The organic osmolytes betaine and proline are transported by a shared system in early preimplantation mouse embryos

Betaine and proline protect preimplantation mouse embryos against increased osmolarity and decreased cell volume, implying that they may function as organic osmolytes. However, the transport system(s) that mediates their accumulation in fertilized eggs and early embryos was unknown, and previously identified mammalian organic osmolyte transporters could not account for their transport. Here, we report that there is a single saturable transport component shared by betaine and proline in 1-cell mouse embryos. A series of inhibitors had nearly identical effects on both betaine and proline transport by this system. In addition, K(i) values for reciprocal inhibition of betaine and proline transport were approximately 100-300 microM, similar to K(m) values ( approximately 200-300 microM) for their transport, and both had similar maximal transport rates (V(max)). The K(i) values for inhibition of betaine and proline transport by dimethylglycine were similar ( approximately 2 mM), further supporting transport of both substrates by a single transport system. Finally, betaine and proline transport each required Na(+)- and Cl(-). These data were consistent with a single, Na(+)- and Cl(-)-requiring, betaine/proline transport system in 1-cell mouse embryos. While betaine was only transported by a single saturable system, we found an additional, less conspicuous proline transport route that was betaine-insensitive, Na(+)-sensitive, and inhibited by alanine, leucine, cysteine, and methionine. Furthermore, we showed that betaine, like proline, is present in the mouse oviduct and thus could serve as a physiological substrate. Finally, accumulation of both betaine and proline increased with increasing osmolarity, consistent with a possible role as organic osmolytes in early embryos.     

Beta-alanine but not taurine can function as an organic osmolyte in preimplantation mouse embryos cultured from fertilized eggs

Early preimplantation mouse embryos are susceptible to the detrimental effects of increased osmolarity and, paradoxically, their in vitro development is significantly compromised by osmolarities near that of oviductal fluid. In vitro development can be restored, however, by several compounds that are accumulated by 1-cell embryos to act as organic osmolytes, providing intracellular osmotic support and cell volume regulation. Taurine, a substrate of the beta-amino acid transporter that functions as an organic osmolyte transporter in other cells, had been proposed to function as an organic osmolyte in mouse embryos. Here, however, we found that taurine is neither able to provide protection for in vitro embryo development against increased osmolarity nor is it accumulated to higher intracellular levels as osmolarity is increased, indicating that it cannot function as an organic osmolyte in early preimplantation embryos. In contrast, beta-alanine, the other major substrate of the beta-amino acid transporter, both protects against increased osmolarity and is accumulated to somewhat higher levels as osmolarity is increased, indicating that it is able to function as an organic osmolyte in embryos. However, we also found that beta-alanine is displaced from embryos by glycine-the most effective organic osmolyte in embryos previously identified-and beta-alanine does not increase protection above that afforded by glycine at concentrations near those in vivo. Thus, the beta-amino acid transporter is likely present in early preimplantation embryos to supply beta-amino acids such as taurine for purposes other than to serve as organic osmolytes.     

Regulation of intracellular glycine as an organic osmolyte in early preimplantation mouse embryos

GLYT1, a glycine transporter belonging to the neurotransmitter transporter family, has recently been identified as a novel cell volume-regulatory mechanism in the earliest stages of the mouse preimplantation embryo. It apparently acts by regulating the steady-state intracellular concentration of glycine, which functions as an organic osmolyte in embryos, to balance external osmolarity and thus maintain cell volume. GLYT1 in embryos was the first mammalian organic osmolyte transporter identified that appears to function in cell volume control under conditions of normal osmolarity, rather than being a response to the stress of chronic hypertonicity. Its maximal rate of transport was shown to be regulated by osmolarity. However, it was not known whether this osmotic regulation of the rate of glycine transport is sufficient to account for the observed control of steady-state intracellular glycine levels as a function of osmolarity in embryos. Here, we show that the intracellular accumulation of glycine in embryos is a direct function of the rate of glycine uptake via GLYT1. In addition, we have shown that the rate of efflux, likely via the volume-regulated anion and organic osmolyte channel in embryos, is also under osmotic regulation and contributes substantially to the control of steady-state glycine concentrations. Together, control of both the rate of uptake and rate of efflux of glycine underlies the mechanism of osmotic regulation of the steady-state concentration of glycine and hence cell volume in early embryos.     

