which were surrounded with at least two layers of cumulus cells (good quality oocytes) were selected and subjected to culture in pre-incubated bicarbonate-buffered TCM 199 supplemented with 0.05 IU/ml recombinant human follicle stimulating hormone (rhFSH), 1 IU/ml human chorionic gonadotropin (hCG), and 1 μg/ml estradiol (OCM: oocyte culture medium). Before culturing, the selected oocytes were randomly divided into four treatment groups: Group 1, cumulus enclosed oocytes cultured in OCM; Group 2, denuded oocytes cultured in OCM; Group 3, denuded oocytes co-cultured with a cumulus cell monolayer in OCM; Group 4, denuded oocytes cultured in OCM in the presence of cumulus cells-conditioned medium. After an incubation period (26–27 h), the nuclear status of the oocytes in each treatment group was assessed using a 2% orcein stain. The rate of oocytes reaching the metaphase II (MII) stage (metaphase of second stage of meiosis division) was 82%, 5%, 11%, and 47% for Groups 1, 2, 3, and 4, respectively. The differences between groups were significantly (P < 0.05) different. The percentage of MII oocytes in Group 4 (47%) was higher than that obtained in Group 3 (11%), indicating a higher efficiency in a cumulus cell-conditioned medium, compared to the cumulus cells monolayer in providing the proper condition for sheep oocyte nuclear maturation. The results suggest the ability of sheep oocytes to resume meiosis in the absence of gap junctional communication (GJC) between the cumulus cells and oocyte being drastically interrupted while for optimum oocyte nuclear maturation, the intact physical contact between the oocyte and cumulus cells is essential.     

Effect of ovarian cortex cells on nuclear maturation of sheep oocytes during in vitro maturation

The objective of this study was to investigate the influence of ovarian cortex cells (OCCs) monolayers on the nuclear maturation of sheep oocytes with or without cumulus cells during IVM. Sheep ovaries collected from a local abattoir were transported to the laboratory in warm PBS containing antibiotics within 2-3h after collection. Cumulus-oocyte complexes (COCs) were obtained by aspiration and evaluated in a pre-incubated Hepes-modified TCM 199 medium. The selected COCs were randomly divided into six treatment groups: group 1 (control group): oocytes enclosed by cumulus cells were cultured in maturation medium; group 2 (co-culture group): oocytes enclosed by cumulus cells co-cultured with OCCs monolayers; group 3 (conditioned group): oocytes enclosed by cumulus cells were cultured in OCCs-conditioned medium; group 4 (denuded group): denuded oocytes were cultured in the maturation medium; group 5 (denuded co-culture group): denuded oocytes co-cultured with OCCs monolayers in maturation medium; group 6 (denuded conditioned group): denuded oocytes were cultured in OCCs-conditioned medium. After maturation for 24h, the oocytes in each treatment group were fixed, stained and the nuclear status of the oocytes were assessed under an inverted microscope. The highest percentage of metaphase II (M-II) stage oocyte was observed in group 2 (86.3%) and the lower percentage was observed in the denuded groups (group 4-6). The removal of cumulus cells dramatically decreased the percentage of M-II stage oocyte. The comparison of the nuclear maturation status in group 4-6 showed that the co-culture of oocyte with OCCs monolayers resulted in progression to completing the GVBD stage to reach the M-II stage. The results demonstrated that the presence of OCCs could positively influence the meiotic resumption and progression of sheep oocytes during IVM.     

The effect of shoot-root ratio and temperature on K+ influx in rye

The temperature sensitivity of K⁺ influx into rye roots and root plasma membrane ATPase activity were compared in plants grown at different temperatures. It was shown that ATPase activity obeyed the Arrhenius relationship with temperature, whereas K⁺ influx into intact plants was linearly related to temperature and markedly influenced by shoot/root ratio. A model for acclimation of K⁺ influx to low temperatures based on the regulation of the K⁺ carrier mechanism by plant demand for K⁺ is described.     

The M-antigen in HK and LK sheep red cell membranes

Summary Red cells of all high-potassium-type (HK) sheep and of more than one half of all low-potassium-type (LK) sheep contained the M-antigen and were hemolyzed by iso-immune anti-M antiserum in presence of a guinea pig serum complement. It was characteristic for the hemolysis of HK red cells by the M-antiserum the all HK cells were ultimately hemolyzed at suboptimal antibody concentrations, provided the time of incubation at 37 °C was sufficiently long. Thus, the M-antigen appears to be expressed on all red cells of an individual HK sheep. The M-antibody was absorbed by HK red cells and their membranes with a high affinity, whereas M-negative LK red cells and their membranes did not bind the antibody. The ratio of the number of antibody units absorbed per cell or membrane to the number of antibody units required for lysis approached unity. The amount of antibody absorbed per membrane was unaffected by ouabain in the presence of ATP, Mg⁺⁺, Na⁺, and K⁺. The M-antigen activity depends on the integrity of the red cell membrane and was not detectable after lyophilization of HK membranes or in the membrane protein solubilized by n-butanol. The major M-antibody activity was found among the high molecular weight plasma proteins and may be attributed to the ₂ M globulins. Heterogeneity within the antibody fraction cannot be excluded since some hemolytic activity was detected in a chromatographic fraction containing predominantly -globulin. The relationship between the M-antigen and the Na⁺–K⁺ transport system in sheep red cell membranes is discussed.This work was presented in part at the 53rd annual meeting of the Federation of American Societies for Experimental Biology, Atlantic City, N. J. 1969.     

