中国鲎和圆尾鲎血淋巴细胞分类和特征的比较研究

为了更好地了解中国鲎(Tachpleus tridentatus)和圆尾鲎(Carcinoscorpius rotundicauda)血淋巴细胞的种类组成和特征差异,综合运用光学显微镜、扫描电镜和粒度仪,较为系统地对两种鲎的血淋巴细胞进行了分类和特征研究,从而为两种鲎的血淋巴细胞和分子生物学研究提供基础资料。根据血淋巴细胞大小、核质比、细胞着色特点、细胞中颗粒存在与否、颗粒的密集程度等,中国鲎和圆尾鲎的血淋巴细胞均可分为大颗粒细胞、小颗粒细胞和透明细胞三种主要类型,且两种鲎的血淋巴细胞均以颗粒细胞为主,透明细胞在血淋巴细胞中所占比例最小,但具有高核质比。两种鲎的同类血淋巴细胞在染色和形态上无显著性差异,但在同一种鲎中,血淋巴细胞密度存在显著的雌雄差异。       

Effects of Ocean Acidification on Juvenile Red King Crab (Paralithodes camtschaticus) and Tanner Crab (Chionoecetes bairdi) Growth,Condition, Calcification,and Survival

Ocean acidification, a decrease in the pH in marine waters associated with rising atmospheric CO₂ levels, is a serious threat to marine ecosystems. In this paper, we determine the effects of long-term exposure to near-future levels of ocean acidification on the growth, condition, calcification, and survival of juvenile red king crabs, Paralithodes camtschaticus, and Tanner crabs, Chionoecetes bairdi. Juveniles were reared in individual containers for nearly 200 days in flowing control (pH 8.0), pH 7.8, and pH 7.5 seawater at ambient temperatures (range 4.4–11.9 °C). In both species, survival decreased with pH, with 100% mortality of red king crabs occurring after 95 days in pH 7.5 water. Though the morphology of neither species was affected by acidification, both species grew slower in acidified water. At the end of the experiment, calcium concentration was measured in each crab and the dry mass and condition index of each crab were determined. Ocean acidification did not affect the calcium content of red king crab but did decrease the condition index, while it had the opposite effect on Tanner crabs, decreasing calcium content but leaving the condition index unchanged. This suggests that red king crab may be able to maintain calcification rates, but at a high energetic cost. The decrease in survival and growth of each species is likely to have a serious negative effect on their populations in the absence of evolutionary adaptation or acclimatization over the coming decades.     

Measurement of an intracellular pH rise after fertilization in crab eggs using 31P-NMR

The effect of fertilization upon the intracellular pH, pH_i, in crab ovulated eggs was examined by ³¹P-NMR. The pH_i values were obtained from the chemical shift differences between the phosphoarginine PA resonance and the inorganic phosphate P_i resonance. The detection of the P_i peak was accomplished by Hahn spin-echo experiments in order to cancel the broad signal arising from phosphoproteins which overlaps the P_i signal. The average pH_i of the unfertilized unactivated eggs was 6.55 and a rise of 0.12 pH unit occurred after fertilization.     

Altered proton extrusion in cells adapted to growth at low extracellular pH

Intracellular pH (pH_i) homeostasis is crucial to cell survival. Cells that are chronically exposed to a low pH environment must adapt their hydrogen ion extrusion mechanisms to maintain their pH_i in the physiologic range. An important component of the adaptation to growth at low pH is the upregulation of pH_i relative to the extracellular pH (pH_e). To test the ability of low pH_e adapted cells to respond to a pH_i lowering challenge, a fluorescence assay was used that directly monitors proton removal as the rate of change of pH_i during recovery from cytosolic acidification. Two cell lines of Chinese hamster origin (ovarian carcinoma and ovary fibroblastoid cells) were compared, both of which showed altered proton extrusion after adaptation to growth at low pH_e = 6.70. In the ovarian carcinoma (OvCa) cell line, the pattern was consistent with an upregulation by means of an increase in the number of functional proton transporters in the plasma membrane. In the ovary fibroblastoid (CHO-10B) cell line, pH_i was consistently elevated in adapted cells as compared with cells grown at normal pH_e = 7.30 without an increase in maximum extrusion rate. This upregulation was consistent with a shift in the activating pH_i of proton transporters without an increase in the number of transporters, i.e., a change in substrate affinity of the transporter. In OvCa cells, recovery from acidification could be blocked by amiloride, an inhibitor of Na⁺/H⁺ exchange. In contrast, a more modest effect of amiloride on CHO cells was observed but a complete inhibition was seen with the Cl⁻/HCO⁻₃ exchange inhibitor 4,4′-diisothiocyanatostilbene-2,2′-disulfonic acid (DIDS). These data indicate that the two cell lines rely to different degrees on the two major pathways for pH regulation during recovery from cytosolic acidification. J. Cell. Physiol. 173:397–405, 1997. © 1997 Wiley-Liss, Inc.     

