Loss of LAT1 sex-dependently delays recovery after caerulein-induced acute pancreatitis

Background: The expression of amino acid transporters is known to vary during acute pancreatitis (AP) except for LAT1 (slc7a5), the expression of which remains stable. LAT1 supports cell growth by importing leucine and thereby stimulates mammalian target of rapamycin (mTOR) activity, a phenomenon often observed in cancer cells. The mechanisms by which LAT1 influences physiological and pathophysiological processes and affects disease progression in the pancreas are not yet known. Aim: To evaluate the role of LAT1 in the development of and recovery from AP. Methods: AP was induced with caerulein (cae) injections in female and male mice expressing LAT1 or after its knockout (LAT1 Cre/LoxP). The development of the initial AP injury and its recovery were followed for seven days after cae injections by daily measuring body weight, assessing microscopical tissue architecture, mRNA and protein expression, protein synthesis, and enzyme activity levels, as well as by testing the recruitment of immune cells by FACS and ELISA. Results: The initial injury, evaluated by measurements of plasma amylase, lipase, and trypsin activity, as well as the gene expression of dedifferentiation markers, did not differ between the groups. However, early metabolic adaptations that support regeneration at later stages were blunted in LAT1 knockout mice. Especially in females, we observed less mTOR reactivation and dysfunctional autophagy. The later regeneration phase was clearly delayed in female LAT1 knockout mice, which did not regain normal expression of the pancreas-specific differentiation markers recombining binding protein suppressor of hairless-like protein (rbpjl) and basic helix-loop-helix family member A15 (mist1). Amylase mRNA and protein levels remained lower, and, strikingly, female LAT1 knockout mice presented signs of fibrosis lasting until day seven. In contrast, pancreas morphology had returned to normal in wild-type littermates. Conclusion: LAT1 supports the regeneration of acinar cells after AP. Female mice lacking LAT1 exhibited more pronounced alterations than male mice, indicating a sexual dimorphism of amino acid metabolism

The catalytic subunit of the system L1 amino acid transporter (S<i>lc7a5</i>) facilitates nutrient signalling in mouse skeletal muscle

The System L1-type amino acid transporter mediates transport of large neutral amino acids (LNAA) in many mammalian cell-types. LNAA such as leucine are required for full activation of the mTOR-S6K signalling pathway promoting protein synthesis and cell growth. The SLC7A5 (LAT1) catalytic subunit of high-affinity System L1 functions as a glycoprotein-associated heterodimer with the multifunctional protein SLC3A2 (CD98). We generated a floxed Slc7a5 mouse strain which, when crossed with mice expressing Cre driven by a global promoter, produced Slc7a5 heterozygous knockout (Slc7a5+/-) animals with no overt phenotype, although homozygous global knockout of Slc7a5 was embryonically lethal. Muscle-specific (MCK Cre-mediated) Slc7a5 knockout (MS-Slc7a5-KO) mice were used to study the role of intracellular LNAA delivery by the SLC7A5 transporter for mTOR-S6K pathway activation in skeletal muscle. Activation of muscle mTOR-S6K (Thr389 phosphorylation) in vivo by intraperitoneal leucine injection was blunted in homozygous MS-Slc7a5-KO mice relative to wild-type animals. Dietary intake and growth rate were similar for MS-Slc7a5-KO mice and wild-type littermates fed for 10 weeks (to age 120 days) with diets containing 10%, 20% or 30% of protein. In MS-Slc7a5-KO mice, Leu and Ile concentrations in gastrocnemius muscle were reduced by ∼40% as dietary protein content was reduced from 30 to 10%. These changes were associated with >50% decrease in S6K Thr389 phosphorylation in muscles from MS-Slc7a5-KO mice, indicating reduced mTOR-S6K pathway activation, despite no significant differences in lean tissue mass between groups on the same diet. MS-Slc7a5-KO mice on 30% protein diet exhibited mild insulin resistance (e.g. reduced glucose clearance, larger gonadal adipose depots) relative to control animals. Thus, SLC7A5 modulates LNAA-dependent muscle mTOR-S6K signalling in mice, although it appears non-essential (or is sufficiently compensated by e.g. SLC7A8 (LAT2)) for maintenance of normal muscle mass

Dysfunctional LAT2 amino acid transporter is associated with cataract in mouse and humans

Cataract, the loss of ocular lens transparency, accounts for ∼50% of worldwide blindness and has been associated with water and solute transport dysfunction across lens cellular barriers. We show that neutral amino acid antiporter LAT2 (Slc7a8) and uniporter TAT1 (Slc16a10) are expressed on mouse ciliary epithelium and LAT2 also in lens epithelium. Correspondingly, deletion of LAT2 induced a dramatic decrease in lens essential amino acid levels that was modulated by TAT1 defect. Interestingly, the absence of LAT2 led to increased incidence of cataract in mice, in particular in older females, and a synergistic effect was observed with simultaneous lack of TAT1. Screening SLC7A8 in patients diagnosed with congenital or age-related cataract yielded one homozygous single nucleotide deletion segregating in a family with congenital cataract. Expressed in HeLa cells, this LAT2 mutation did not support amino acid uptake. Heterozygous LAT2 variants were also found in patients with cataract some of which showed a reduced transport function when expressed in HeLa cells. Whether heterozygous LAT2 variants may contribute to the pathology of cataract needs to be further investigated. Overall, our results suggest that defects of amino acid transporter LAT2 are implicated in cataract formation, a situation that may be aggravated by TAT1 defects