Cytodifferentiation and membrane transport properties in LK sheep red cells

Young cells produced in LK sheep during rapid hematopoiesis after massive hemorrhage contain more K than the cells which are normally released into the circulation. The K content in these new cells falls to that characteristic of mature LK cells after a few days in the circulation. K transport properties in young and old cells before and after massive bleeding were studied. Young and old cells were separated by means of a density gradient centrifugation technique. Evidence showing that younger cells are found in the lower density fractions is presented. Active transport of K in the lightest fraction as measured by strophanthidin-sensitive influx was four to five times greater in red cells drawn 6 days after massive bleeding while the K leak as measured by strophanthidin-insensitive influx was only slightly larger. No change after bleeding was observed in older cells which had been present in the circulation prior to the hemorrhage. It is concluded that the high K content of young cells produced in LK sheep after bleeding is due to temporary retention of membrane K transport properties characteristic of HK cells. Thus, genetically determined modification of membrane transport properties has been shown to occur in nondividing circulating red cells.     

Holding bovine oocytes in the absence of maturation inhibitors: kinetics of in vitro maturation and effect on blastocyst development after in vitro fertilization

Holding immature oocytes before maturation simplifies the transport of oocytes and aids in scheduling later manipulations. We examined the effect of holding bovine oocytes in the absence of meiotic inhibitors on their subsequent meiotic and developmental competence. Oocytes were matured immediately after recovery (control) or were held in a mixture of 40% TCM 199 with Earle's salts, 40% TCM 199 with Hanks' salts, and 20% FBS, at room temperature for 16 to 18h (EH-held) and then matured. Chromatin status was determined at 0, 10, 14, 18, and 22h of maturation culture. Oocytes were fertilized in vitro after either 18 or 22-24h maturation. The EH treatment maintained oocytes at the germinal vesicle stage (79.3%, vs. 87.7% for control oocytes at 0h; P>0.05). Upon culture, held oocytes matured more quickly than did control oocytes. The proportions of mature oocytes were not significantly different between groups at 18h (EH-held, 80.6% and control, 79.3%); however, after 22h significantly more EH-held than control oocytes had degenerated (24.1% vs. 4.5%, P<0.0001). Blastocyst development was similar between groups for oocytes fertilized after 18h maturation (EH-held, 29.6% and control, 27.8%). When oocytes were fertilized after 22-24h maturation, EH-held oocytes yielded lower blastocyst development than did control oocytes (16.5% vs. 29.3%, P<0.05). In conclusion, bovine oocytes may be effectively held in the EH treatment before maturation without adversely affecting meiotic or developmental competence. However, holding affects the kinetics of maturation and this must be taken into account when subsequent manipulations are performed.     

Pig reticulocytes. V. Development of Rb+ influx during in vitro maturation

Influx of the K⁺ analogue Rb⁺ was measured through the ouabain-sensitive Na⁺/K⁺ pump and the ouabain-insensitive “leak” pathways in Cl^? or NO in mature red cells from adult pigs and in reticulocytes naturally occurring in 7-day-old piglets. In reticulocytes, Rb⁺ influxes by the two pathways were of about equal magnitude in Cl^? (13 and 10 mmoles/liter cells × hr) and at least 25-fold larger than in mature red cells (0.5 and 0.4 mmoles/liter cells × hr). In Na ⁺ media, a portion of the ouabain-insensitive “leak” flux of Rb⁺ was Cl^? dependent (Rb⁺Cl^? transport) as NO replacement reduced Rb⁺ influx by 90% in reticulocytes and by 40% in mature red cells. The sulfhydryl reagent N-ethylmaleimide (NEM) stimulated Rb⁺Cl^? transport about twofold in reticulocytes and up to 13-fold in mature red cells. When reticulocytes matured to erythrocytes during in vitro incubation, about 90% of both ouabain-sensitive Rb⁺ pump and ouabain-insensitive Rb⁺Cl^? influx were lost. In contrast, the NEM-stimulated Rb⁺Cl^? transport changed much less throughout this period, suggesting an entity operationally but not necessarily structrually distinct from the basal Rb⁺Cl^? transport. Although the experimental variability precluded a full assessment of significant changes in the small Na⁺/K⁺(Rb⁺) pump and Rb⁺Cl^? fluxes in mature pig red cells kept for the same time period in vitro, Rb⁺ flux changes in reticulocytes appear to be maturational in nature, reflecting parallel activity transitions of Na⁺/K⁺ pump and Cl^?-dependent K⁺ fluxes in vivo.     

