Acidification and alkalinization of lakes by experimental addition of nitrogen compounds

Fertilization of a small lake with ammonium chloride for four years as part of a eutrophication experiment caused it to acidify to pH values as low as 4.6. Implications for acidification of lakes via precipitation polluted with ammonium compounds are discussed.When phosphate was supplied with the ammonium, biological nitrogen uptake, apparently by phytoplankton, was the main mechanism causing acidification. When ammonium was applied without phosphate, it accumulated to high concentrations in solution, after which nitrification caused rapid acidification. In both cases, the whole-lake efficiency of acidification was low, averaging about 13% of the potential acidification of supplied ammonium chloride (Table 2).Subsequent application of phosphate plus sodium nitrate for two years caused the pH of the lake to increase. The efficiency of alkalinization was higher than for acidification, averaging 69% of the potential alkalinization of the supplied sodium nitrate.     

Culture medium alkalinization by dermatophytes

95 dermatophyte strains (12 of Trichophyton mentagrophytes, 12 of T. tonsurans, 11 of T. rubrum, 12 of T. megninii, 12 of T. violaceum, 2 of T. schoenleinii, 1 of T. soudanense, 12 of M. canis, 8 of Microsporum gypseum, 1 of M. ferrugineum and 12 of Epidermphoyton floccosum). 1 of Aspergillus niger, 1 of A. ochraceus, 1 of Paecilomyces sp., 1 of Penicillium sp. and 1 of Candida albicans were grown in Sabouraud liquid medium for the study of pH variation over 6 weeks at room temperature and after 4 weeks at 37 degrees C. All the dermatophyte strains alkalinized the medium. The highest pH values after 2-3 weeks' development in room temperature were produced by T. mentagrophytes, M. gypseum and M. canis, and the lowest by T. rubrum and T. violaceum. After the 4th week the alkalinizing activity became more marked for T. mentagrophytes and remained stationary for T. violaceum, In the 5th week the values produced by T. tonsurans were higher than those for M. gypseum, and those for E. floccosum and T. megninii were higher than those of M. canis. A similar behaviour was observed for T. rubrum and T. megninii and for M. canis, M. gypseum and M. ferrugineum. There seems to be a relation between the alkalinizing capacity and the rapidity and amount of the growth. At 37 degrees C both alkalinization and range of variation of the pH values of the medium became more noticeable for the strains of each species.     

Intracellular alkalinization in dexamethasone-induced thymocyte apoptosis

Glucocorticoid can induce apoptosis of thymocytes, but its mechanism is not clear yet. In this study, we reported that dexamethasone-induced apoptosis was associated with intracellular alkalinization. Dexamethasone induced a higher percentage of apoptosis in 138 mM than in 50 mM NaCl, total abrogation of apoptosis was noted in NaCl-depleted culture medium. Highest apoptotic rate was observed in medium with pH 7.2, whereas it was partially and completely inhibited at pH 6.5 and pH 6.0, respectively. Intracellular pH was higher in pre-apoptotic thymocytes than non-apoptotic ones. The Na+ /H+ antiporter inhibitor of 5-(N,N'-dimethyl)-amiloride inhibited the dexamethasone-induced increase in pHi and apoptosis of thymocytes. Glucocorticoid antagonist RU486 also blocked the dexamethasone-induced effect. Furthermore, the apoptosis and increase in intracellular pH induced by dexamethasone were inhibited by cycloheximide, actinomycin D. It seems that intracellular pH is increased during the development of thymocyte apoptosis and inhibiting its increment would retard the rate of progression to cell death.     