Production and characterization of monoclonal antibodies to the hemocytes of mud crab, Scylla serrata

Monoclonal antibodies (MAbs) to hemocytes of mud crab, Scylla serrata, were produced by immunizing mice with formalin-fixed hemocytes. Of the six MAbs produced, two (MAb 1D11 and MAb 1A2) reacted specifically with hemocyte proteins in western blot. MAb 1A2 showed strong immunofluorescent reaction with granular hemocytes and a weak reaction with semigranular cells. However, hyaline cells did not show any reaction. The MAbs also showed strong cross-reactivity with the hemocytes of different crab species but not with other crustaceans. The MAbs produced can be used as a marker for granular hemocytes of crabs.     

Intracellular and Extracellular pH and Ca Are Bound to Control Mitosis in the Early Sea Urchin Embryo via ERK and MPF Activities

Studies aiming to predict the impact on marine life of ocean acidification and of altered salinity have shown altered development in various species including sea urchins. We have analyzed how external Na, Ca, pH and bicarbonate control the first mitotic divisions of sea urchin embryos. Intracellular free Ca (Ca_i) and pH (pH_i) and the activities of the MAP kinase ERK and of MPF regulate mitosis in various types of cells including oocytes and early embryos. We found that intracellular acidification of fertilized eggs by Na-acetate induces a huge activation of ERK at time of mitosis. This also stops the cell cycle and leads to cell death, which can be bypassed by treatment with the MEK inhibitor U0126. Similar intracellular acidification induced in external medium containing low sodium or 5-(N-Methyl-N-isobutyl) amiloride, an inhibitor of the Na⁺/H⁺ exchanger, also stops the cell cycle and leads to cell death. In that case, an increase in Ca_i and in the phosphorylation of tyr-cdc2 occurs during mitosis, modifications that depend on external Ca. Our results indicate that the levels of pH_i and Ca_i determine accurate levels of Ptyr-Cdc2 and P-ERK capable of ensuring progression through the first mitotic cycles. These intracellular parameters rely on external Ca, Na and bicarbonate, alterations of which during climate changes could act synergistically to perturb the early marine life.     

Ocean acidification impairs crab foraging behaviour

Anthropogenic elevation of atmospheric CO₂ is driving global-scale ocean acidification, which consequently influences calcification rates of many marine invertebrates and potentially alters their susceptibility to predation. Ocean acidification may also impair an organism''s ability to process environmental and biological cues. These counteracting impacts make it challenging to predict how acidification will alter species interactions and community structure. To examine effects of acidification on consumptive and behavioural interactions between mud crabs (Panopeus herbstii) and oysters (Crassostrea virginica), oysters were reared with and without caged crabs for 71 days at three pCO₂ levels. During subsequent predation trials, acidification reduced prey consumption, handling time and duration of unsuccessful predation attempt. These negative effects of ocean acidification on crab foraging behaviour more than offset any benefit to crabs resulting from a reduction in the net rate of oyster calcification. These findings reveal that efforts to evaluate how acidification will alter marine food webs should include quantifying impacts on both calcification rates and animal behaviour.     