Characterization of glycine betaine porter I from Listeria monocytogenes and its roles in salt and chill tolerance

Listeria monocytogenes is a pathogenic bacterium that can grow at low temperatures and elevated osmolarity. The organism survives these stresses by the intracellular accumulation of osmolytes: low-molecular-weight organic compounds which exert a counterbalancing force. The primary osmolyte in L. monocytogenes is glycine betaine, which is accumulated from the environment via two transport systems: glycine betaine porter I, an Na(+)-glycine betaine symporter; and glycine betaine porter II, an ATP-dependent transporter. The biochemical characteristics of glycine betaine porter I were investigated in a mutant strain (LTG59) lacking the ATP-dependent transporter. At 4% NaCl, glycine betaine uptake in LTG59 was about fivefold lower than in strain DP-L1044, which has both transporters, indicating that the ATP-dependent transporter is the primary means by which glycine betaine enters the cell. In the absence of osmotic stress, cold-activated uptake by both transporters was most rapid between 7 and 12 degrees C, but a larger fraction of the total uptake was via the ATP-dependent transporter than was observed under salt-stressed conditions. Twelve glycine betaine analogs were tested for their ability to inhibit glycine betaine uptake and growth of stressed cultures. Carnitine, dimethylglycine, and gamma-butyrobetaine appear to inhibit the ATP-dependent transporter, while trigonelline and triethylglycine primarily inhibit glycine betaine porter I. Triethylglycine was also able to retard the growth of osmotically stressed L. monocytogenes grown in the presence of glycine betaine.     

Functional characterization of the Betaine/gamma-aminobutyric acid transporter BGT-1 expressed in Xenopus oocytes.

Betaine is an osmolyte accumulated in cells during osmotic cell shrinkage. The canine transporter mediating cellular accumulation of the osmolyte betaine and the neurotransmitter gamma-aminobutyric acid (BGT-1) was expressed in Xenopus oocytes and analyzed by two-electrode voltage clamp and tracer flux studies. Exposure of oocytes expressing BGT-1 to betaine or gamma-aminobutyric acid (GABA) depolarized the cell membrane in the current clamp mode and induced an inward current under voltage clamp conditions. At 1 mM substrate the induced currents decreased in the following order: betaine = GABA > diaminobutyric acid = beta-alanine > proline = quinidine > dimethylglycine > glycine > sarcosine. Both the Vmax and Km of GABA- and betaine-induced currents were voltage-dependent, and GABA- and betaine-induced currents and radioactive tracer uptake were strictly Na+-dependent but only partially dependent on the presence of Cl-. The apparent affinity of GABA decreased with decreasing Na+ concentrations. The Km of Na+ also depended on the GABA and Cl- concentration. A decrease of the Cl- concentration reduced the apparent affinity for Na+ and GABA, and a decrease of the Na+ concentration reduced the apparent affinity for Cl- and GABA. A comparison of 22Na+-, 36Cl--, and 14C-labeled GABA and 14C-labeled betaine fluxes and GABA- and betaine-induced currents yielded a coupling ratio of Na+/Cl-/organic substrate of 3:1:1 or 3:2:1. Based on the data, a transport model of ordered binding is proposed in which GABA binds first, Na+ second, and Cl- third. In conclusion, BGT-1 displays significant functional differences from the other members of the GABA transporter family.     