Responses of salivary acinar cells to intracellular alkalinization

Responses of rat submandibular acini to intracellular alkalinization were investigated. Intracellular alkalinization was induced by addition of NH⁴Cl or methylamines, or by prepulse with Na butyrate. Only partial recovery occurred following Na butyrate prepulse or methylated amine addition, but full recovery was observed following addition of NH⁴Cl. The latter recovery was DIDS and dimethylamiloride-insensitive but was inhibited by bumetanide or high [K⁺] and stimulated in Na⁺ free buffer and by ouabain. Acetylcholine stimulated recovery from NH⁴Cl- or Na butyrate pre-pulse-induced alkalinization and reduced the extent of alkalinization induced by methylated amines. Acetylcholine-stimulated recovery from NH⁴Cl-induced alkalinization was mimicked by substance P or ionomycin and was partially Ca²⁺-dependent. This stimulated recovery was bumetanide-insensitive but was partially sensitive to charybdotoxin. Taken together, these data indicate that in unstimulated cells, recovery from alkalinization induced by NH⁴Cl occurs by bumetanide-sensitive transport of the NH⁴⁺ ion, that DIDS-inhibitable anion transport contributes little to this recovery, and that acetylcholine and other Ca²⁺-elevating agents accelerate recovery from NH⁴Cl-induced alkaline challenge by a mechanism insensitive to bumetanide, DIDS, ouabain, and dimethylamiloride but sensitive to extracellular Ca²⁺ and to charybdotoxin. Partial recovery from alkaline challenge can also occur in the absence of NH⁴⁺ ions, and acetylcholine also stimulates this mode of recovery. Together, these data suggest that these cells have little intrinsic ability to recover from intracellular alkalinization and that the NH⁴⁺ ion may be a surrogate for K⁺ in at least two ion transport pathways. © 1994 wiley-Liss, Inc.     

The induction of ornithine decarboxylase by L-asparagine and intracellular alkalinization

The uptake of transport systems A and N amino acids, most noticeably L-asparagine, is essential for the induction of ornithine decarboxylase (L-ornithine carboxylase, EC 4.1.1.17) in cultured cells and we have proposed that the uptake-associated pH and ionic changes might constitute part of the cell activation signal (1). In the present study, it was shown that extracellular L-asparagine caused an immediate and transient increase in intracellular pH which was continuously monitored by the fluorescence probe BCECF (2',7'-bis(carboxyethyl)-5,6-carboxyfluorescein). NH4Cl and NH4OH which caused intracellular alkalinization also caused ornithine decarboxylase activity to increase.     

Luminal alkalinization in the intestine of the goby

Summary The rate of luminal alkalinization in vitro byGillichthys mirabilis posterior intestine as measured by a manual pH stat technique was 0.70±0.05 Equiv/cm² h; acidification of the mucosal medium was never observed. The rate of HCO ₃ ^– secretion (J ^HCO ₃) was reduced by ouabain, serosally-applied DIDS, removal of serosal HCO ₃ ^– and replacement of media Cl^– with gluconate. HCO ₃ ^– secretion was enhanced replacement of Cl^– with isethionate and unaffected by mucosal DIDS, furosemide or acetazolamide.J ^HCO ₃ was reduced at mucosal pH above or below 7.5. These results support active HCO ₃ ^– secretion via a Cl^–/HCO ₃ ^– exchange mechanism on the basolateral membrane and a conductive exit pathway for HCO ₃ ^– , H⁺ or OH^– on the apical membrane.Abbreviations DIDS diisothiocyanostilbene-2,2-disulfonic acid - TEP transepithelial potential - GBR Gillichthyts bicarbonate Ringer - GUR Gillichthys unbuffered, bicarbonate-free Ringer - GER Gillichthys EPPS-buffered, bicarbonate-free Ringer - EPPS N-(2-hydroxyethyl)piperazine-N-3-propanesulfonic acid     

Poliovirus-induced intracellular alkalinization involves a proton ATPase and protein phosphorylation