Growth inhibition of hybridoma cells by ammonium ion: correlation with effects on intracellular pH

The effect of NH₄Cl addition on intracellular pH (pH _i ) was determined by flow cytometric measurements of the fluorescence of a pH-sensitive dye. The effects of NH₄Cl on growth were determined for batch growth of cells in flasks in an incubator. The addition of NH₄Cl caused a cytoplasmic acidification. A new lower steady-state value of pH _i was attained within 20–40 min of NH₄Cl addition. A correlation was found between the effects of NH₄Cl on growth and on pH _i : whereas 3 mM NH₄Cl had little effect on growth and on pH _i , 10 mM NH₄Cl caused a substantial growth inhibition and a pH _i decrease of 0.2–0.3 units. The effects of NH₄Cl on growth and on pH _i were found to be independent of the external pH value (pH _e over the range 6.8 to 7.6, except that 10 mM NH₄Cl was more toxic at pH _e 7.6. The addition of NH₄Cl caused an increase in the average cell volume at pH _e 7.6, but had no effect on the average cell volume at pH _e 's 6.8 and 7.2. For comparison, the effects of pH _e alone on growth and on pH _i were determined. There was little difference in cell growth at pH _e 's 6.8, 7.2 and 7.6. At pH _e 6.6, there was a substantial growth inhibition. Some measurements of the effects of pH _e on pH _i were made, although the steady-state value of pH _i as a function of pH _e was not determined due to limitations in the pH _i -measuring technique. These measurements showed that pH _i remained constant from pH _e 7.6 to 6.8, but fell by 0.2 units at pH _e 6.6, in agreement with the growth results.     

Preferential intracellular pH regulation represents a general pattern of pH homeostasis during acid–base disturbances in the armoured catfish,Pterygoplichthys pardalis

Preferential intracellular pH (pH_i) regulation, where pH_i is tightly regulated in the face of a blood acidosis, has been observed in a few species of fish, but only during elevated blood PCO₂. To determine whether preferential pH_i regulation may represent a general pattern for acid–base regulation during other pH disturbances we challenged the armoured catfish, Pterygoplichthys pardalis, with anoxia and exhaustive exercise, to induce a metabolic acidosis, and bicarbonate injections to induce a metabolic alkalosis. Fish were terminally sampled 2–3 h following the respective treatments and extracellular blood pH, pH_i of red blood cells (RBC), brain, heart, liver and white muscle, and plasma lactate and total CO₂ were measured. All treatments resulted in significant changes in extracellular pH and RBC pH_i that likely cover a large portion of the pH tolerance limits of this species (pH 7.15–7.86). In all tissues other than RBC, pH_i remained tightly regulated and did not differ significantly from control values, with the exception of a decrease in white muscle pH_i after anoxia and an increase in liver pH_i following a metabolic alkalosis. Thus preferential pH_i regulation appears to be a general pattern for acid–base homeostasis in the armoured catfish and may be a common response in Amazonian fishes.     

Effect of hypercapnia on intracellular pH regulation in a rainbow trout hepatoma cell line,RTH 149

Fish exposed to elevated water CO₂ experience a rapid increase in blood CO₂ levels (hypercapnia), resulting in acidification of both intra- and extra-cellular compartments. While the mechanisms associated with extracellular pH regulation have been well explored, much less is known about intracellular pH (pH_i) regulation. There is great interest in developing non-animal models for research. One such model is the rainbow trout hepatoma cell line (RTH 149), which has been used to study a wide range of topics; however, no studies have investigated its potential use in pH_i regulation. Employing the pH-sensitive fluoroprobe BCECF, the present study examined pH_i regulation in RTH 149 under normocapnia and during extracellular acidification induced by either elevated CO₂ or 1 M HCl. During exposure to hypercapnia, RTH 149 cells were acidified without recovery as long as the elevated CO₂ was maintained. In addition, rates of pH_i recovery from NH₄Cl-induced acidosis were significantly lower in cells exposed to hypercapnia or HCl compared to that in normocapnic cells, indicating that elevated CO₂ indirectly impeded pH_i recovery through a reduction in pH_e and/or pH_i. Moreover, pH_i regulation in RTH 149 was EIPA-sensitive, suggesting that an NHE may be involved. Overall, RTH 149 may have the potential for identifying transporters likely to play a role in pH_i regulation in fish. However, it should not be used as a complete replacement for in vivo studies, especially to quantify acid–base regulatory ability at whole animal level, since RTH 149 appeared to have enhanced pH_i recovery rates relative to primary hepatocytes.     