Characterization of Glycine Betaine Porter I from Listeria monocytogenes and Its Roles in Salt and Chill Tolerance

Listeria monocytogenes is a pathogenic bacterium that can grow at low temperatures and elevated osmolarity. The organism survives these stresses by the intracellular accumulation of osmolytes: low-molecular-weight organic compounds which exert a counterbalancing force. The primary osmolyte in L. monocytogenes is glycine betaine, which is accumulated from the environment via two transport systems: glycine betaine porter I, an Na⁺-glycine betaine symporter; and glycine betaine porter II, an ATP-dependent transporter. The biochemical characteristics of glycine betaine porter I were investigated in a mutant strain (LTG59) lacking the ATP-dependent transporter. At 4% NaCl, glycine betaine uptake in LTG59 was about fivefold lower than in strain DP-L1044, which has both transporters, indicating that the ATP-dependent transporter is the primary means by which glycine betaine enters the cell. In the absence of osmotic stress, cold-activated uptake by both transporters was most rapid between 7 and 12°C, but a larger fraction of the total uptake was via the ATP-dependent transporter than was observed under salt-stressed conditions. Twelve glycine betaine analogs were tested for their ability to inhibit glycine betaine uptake and growth of stressed cultures. Carnitine, dimethylglycine, and γ-butyrobetaine appear to inhibit the ATP-dependent transporter, while trigonelline and triethylglycine primarily inhibit glycine betaine porter I. Triethylglycine was also able to retard the growth of osmotically stressed L. monocytogenes grown in the presence of glycine betaine.     

Three transporters mediate uptake of glycine betaine and carnitine by Listeria monocytogenes in response to hyperosmotic stress

The uptake and accumulation of the potent osmolytes glycine betaine and carnitine enable the food-borne pathogen Listeria monocytogenes to proliferate in environments of elevated osmotic stress, often rendering salt-based food preservation inadequate. To date, three osmolyte transport systems are known to operate in L. monocytogenes: glycine betaine porter I (BetL), glycine betaine porter II (Gbu), and a carnitine transporter OpuC. We investigated the specificity of each transporter towards each osmolyte by creating mutant derivatives of L. monocytogenes 10403S that possess each of the transporters in isolation. Kinetic and steady-state osmolyte accumulation data together with growth rate experiments demonstrated that osmotically activated glycine betaine transport is readily and effectively mediated by Gbu and BetL and to a lesser extent by OpuC. Osmotically stimulated carnitine transport was demonstrated for OpuC and Gbu regardless of the nature of stressing salt. BetL can mediate weak carnitine uptake in response to NaCl stress but not KCl stress. No other transporter in L. monocytogenes 10403S appears to be involved in osmotically stimulated transport of either osmolyte, since a triple mutant strain yielded neither transport nor accumulation of glycine betaine or carnitine and could not be rescued by either osmolyte when grown under elevated osmotic stress.     

Three Transporters Mediate Uptake of Glycine Betaine and Carnitine by Listeria monocytogenes in Response to Hyperosmotic Stress

The uptake and accumulation of the potent osmolytes glycine betaine and carnitine enable the food-borne pathogen Listeria monocytogenes to proliferate in environments of elevated osmotic stress, often rendering salt-based food preservation inadequate. To date, three osmolyte transport systems are known to operate in L. monocytogenes: glycine betaine porter I (BetL), glycine betaine porter II (Gbu), and a carnitine transporter OpuC. We investigated the specificity of each transporter towards each osmolyte by creating mutant derivatives of L. monocytogenes 10403S that possess each of the transporters in isolation. Kinetic and steady-state osmolyte accumulation data together with growth rate experiments demonstrated that osmotically activated glycine betaine transport is readily and effectively mediated by Gbu and BetL and to a lesser extent by OpuC. Osmotically stimulated carnitine transport was demonstrated for OpuC and Gbu regardless of the nature of stressing salt. BetL can mediate weak carnitine uptake in response to NaCl stress but not KCl stress. No other transporter in L. monocytogenes 10403S appears to be involved in osmotically stimulated transport of either osmolyte, since a triple mutant strain yielded neither transport nor accumulation of glycine betaine or carnitine and could not be rescued by either osmolyte when grown under elevated osmotic stress.     