We reported previously that poliovirus infection induces alkalinization in HeLa cells and that an alkaline intracellular pH (pHi) promoted viral replication. Additional experiments were carried out to understand the underlying mechanism. Virus-infected or control monolayer cultures were incubated with nominally bicarbonate-free Eagle's minimal essential medium (MEM) buffered with N-2-hydroxyethylpiperazine-N-3-ethanesulfonic acid (HEPES), and immediately following preincubations, changes in pHi were monitored via benzoic acid uptake around 2 h postinfection. The absence of pH increase in cells infected with ultraviolet light-inactivated virus (UV-virus) indicated that viral gene expression was required for this effect. On the other hand, lack of effect of 3 mM guanidine, an inhibitor of poliovirus-specific RNA but not protein synthesis, suggested that translation of input viral genome RNA is sufficient for the pH increase. Activation of Na⁺/H⁺ exchange, Cl^?HCO^?₃ exchange, or H⁺-ATPase was considered as possible mechanisms by which alkalinization occurs in virus-infected cells. Na⁺/H⁺ exchange was excluded because the pH effect occurred in a Na⁺/H⁺ exchange deficient HeLa cell mutant. Similarly, Cl^?/HCO^?₃ exchange was excluded because virus-specific alkalinization was evident in the presence of Cl^? or bicarbonate deficient medium and was not associated with an increase in HCO^?₃ uptake or a decrease in Cl^? uptake. Lack of dependence on Na⁺, abrogation by 10 μM 7-chloro-4-nitrobenz-2-oxa-1,3-diazole (NBD-Cl), and resistance to 1 mM vandate suggested that this effect was due to the activation of a vacuolar-type (V) proton ATPase. Studies using protein kinase inhibitors indicated that activation of the ATPase in virus-infected cells probably involved protein kinase C-mediated phosphorylation. © 1993 Wiley-Liss, Inc.     

Golgi alkalinization by the papillomavirus E5 oncoprotein

The E5 oncoprotein of bovine papillomavirus type I is a small, hydrophobic polypeptide localized predominantly in the Golgi complex. E5-mediated transformation is often associated with activation of the PDGF receptor (PDGF-R). However, some E5 mutants fail to induce PDGF-R phosphorylation yet retain transforming activity, suggesting an additional mechanism of action. Since E5 also interacts with the 16-kD pore-forming subunit of the vacuolar H(+)-ATPase (V-ATPase), the oncoprotein could conceivably interfere with the pH homeostasis of the Golgi complex. A pH-sensitive, fluorescent bacterial toxin was used to label this organelle and Golgi pH (pH(G)) was measured by ratio imaging. Whereas pH(G) of untreated cells was acidic (6.5), no acidification was detected in E5-transfected cells (pH approximately 7.0). The Golgi buffering power and the rate of H(+) leakage were found to be comparable in control and transfected cells. Instead, the E5-induced pH differential was attributed to impairment of V-ATPase activity, even though the amount of ATPase present in the Golgi complex was unaltered. Mutations that abolished binding of E5 to the 16-kD subunit or that targeted the oncoprotein to the endoplasmic reticulum abrogated Golgi alkalinization and cellular transformation. Moreover, transformation-competent E5 mutants that were defective for PDGF-R activation alkalinized the Golgi lumen. Neither transformation by sis nor src, two oncoproteins in the PDGF-R signaling pathway, affected pH(G). We conclude that alkalinization of the Golgi complex represents a new biological activity of the E5 oncoprotein that correlates with cellular transformation.     

Multiplication-stimulating activity-induced alkalinization of canine renal proximal tubular cells

The actions of a variety of polypeptide growth factors on isolated cells are thought to be initiated by stimulation of Na+-H+ exchange across the plasma membranes of the cells resulting in intracellular alkalinization. To determine whether insulin-like growth factors (IGFs) exert actions through such a mechanism, we incubated suspensions of canine renal proximal tubular segments with insulin or IGF I or with multiplication-stimulating activity (MSA)/IGF II. Changes in intracellular pH were detected by measurements of the distribution of [14C]5,5-dimethoxazolidine-2,4-dione. Incubation of segments with 10(-9) M MSA under conditions such that extracellular [Na+] greater than intracellular [Na+] effected intracellular alkalinization detectable within 1-2 min. Alkalinization was not observed under conditions where this gradient was not present. Alkalinization was not prevented by inclusion of 1 mM 4-acetamido-4'-isothiocyanostilbene-2,2'-disulfonic acid or 1 mM ouabain in incubations, but was inhibited by amiloride. Incubation of proximal tubular segments with as little as 10(-11) M MSA effected intracellular alkalinization. Incubation with as much as 10(-6) M insulin or IGF I did not. Our findings are consistent with an action of MSA/IGF II to stimulate Na+-H+ exchange across the plasma membrane of the renal proximal tubular cell. It is possible that the stimulation represents a mechanism by which actions of IGF II are initiated in growth factor-sensitive cells.     