pH heterogeneity at intracellular and extracellular plasma membrane sites in HT29-C1 cell monolayers

In the colonic mucosa, short-chain fatty acids changeintracellular pH (pH_i) and extracellular pH(pH_e). In this report, confocal microscopy anddual-emission ratio imaging of carboxyseminaphthorhodofluor-1 were usedfor direct evaluation of pH_i and pH_e in asimple model epithelium, HT29-C1 cells. Live cell imaging along theapical-to-basal axis of filter-grown cells allowed simultaneousmeasurement of pH in the aqueous environment near the apical membrane,the lateral membrane, and the basal membrane. Subapical cytoplasmreported the largest changes in pH_i after isosmoticaddition of 130 mM propionate or 30 mM NH₄Cl. In restingcells and cells with an imposed acid load, lateral membranes hadpH_i values intermediate between the relatively acidicsubapical region (pH 6.3-6.9) and the relatively alkaline basalpole of the cells (pH 7.4-7.1). Transcellular pH_igradients were diminished or eliminated during an induced alkalineload. Propionate differentially altered pH_e near the apicalmembrane, in lateral intracellular spaces between adjacent cells, andnear the basal membrane. Luminal or serosal propionate causedalkalinization of the cis compartment (where propionate wasadded) but acidification of the trans compartment only inresponse to luminal propionate. Addition of NH₄Cl produced qualitatively opposite pH_e excursions. The microscopicvalues of pH_i and pH_e can explain a portion ofthe selective activation of polarized Na/H exchangers observed inHT29-C1 cells in the presence of transepithelial propionate gradients.

     

Changes in Intracellular pH Are Not Correlated with the Circadian Rhythm of Neurospora

Intracellular pH (pH_i) was measured during the circadian cycle of Neurospora. Internal pH of Neurospora cultures in liquid medium was assayed by the 5,5-dimethyl-2,4-oxazolidinedione method and gave values for pH_i which were similar to those previously obtained by other workers using pH-microelectrodes with agar-grown cultures. Cytoplasmic pH changed in liquid medium cultures, but these changes were not related to the circadian clock. Furthermore, treatments which raise or lower pH_i do not phase-shift the circadian rhythm. These results indicate that pH_i plays no specific role in regulating the circadian clock of Neurospora.     

Estimation of intracellular pH in muscle of fishes from different thermal environments

A technique based on homogenisation of rapidly frozen tissue was used to investigate the regulation of intracellular pH (pH_i) in freshwater and marine fish from diverse environmental temperatures. The following species were held at ambient temperatures of ca. 1°C (Notothenia coriiceps; Antarctica), 5°C (Pleuronectes platessa, Myoxocephalus scorpius; North Sea), and 26°C (Oreochromis niloticus; African lakes). The effects of seasonal acclimatisation to 4, 11 and 18°C were also examined in rainbow trout in the winter, autumn and summer, respectively. Extracellular (whole blood) pH (pH_e) did not follow the constant relative alkalinity relationship, where pH⁺=pOH⁻ for any particular temperature, over a range of 1–26°C (overall δpH_e/δT=0.009±0.002 U °C⁻¹; P<0.001), apparently being regulated by ionic fluxes and ventilation. Intracellular pH (pH_i) was also regulated independently of pN(=0.5 pK water) in all species of fish examined. The inverse relationship between pH_i and environmental temperature gave an overall δpH_i/δT of −0.010±0.001 U °C⁻¹ (for both white and red muscle) and −0.004±0.003 U °C⁻¹ (cardiac muscle). However, between 1 and 11°C δpH_i/δT was much higher (P<0.001), −0.022±0.003 U °C⁻¹ (white muscle) and −0.022±0.004 U °C⁻¹ (red muscle). The possible adaptive roles for these different acid–base responses to environmental temperature variation among tissues and species, and the potential difficulties of estimating pH_i, are discussed.     