Ultraviolet B radiation induces cell shrinkage and increases osmolyte transporter mRNA expression and osmolyte uptake in HaCaT keratinocytes

We have previously shown that compatible organic osmolytes, such as betaine, myo-inositol and taurine, are part of the stress response of normal human keratinocytes (NHKs) to ultraviolet B (UVB) radiation. In this regard, we tested human HaCaT keratinocytes as a surrogate cell line for NHK. HaCaT cells osmo-dependently express mRNA specific for transport proteins for betaine (BGT-1), myo-inositol (SMIT) and taurine (TAUT). Compared to normoosmotic (305 mosmol/l) controls, which strongly constitutively expressed BGT-1 mRNA, strong induction of SMIT and TAUT mRNA as well as low induction of BGT-1 mRNA expression was observed between 3 and 9 h after hyperosmotic exposure (405 mosmol/l). This expression correlated with an increased osmolyte uptake. Conversely, hypoosmotic (205 mosmol/l) stimulation led to a significant efflux of osmolytes. Exposure to UVB (290-315 nm) radiation induced cell shrinkage which was followed by an upregulation of osmolyte transporter mRNA levels and osmolyte uptake. These results demonstrate that human HaCaT keratinocytes possess an osmolyte strategy including UVB-induced cell shrinkage and following increased osmolyte uptake. However, several differences in osmolyte transporter expression and uptake were noted between NHK and HaCaT cells, indicating that the use of HaCaT cells as a surrogate cell line for NHK has limitations.     

Developmentally regulated cell cycle dependence of swelling-activated anion channel activity in the mouse embryo

Anion channels activated by increased cell volume are a nearly ubiquitous mechanism of cell volume regulation, including in early preimplantation mouse embryos. Here, we show that the swelling-activated anion current (I(Cl,swell)) in early mouse embryos is cell-cycle dependent, and also that this dependence is developmentally regulated. I(Cl,swell) is present both in first meiotic prophase (germinal vesicle stage) mouse oocytes and in unfertilized mature oocytes in second meiotic metaphase, and it persists after fertilization though the 1-cell and 2-cell stages. I(Cl,swell) was found to remain unchanged during metaphase at the end of the 1-cell stage. However, I(Cl,swell) decreased during prophase and became nearly undetectable upon entry into metaphase at the end of the 2-cell stage. Entry into prophase/metaphase was required for the decrease in I(Cl,swell) at the end of the 2-cell stage, since it persisted indefinitely in 2-cell embryos arrested in late G(2). There is considerable evidence that the channel underlying I(Cl,swell) is not only permeable to inorganic anions, but to organic osmolytes as well. We found a similar pattern of cell cycle and developmental dependence in the 1-cell and 2-cell stages for the swelling-induced increase in permeability to the organic osmolyte glycine. Thus, entry into metaphase deactivates I(Cl,swell) in embryos, but only after developmental progression through the 2-cell stage.     

Cloning of a Na(+)- and Cl(-)-dependent betaine transporter that is regulated by hypertonicity.

Many hypertonic bacteria, plants, marine animals, and the mammalian renal medulla are protected from the deleterious effects of high intracellular concentrations of electrolytes by accumulating high concentrations of the nonperturbing osmolyte betaine. When kidney-derived Madin-Darby canine kidney (MDCK) cells are cultured in hypertonic medium, they accumulate betaine to 1,000 times its medium concentration. This results from induction by hypertonicity of high rates of betaine transport into cells. We have isolated a cDNA (BGT-1) encoding a renal betaine transporter by screening an MDCK cell cDNA library for expression of a betaine transporter in Xenopus oocytes. The cDNA encodes a single protein of 614 amino acids, with an estimated molecular weight of 69 kDa. The deduced amino acid sequence exhibits highly significant sequence and topographic similarity to brain gamma-amino-n-butyric acid (GABA) and noradrenaline transporters, suggesting that the renal BGT-1 is a member of the brain GABA/noradrenaline transporter gene family. Expression in oocytes indicates that the BGT-1 protein has both betaine and GABA transport activities that are Cl(-)- as well as Na(+)-dependent and functionally similar to betaine and GABA transport in MDCK cells. Northern hybridization indicates that transporter mRNA is localized to the kidney medulla and is induced in MDCK cells by hypertonicity.     