Evidence for poliovirus-induced cytoplasmic alkalinization in HeLa cells

During the early period after poliovirus infection of HeLa cells, cellular Na+/K+ ATPase activity is transiently activated. We investigated the possibility that Na+/K+ ATPase activation is a consequence of Na+/H+ antiporter activation. Increased uptake of the weak organic acid 5,5-dimethyloxazolidine-2,4-dione by infected cells around 2 h after infection suggested cytoplasmic alkalinization equivalent to pH 7.7 during the biosynthetic phase of viral replication. Consistent with the involvement of Na+/H+ antiporter activation in this phenomenon, it was found to be [Na+]-dependent and inhibited by 5-(N-ethyl-N-isopropyl)amiloride (EIPA). However, the pH increase was not associated with an increase in amiloride-sensitive Na+ uptake by infected cells predicted by this mechanism. By contrast, the alkalinization could be abolished with the anion-exchange inhibitor 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid (DIDS), implicating an anion-exchange mechanism, such as Cl-/HCO3- exchange, in this process. In addition to abolishing virus-induced intracellular alkalinization, both EIPA and DIDS moderately inhibited viral replication. Manipulation of intracellular pH with nigericin in the incubation medium revealed that maximum viral replication required a pH of about 7.7 and that replication was significantly inhibited even at pH 7.3. Thus, the pH increase in infected cells appeared to be physiologically relevant. These findings represent the first demonstration of a biologically meaningful pH increase in cells infected with a lytic virus.     

Acidification capacity of the kidneys and aging

The authors studied the acidification capacity of the kidneys in 60 healthy subjects aged 18-70 years after a single load of NH4Cl in a dose of 0.1 g/kg. The acidification load was followed by a significant increase in NH4+ excretion in the first five hours afterwards in young individuals (18-30 years). In subjects aged over 50, changes in NH4+ excretion were nonsignificant under these conditions. Titratable acid excretion rose significantly after the given acidification load in subjects aged 18-60 years; in older subjects it no longer increased significantly. Changes in titratable acid excretion displayed a significant correlation to the renal excretion of phosphates. The findings indicate that the diminished capacity of older subjects to increase titratable acid excretion after an acute NH4Cl load is due to an insufficient decrease in the tubular resorption of phosphates. Renal capacity for adequate reduction of the urine pH after a NH4Cl load was unimpaired.     

The impact of nanoparticle-driven lysosomal alkalinization on cellular functionality

Background

The biomedical use of nanosized materials is rapidly gaining interest, which drives the quest to elucidate the behavior of nanoparticles (NPs) in a biological environment. Apart from causing direct cell death, NPs can affect cellular wellbeing through a wide range of more subtle processes that are often overlooked. Here, we aimed to study the effect of two biomedically interesting NP types on cellular wellbeing.

Results

In the present work, gold and SiO₂ NPs of similar size and surface charge are used and their interactions with cultured cells is studied. Initial screening shows that at subcytotoxic conditions gold NPs induces cytoskeletal aberrations while SiO₂ NPs do not. However, these transformations are only transient. In-depth investigation reveals that Au NPs reduce lysosomal activity by alkalinization of the lysosomal lumen. This leads to an accumulation of autophagosomes, resulting in a reduced cellular degradative capacity and less efficient clearance of damaged mitochondria. The autophagosome accumulation induces Rac and Cdc42 activity, and at a later stage activates RhoA. These transient cellular changes also affect cell functionality, where Au NP-labelled cells display significantly impeded cell migration and invasion.

Conclusions

These data highlight the importance of in-depth understanding of bio-nano interactions to elucidate how one biological parameter (impact on cellular degradation) can induce a cascade of different effects that may have significant implications on the further use of labeled cells.