Swelling activation of K-Cl cotransport in LK sheep erythrocytes: a three-state process

K-Cl cotransport in LK sheep erythrocytes is activated by osmotic swelling and inhibited by shrinkage. The mechanism by which changes in cell volume are transduced into changes in transport was investigated by measuring time courses of changes in transport after osmotic challenges in cells with normal and reduced Mg concentrations. When cells of normal volume and normal Mg are swollen, there is a delay of 10 min or more before the final steady-state flux is achieved, as there is for swelling activation of K-Cl cotransport in erythrocytes of other species. The delay was shown to be independent of the extent of swelling. There was also a delay after shrinkage inactivation of cotransport. Reducing cellular Mg concentration activates cotransport. Swelling of low-Mg cells activates cotransport further, but with no measurable delay. In contrast, there is a delay in shrinkage inactivation of cotransport in low-Mg cells. The results are interpreted in terms of a three-state model: [formula see text] in which A state, B state, and C state transporters have relatively slow, intermediate, and fast transport rates, respectively. Most transporters in shrunken cells with normal Mg are in the A state. Swelling converts transporters to the B state in the rate-limiting process, followed by rapid conversion to the C state. Reducing cell Mg also promotes the A-- >B conversion. Swelling of low-Mg cells activates transport rapidly because of the initial predominance of B state transporters. The results support the following conclusions about the rate constants of the three-state model: k21 is the rate constant for a Mg-promoted process that is inhibited by swelling; k12 is not volume sensitive. Both k23 and k32 are increased by swelling and reduced by shrinkage; they are rate constants for a single process, whereas k12 and k21 are rate constants for separate processes. Finally, the A-->B conversion entails an increase in Jmax of the transporters, and the B-->C conversion entails an increase in the affinity of the transporters for K.     

Using RT-PCR and glutathione level to study the effect of follicular fluid on in vitro maturation and gene expression of sheep oocytes

The aim of this study is to evaluate the effect of sheep follicular fluid (SFF) supplementation of the in vitro maturation (IVM) media of sheep oocytes on the resumption of meiosis, glutathione (GSH) level, and expression of apoptosis (Bax, Bcl-2) as well as heat shock protein beta-1 (HSPB1) genes. Sheep ovaries were collected from the central slaughterhouse of Riyadh city, KSA. Oocytes were aspirated from 3 to 8 mm follicles. Sheep oocytes were cultured in maturation medium with different concentrations of sheep follicular fluid: 0% (control), 10%, 20% and 40% for 24 h. The results indicated that the maturation rate of oocytes was significantly (p ≤ .05) decreased in 40% SFF (36.87%) versus the control (61.3%), 10% SFF (63.95%) and 20% SFF (64.08%). The supplementation of the IVM medium with 10% SFF induced an intra-oocyte GSH concentration that was significantly higher than in sheep oocytes cultured with 20% and 40% SFF and similar to the GSH content in oocytes cultured without SFF. Real-time polymerase chain reaction analysis of gene expression revealed no significant differences in the Bax and HSPB1 genes between the control and 10% SFF, whereas they were significantly higher in 40% FF (p ≤ .05) compared to the control. The expression of Bax:Bcl-2 was significantly higher in 20% and 40% SFF compared to the control group. In conclusion, the addition of SFF to the IVM culture of sheep oocytes is recommended to support nuclear maturation and increase oocyte competence.     

Chromosome configuration during in vitro maturation of goat, sheep and buffalo oocytes

The competence of meiotic chromosome configuration at the time of co-culture of oocytes with spermatozoa is an essential prerequisite for successful in vitro fertilization (IVF). Although this technology has been used in several livestock species, various intrinsic and extrinsic factors affecting the high repeatablity of IVF have yet to be understood. The present study was conducted to determine the appropriate time for coculture of oocytes and spermatozoa in order to optimize the fertilization rate in sheep, goats and buffalo. Oocytes were collected from the ovaries of slaughtered animals. The oocytes were divided into 10 groups and cultured for maturation in TCM-199 supplemented with estrous cow serum for different durations at 38.5 x 0.5/C in a CO(2) incubator. Sheep and goat oocytes were removed from culture medium after 0,6,12,22,24,26,28,30,32 and 36 and buffalo oocytes after 0,6,12,16,20,22,24,26,28, and 36 h. The oocytes were treated with hypotonic solution (0.75 M KCl) and fixed in Carony's fixative on glass slides. The fixed oocytes were stained with Giemsa solution, and the meiotic chromosomes were evaluated under a compound microscope at x 1000 magnification. Observations were recorded on a total of 1328 oocytes (sheep, 409; goat, 727 and buffalo, 192). The sequential configurations of diffused chromatin, pachytene, diplotene (along with nucleoli), diakinesis and metaphase II (MII) were analyzed at different durations of culture. Control oocytes (fixed at 0 h without incubation) were mostly at the pachytene stage, and as the duration of culture increased the instances of diplotene, diakinesis and finally MII increased. Oocytes at the MII stage of meiosis are known to be at the optimal stage of development for co-culture with spermatozoa and successful in vitro fertilization. On the basis of sequential configuration of chromosomes, it was found that the optimal duration of in vitro maturation of oocytes is 32, 30 and 24 h for sheep, goats and buffalo, respectively.