COX2 activity promotes organic osmolyte accumulation and adaptation of renal medullary interstitial cells to hypertonic stress

The mechanism by which COX2 inhibition decreases renal cell survival is poorly understood. In the present study we examined the effect of COX2 activity on organic osmolyte accumulation in renal medulla and in cultured mouse renal medullary interstitial cells (MMICs) and its role in facilitating cell survival. Hypertonicity increased accumulation of the organic osmolytes inositol, sorbitol, and betaine in cultured mouse medullary interstitial cells. Pretreatment of MMICs with a COX2-specific inhibitor (SC58236, 10 micromol/liter) dramatically reduced osmolyte accumulation (by 79 +/- 9, 57 +/- 12, and 96 +/- 10% for inositol, sorbitol, and betaine respectively, p < 0.05). Similarly, 24 h of dehydration increased inner medullary inositol, sorbitol, and betaine concentrations in vivo by 85 +/- 10, 197 +/- 28, and 190 +/- 24 pmol/microg of protein, respectively, but this increase was also blunted (by 100 +/- 5, 66 +/- 15, and 81 +/- 9% for inositol, sorbitol, and betaine, respectively, p < 0.05) by pretreatment with an oral COX2 inhibitor. Dehydrated COX2-/- mice also exhibited an impressive defect in sorbitol accumulation (88 +/- 9% less than wild type, p < 0.05) after dehydration. COX2 inhibition (COX2 inhibitor-treated or COX2-/- MMICs) dramatically reduced the expression of organic osmolyte uptake mechanisms including betaine (BGT1) and sodium-myo-inositol transporter and aldose reductase mRNA expression under hypertonic conditions. Importantly, preincubation of COX2 inhibitor-treated MMICs with organic osmolytes restored their ability to survive hypertonic stress. In conclusion, osmolyte accumulation in the kidney inner medulla is dependent on COX2 activity, and providing exogenous osmolytes reverses COX2-induced cell death. These findings may have implications for the pathogenesis of analgesic nephropathy.     

Downregulation of the osmolyte transporters SMIT and BGT1 by AMP-activated protein kinase

The myoinositol transporter SMIT (SLC5A3) and the betaine/γ-aminobutyric acid (GABA) transporter BGT1 (SLC6A12) accomplish cellular accumulation of organic osmolytes and thus contribute to cell volume regulation. Challenges of cell volume constancy include energy depletion, which compromises the function of the Na(+)/K(+) ATPase leading to cellular Na(+) accumulation and subsequent cell swelling. Energy depletion is sensed by AMP-activated protein kinase (AMPK). The present study explored whether AMPK influences the activity of SMIT and BGT1. To this end, cRNA encoding SMIT or BGT1 was injected into Xenopus oocytes with and without additional injection of wild type AMPK (AMPKα1+AMPKβ1+AMPKγ1), of constitutively active (γR70Q)AMPK (AMPKα1+AMPKβ1+(R70Q)AMPKγ1) or of catalytically inactive (αK45R)AMPK ((K45R)AMPKα1+AMPKβ1+AMPKγ1). Substrate-induced current in dual electrode voltage-clamp experiments was taken as measure of osmolyte transport. As a result, in SMIT-expressing, but not in water-injected Xenopus oocytes, myoinositol, added to the extracellular bath, generated a current (I(SMIT)), which was half maximal (K(M)) at ≈7.2μM myoinositol concentration. Furthermore, in BGT1-expressing, but not in water-injected Xenopus oocytes, GABA added to the bath generated a current (I(GABA)), which was half maximal (K(M)) at ≈0.5mM GABA concentration. Coexpression of AMPK and of (γR70Q)AMPK but not of (αK45R)AMPK significantly decreased I(SMIT) and I(GABA). AMPK decreased the respective maximal currents without significantly modifying the respective K(M). In conclusion, the AMP-activated kinase AMPK is a powerful regulator of the organic osmolyte transporters SMIT and BGT1 and thus interacts with cell volume regulation.     

Identification of an ATP-driven, osmoregulated glycine betaine transport system in Listeria monocytogenes.