     

胞外酸性与肿瘤的浸润转移

组织缺氧是实体瘤的一个主要特征,它引起肿瘤细胞胞外酸性环境的形成.肿瘤细胞通过质子感知的G蛋白偶联受体（G protein-coupled receptors,GPCRs）或质子感知的离子通道感知其胞外的酸性环境,并激活多条细胞内信号通路,影响细胞功能. 肿瘤最致命的方面在于其转移能力,肿瘤转移程度与肿瘤细胞迁移能力呈正相关. 因此,对胞外酸性与肿瘤细胞迁移扩散之间关系的深入研究将有助于发现更多新的抗肿瘤转移药物.本文就肿瘤酸性微环境的形成、肿瘤细胞的质子感知制、胞外酸性环境对肿瘤浸润转移的影响及如何将肿瘤pH调节应用于癌症治疗等方面的内容予以综述.     

Bicarbonate determines cytoplasmic pH and suppresses mitogen-induced alkalinization in fibroblastic cells

Addition of growth factors to responsive cells in HCO3- -free media results in a rapid rise in cytoplasmic pH (pHi) caused by activation of Na+/H+ exchange. In this paper, we have examined how pHi regulation and growth factor responsiveness are affected by HCO3(-)using quiescent mouse MES-1 fibroblastic cells as a model. When cells are exposed to 25 mM HCO3-, 5% CO2, steady-state pHi reaches a new more alkaline level (by 0.25 unit) within 10 min. This rise in pHi is both Na+- and HCO3- -dependent, does not occur in Cl(-)-depleted cells, and is inhibited by 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid, but not by 5-(n,n-dimethyl)-amiloride, indicating the involvement of Na+-dependent HCO3-/Cl- exchange. Furthermore, the recovery of pHi from acute acid loads is accelerated by HCO3- in a Na+-dependent and 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid-sensitive manner and is blocked in Cl(-) -depleted cells. Similar results were obtained for mouse 3T3 cells and human fibroblasts. In the presence of HCO3-/CO2 (pH 7.35), mitogens and phorbol esters fail to induce a detectable rise in pHi. However, when steady-state pHi is artificially lowered by approximately 0.4 unit, growth factors evoke significant increases in pHi due to activation of Na+/H+ exchange. In the absence of HCO3-, mitogen-induced alkalinizations are readily detectable but not when pHi is artificially elevated to the value normally observed in HCO3- media. From these results we conclude that: 1) Na+-dependent HCO3-/Cl- exchange determines steady-state pHi and acts in parallel with Na+/H+ exchange to stimulate pHi recovery from acid loading; 2) Na+-dependent HCO3-/Cl- exchange raises steady-state pHi to a level beyond the operating range of the Na+/H+ exchanger and thereby prevents growth factors from alkalinizing the cytoplasm any further. The results also imply that, unlike Na+/H+ exchange, Na+-dependent HCO3-/Cl- exchange is not activated by mitogens.     

Cytoplasmic alkalinization during germ tube formation in Candida albicans

Weak acids were used to measure the internal pH of yeast cells of Candida albicans that had been induced to form buds or germ tubes. Under conditions that supported germ tube formation the internal pH rose from around 6.8 to over 8.0 after 30 min in two different induction media. Internal pH measured by 31P NMR confirmed this pattern and also showed that the internal pH fell to around 7.0 prior to the outgrowth of germ tubes. Conditions which led to budding induced less cytoplasmic alkalinization. This alkalinization was brought about when cells were inoculated into media of neutral pH and at an increased temperature. Increasing the temperature of the medium augmented the alkalinization of the cytoplasm induced by raising the external pH. Strains of C. albicans defective in the ability to produce germ tubes did not show this dramatic cytoplasmic alkalinization under conditions which normally supported filamentous growth. The raising of internal pH may be due to the activation of the plasma membrane proton-pumping ATPase since diethylstilboestrol inhibited the cytoplasmic alkalinization and germ tube formation without causing irreversible loss of cell viability. The results show that the induction of the dimorphic transition in this organism is accompanied by a steep rise in internal pH. It is not known whether these changes are the cause or consequence of morphogenesis.