海洋酸化对蟹类影响的研究进展

人类活动排放二氧化碳引起了海水碳酸盐平衡体系变化和pH下降, 最终导致了“海洋酸化”。海洋酸化对蟹类产生了从表观到分子的多重影响。文章在总结海洋酸化对各种蟹类生长发育、生理与代谢、表型和行为等方面影响的基础上, 对其影响的机理展开了讨论, 并对控制海洋酸化及其对蟹类的影响研究提出了意见和建议。     

Thermotolerance and intracellular pH in two Chinese hamster cell lines adapted to growth at low pH

As an in vitro model for the low extracellular pH (pH_e) which has frequently been observed in tumors, cell lines have been grown in a low-pH medium in order to allow cell adaptation to that milieu. Two Chinese hamster cell lines [Chinese hamster ovary (CHO) and Chinese hamster ovarian carcinoma (OvCa)] were compared, both of which acquired thermotolerance during 42°C heating in pH_e = 7.3 buffer, but not in pH_e = 6.7 medium unless grown at that pH long enough to become adapted. CHO cells, even when acutely acidified, showed higher intracellular pH (pH_i) values in a suspension assay than OvCa cells, which confirmed the danger of comparing absolute values of pH_i between cell lines. Despite this fundamental difference, relative changes in pH_i were similar in that both lines showed a higher pH_i in adapted than in unadapted cells, over the range of pH_e values tested. The upregulation of pH_i was statistically significant, but the two lines differed in the time frame over which adaptation occurred. OvCa cells acquired an enhanced ability to develop tolerance to 42° heat at pH_e = 6.7 in 4 days, but the CHO cells acquired this ability more progressively, achieving a maximum ability at approximately 100 days. In contrast, both lines were able to upregulate their pH_i within 4 hours of being exposed to pH 6.7 medium. A further indication of different biochemical mechanisms at work was the opposite effects seen on pH_i in the two cell lines upon the removal of extracellular CO₂/HCO⁻₃. The differential between adapted and unadapted OvCa cells was enhanced by removal of bicarbonate, whereas CHO cells seemed less stable and the data with greater scatter failed to show any difference between adapted and unadapted cells. © 1996 Wiley-Liss, Inc.     

Demonstration of expression of a neuropeptide-encoding gene in crustacean hemocytes

Crustacean hyperglycemic hormone (CHH) was originally identified in a neuroendocrine system-the X-organ/sinus gland complex. In this study, a cDNA (Prc-CHH) encoding CHH precursor was cloned from the hemocyte of the crayfish Procambarus clarkii. Analysis of tissues by a CHH-specific enzyme-linked immunosorbent assay (ELISA) confirmed the presence of CHH in hemocytes, the levels of which were much lower than those in the sinus gland, but 2 to 10 times higher than those in the thoracic and cerebral ganglia. Total hemocytes were separated by density gradient centrifugation into layers of hyaline cell (HC), semi-granular cell (SGC), and granular cell (GC). Analysis of extracts of each layer using ELISA revealed that CHH is present in GCs (202.8 ± 86.7 fmol/mg protein) and SGCs (497.8 ± 49.4 fmol/mg protein), but not in HCs. Finally, CHH stimulated the membrane-bound guanylyl cyclase (GC) activity of hemocytes in a dose-dependent manner. These data for the first time confirm that a crustacean neuropeptide-encoding gene is expressed in cells essential for immunity and its expression in hemocytes is cell type-specific. Effect of CHH on the membrane-bound GC activity of hemocyte suggests that hemocyte is a target site of CHH. Possible functions of the hemocyte-derived CHH are discussed.     

Regulation of intracellular pH in rat uterine smooth muscle, studied by P NMR spectroscopy

Intracellular pH (pH_i) affects smooth muscle function, yet little is known concerning its regulation. I have therefore investigated pH regulation in rat uterus, using ³¹P-NMR spectroscopy. A change in extracellular pH(pH_e) of 1 pH unit (7.4 to 6.4) elicited a 0.29 change in pH_i; smaller changes in pH_o were accompanied by proportionately smaller changes in pH_i. The pH changes were reversible. There was no fall of uterine ATP or phosphocreatine during the pH changes.     