The ability of the gram-positive, food-borne pathogen Listeria monocytogenes to tolerate environments of elevated osmolarity and reduced temperature is due in part to the transport and accumulation of the osmolyte glycine betaine. Previously we showed that glycine betaine transport was the result of Na(+)-glycine betaine symport. In this report, we identify a second glycine betaine transporter from L. monocytogenes which is osmotically activated but does not require a high concentration of Na(+) for activity. By using a pool of Tn917-LTV3 mutants, a salt- and chill-sensitive mutant which was also found to be impaired in its ability to transport glycine betaine was isolated. DNA sequence analysis of the region flanking the site of transposon insertion revealed three open reading frames homologous to opuA from Bacillus subtilis and proU from Escherichia coli, both of which encode glycine betaine transport systems that belong to the superfamily of ATP-dependent transporters. The three open reading frames are closely spaced, suggesting that they are arranged in an operon. Moreover, a region upstream from the first reading frame was found to be homologous to the promoter regions of both opuA and proU. One unusual feature not shared with these other two systems is that the start codons for two of the open reading frames in L. monocytogenes appear to be TTG. That glycine betaine uptake is nearly eliminated in the mutant strain when it is assayed in the absence of Na(+) is an indication that only the ATP-dependent transporter and the Na(+)-glycine betaine symporter occur in L. monocytogenes.     

JAK2 mediates the acute response to decreased cell volume in mouse preimplantation embryos by activating NHE1

Preimplantation mouse embryos are particularly sensitive to increased osmolarity within their normal physiological range. The detrimental effects can be alleviated by organic osmolytes such as glycine transported into early embryos, an effect thought to be due to the organic osmolyte replacing a portion of intracellular inorganic ions accumulated during acute cell volume regulation. However, no mechanism of cell volume regulation dependent on inorganic ions has been identified in preimplantation embryos. We found that decreased cell volume rapidly activated Na⁺/H⁺ exchange in preimplantation mouse embryos. This activity was likely mediated by the NHE1 (Slc9a1) isoform, since it was blocked by the highly selective NHE1 inhibitor, cariporide, which also inhibited the ability of the 1‐cell embryo to maintain cell volume. How NHE1 is activated by decreased cell volume is not generally well understood. Full activation of NHE1 by decreased cell volume in 2‐cell mouse embryos required the activity of the tyrosine kinase Janus kinase 2 (Jak2), since NHE1 activation was inhibited by the general tyrosine kinase inhibitor genistein, several selective inhibitors of Jak2, and dominant negative Jak2 expressed in 2‐cell embryos. Decreased cell volume furthermore resulted in increased tyrosine phosphorylation of proteins in 2‐cell embryos detected both by anti‐phosphotyrosine antibody and an antibody directed against active phospho‐Jak2. Thus, Jak2 apparently serves as a cell volume sensor in embryos. Evidence from pharmacological inhibitors further indicated that NHE1 activation by decreased cell volume was dependent on calmodulin activity, likely downstream of Jak2, and required active phospholipase C. J. Cell. Physiol. 228: 428–438, 2013. © 2012 Wiley Periodicals, Inc.     

Mouse embryos stressed by physiological levels of osmolarity become arrested in the late 2-cell stage before entry into M phase

Preimplantation mouse embryos of many strains become arrested at the 2-cell stage if the osmolarity of culture medium that normally supports development to blastocysts is raised to approximately that of their normal physiological environment in the oviduct. Arrest can be prevented if molecules that serve as "organic osmolytes" are present in the medium, because organic osmolytes, principally glycine, are accumulated by embryos to provide intracellular osmotic support and regulate cell volume. Medium with an osmolarity of 310 mOsM induced arrest of approximately 80% of CF1 mouse embryos at the 2-cell stage, in contrast to the approximately 100% that progressed beyond the 2-cell stage at 250 or 301 mOsM with glycine. The nature of this arrest induced by physiological levels of osmolarity is unknown. Arrest was reversible by transfer to lower-osmolarity medium at any point during the 2-cell stage, but not after embryos would normally have progressed to the 4-cell stage. Cessation of development likely was not due to apoptosis, as shown by lack of external annexin V binding, detectable cytochrome c release from mitochondria, or nuclear DNA fragmentation. Two-cell embryos cultured at 310 mOsM progressed through the S phase, and zygotic genome activation markers were expressed. However, most embryos failed to initiate the M phase, as evidenced by intact nuclei with decondensed chromosomes, low M-phase promoting factor activity, and an inactive form of CDK1, although a few blastomeres were arrested in metaphase. Thus, embryos become arrested late in the G(2) stage of the second embryonic cell cycle when stressed by physiological osmolarity in the absence of organic osmolytes.     

The methanogenic archaeon Methanosarcina thermophila TM-1 possesses a high-affinity glycine betaine transporter involved in osmotic adaptation.

Methanogenic Archaea are found in a wide range of environments and use several strategies to adjust to changes in extracellular solute concentrations. One methanogenic archaeon, Methanosarcina thermophila TM-1, can adapt to various osmotic conditions by synthesis of alpha-glutamate and a newly discovered compatible solute, Ne-acetyl-beta-lysine, or by accumulation of glycine betaine (betaine) and potassium ions from the environment. Since betaine transport has not been characterized for any of the methanogenic Archaea, we examined the uptake of this solute by M. thermophila TM-1. When cells were grown in mineral salts media containing from 0.1 to 0.8 M NaC1, M. thermophila accumulated betaine in concentrations up to 140 times those of a concentration gradient within 10 min of exposure to the solute. The betaine uptake system consisted of a single, high-affinity transporter with an apparent K3 of 10 microM and an apparent maximum transport velocity of 1.15 nmol/min/mg of protein. The transporter appeared to be specific for betaine, since potential substrates, including glycine, sarcosine, dimethyl glycine, choline, and proline, did not significantly inhibit betaine uptake. M. thermophila TM-1 cells can also regulate the capacity for betaine accumulation, since the rate of betaine transport was reduced in cells pregrown in a high-osmolarity medium when 500 microM betaine was present. Betaine transport appears to be H+ and/or Na+ driven, since betaine transport was inhibited by several types of protonophores and sodium ionophores.     

Dissecting the roles of osmolyte accumulation during stress

Many plants accumulate organic osmolytes in response to the imposition of environmental stresses that cause cellular dehydration. Although an adaptive role for these compounds in mediating osmotic adjustment and protecting subcellular structure has become a central dogma in stress physiology, the evidence in favour of this hypothesis is largely correlative. Transgenic plants engineered to accumulate proline, mannitol, fructans, trehalose, glycine betaine or ononitol exhibit marginal improvements in salt and/or drought tolerance. While these studies do not dismiss causative relationships between osmolyte levels and stress tolerance, the absolute osmolyte concentrations in these plants are unlikely to mediate osmotic adjustment. Metabolic benefits of osmolyte accumulation may augment the classically accepted roles of these compounds. In re-assessing the functional significance of compatible solute accumulation, it is suggested that proline and glycine betaine synthesis may buffer cellular redox potential. Disturbances in hexose sensing in transgenic plants engineered to produce trehalose, fructans or mannitol may be an important contributory factor to the stress-tolerant phenotypes observed. Associated effects on photoassimilate allocation between root and shoot tissues may also be involved. Whether or not osmolyte transport between subcellular compartments or different organs represents a bottleneck that limits stress tolerance at the whole-plant level is presently unclear. None the less, if osmolyte metabolism impinges on hexose or redox signalling, then it may be important in long-range signal transmission throughout the plant.     

Glucose transporter gene expression in early mouse embryos.

The glucose transporter (GLUT) isoforms responsible for glucose uptake in early mouse embryos have been identified. GLUT 1, the isoform present in nearly every tissue examined including adult brain and erythrocytes, is expressed throughout preimplantation development. GLUT 2, which is normally present in adult liver, kidney, intestine and pancreatic beta cells is expressed from the 8-cell stage onward. GLUT 4, an insulin-recruitable isoform, which is expressed in adult fat and muscle, is not expressed at any stage of preimplantation development or in early postimplantation stage embryos. Genetic mapping studies of glucose transporters in the mouse show that Glut-1 is located on chromosome 4, Glut-2 on chromosome 3, Glut-3 on chromosome 6, and Glut-4 on chromosome 11.