Regulation of intracellular pH in rat uterine smooth muscle,studied by 31P NMR spectroscopy

Intracellular pH (pH_i) affects smooth muscle function, yet little is known concerning its regulation. I have therefore investigated pH regulation in rat uterus, using ³¹P-NMR spectroscopy. A change in extracellular pH(pH_e) of 1 pH unit (7.4 to 6.4) elicited a 0.29 change in pH_i; smaller changes in pH_o were accompanied by proportionately smaller changes in pH_i. The pH changes were reversible. There was no fall of uterine ATP or phosphocreatine during the pH changes.     

Separate Gating Mechanisms Mediate the Regulation of K2P Potassium Channel TASK-2 by Intra- and Extracellular pH

TASK-2 (KCNK5 or K_2P5.1) is a background K⁺ channel that is opened by extracellular alkalinization and plays a role in renal bicarbonate reabsorption and central chemoreception. Here, we demonstrate that in addition to its regulation by extracellular protons (pH_o) TASK-2 is gated open by intracellular alkalinization. The following pieces of evidence suggest that the gating process controlled by intracellular pH (pH_i) is independent from that under the command of pH_o. It was not possible to overcome closure by extracellular acidification by means of intracellular alkalinization. The mutant TASK-2-R224A that lacks sensitivity to pH_o had normal pH_i-dependent gating. Increasing extracellular K⁺ concentration acid shifts pH_o activity curve of TASK-2 yet did not affect pH_i gating of TASK-2. pH_o modulation of TASK-2 is voltage-dependent, whereas pH_i gating was not altered by membrane potential. These results suggest that pH_o, which controls a selectivity filter external gate, and pH_i act at different gating processes to open and close TASK-2 channels. We speculate that pH_i regulates an inner gate. We demonstrate that neutralization of a lysine residue (Lys²⁴⁵) located at the C-terminal end of transmembrane domain 4 by mutation to alanine abolishes gating by pH_i. We postulate that this lysine acts as an intracellular pH sensor as its mutation to histidine acid-shifts the pH_i-dependence curve of TASK-2 as expected from its lower pK_a. We conclude that intracellular pH, together with pH_o, is a critical determinant of TASK-2 activity and therefore of its physiological function.     

Intracellular pH change does not accompany egg activation in the mouse

In the sea urchin, some other marine invertebrates, and the frog, Xenopus, egg activation at fertilization is accompanied by an increase in intracellular pH (pH_i). We measured pH_i, in germinal vesicle (GV)-intact mouse oocytes, ovulated eggs, and in vivo fertilized zygotes using the pH indicator dye, SNARF-1. The mean pH_i was 6.96 ± 0.004 (± SEM) in GV-intact oocytes, 7.00 ± 0.01 in ovulated, unfertilized eggs, and 7.02 ± 0.01 in fertilized zygotes, indicating no sustained changes in pH_i after germinal vesicle breakdown (GVBD) or fertilization. To examine whether transient changes in pH_i occur shortly after egg activation, mouse eggs were parthenogenetically activated by 7% ethanol in phosphate buffered saline (PBS); no significant change in pH_i followed ethanol activation. Since increased Na⁺/H⁺ antiporter activity is responsible for pH_i increase in the sea urchin, pH_i was measured in the absence of added bicarbonate or CO₂ la condition under which the antiporter would be the only major pH_i regulatory mechanism able to operate, since the others were bicarbonate- dependent) in GV-intact oocytes, ovulated eggs, and in vivo fertilized zygotes to determine whether a Na⁺/H⁺ antiporter was activated. There was no physiologically significant difference in pH_i after GVBD or fertilization, when pH_i was measured in bicarbonate-free medium, nor any change upon parthenogenetic activation. Thus, a change in pH_i is not a feature of egg activation in the mouse. © 1996 Wiley-Liss, Inc.