La voie ERK1/2 : point d’intégration et de convergence des connexions entre voies de signalisation dans les cellules épithéliales de prostate normale

Prostate development and cell homeostasis involve strict control of androgen and growth factors induced signaling pathways. These signaling pathways are deeply altered in prostate cancer, especially during late stages. In this work, the RWPE-1 immortalized cell line derived from human prostate epithelium has been used to study the signaling pathways regulating cell proliferation and their crosstalk. Optimal RWPE-1 proliferation is dependent on EGF (Epidermal Growth Factor), that also controls normal epithelial development. EGF-R family is also involved in cancer cell proliferation. EGF-dependent RWPE- 1 cell proliferation relies strictly on the ERK1/2 pathway which is then seen as a signal integrating node. Specific inhibitors showed essential role of androgen receptor in EGF mediated ERK1/2 activation. Androgen receptor is associated with several signaling molecules in RWPE-1 cells. I show here for the first time the physical interaction between the androgen receptor and the ERK1/2 activating kinase Raf1. Then, the androgen receptor could directly regulate an essential pathway for epithelial cells proliferation through a non-genomic mechanism. In addition, I showed that IL-6 dependent RWPE-1 cells proliferation requires both ERK1/2 and EGF-R kinase activities, suggesting an IL-6 mediated transactivation of EGF-R. By using several inhibitors, I showed that ADAM (a disintegrin and metalloprotease) family metaloproteases, especialy ADAM17, are involved in this process. IL-6-mediated ADAM proteins activation could lead to the cleavage of a membrane bound EGF-R ligand, leading to ERK1/2 pathway activation. This new mechanism could be involved in the inflammatory situations inducing hyperproliferation of the prostate epithelium, the first step of the transformation process. To conclude, the signaling pathways I studied are strongly connected in normal epithelial cells. The two new mechanisms described in this study lead to ERK1/2 kinases activation, an integrating node of signaling pathways in normal prostate epithelial cells.Le développement et l’homéostasie cellulaire de la prostate impliquent le contrôle strict des voies de signalisation induites par les androgènes et les facteurs de croissance. Ces diverses voies sont profondément altérées dans le cancer de la prostate, notamment lors des stades les plus avancés. Dans ce travail, une lignée immortalisée à partir de l’épithélium de prostate humaine, la lignée RWPE-1, a été utilisée pour étudier certains signaux régulant la prolifération cellulaire, ainsi que les connexions entre les voies de signalisation correspondantes. La prolifération des cellules RWPE-1 est sous la dépendance de l’EGF (Epidermal Growth Factor) qui intervient physiologiquement dans le développement épithélial. Les récepteurs apparentés à l’EGF-R sont également impliqués dans la prolifération au cours de la progression tumorale. La prolifération des cellules RWPE-1 en réponse à l’EGF est strictement dépendante de la voie ERK1/2, qui est donc considérée comme un point d’intégration des signaux. L’utilisation d’inhibiteurs du récepteur aux androgènes a permis de montrer le rôle essentiel qu’il joue dans l’activation d’ERK1/2 en réponse à l’EGF. Le récepteur aux androgènes s’associe avec plusieurs molécules de signalisation dans les cellules RWPE-1. Je démontre ici pour la première fois une association entre le récepteur aux androgènes et la kinase Raf-1, activatrice de la voie ERK1/2. Ainsi, le récepteur aux androgènes contrôlerait directement un processus essentiel à la prolifération épithéliale selon un mode d’action non-génomique. Par ailleurs, j’ai montré que la réponse proliférative des cellules RWPE-1 à l’IL-6 requiert l’activation de la voie ERK1/2, et l’activité kinase de l’EGF-R, suggérant la transactivation de ce récepteur par l’IL-6. L’utilisation de divers inhibiteurs chimiques a permis de démontrer que les métalloprotéases de la famille ADAM (a disintegrin and metalloprotease), notamment ADAM17, sont impliquées dans ce processus. Ainsi, l’activation de protéines ADAM par l’IL-6 conduirait au clivage d’un ligand membranaire de l’EGF-R, aboutissant à l’activation de la voie ERK1/2. Ce nouveau mécanisme pourrait être impliqué dans les situations inflammatoires conduisant à une prolifération excessive de l’épithélium prostatique, prélude à la transformation tumorale. En conclusion, les voies de signalisation étudiées sont fortement connectées dans les cellules épithéliales normales. Les deux nouveaux mécanismes décrits ici aboutissent à l’activation des kinases ERK1/2, point d’intégration et de convergence des voies de signalisation dans les cellules épithéliales de prostate normale

ERK1/2 pathway : an integrating node of converging signaling pathways in normal prostate epithelial cells.

Le développement et l’homéostasie cellulaire de la prostate impliquent le contrôle strict des voies de signalisation induites par les androgènes et les facteurs de croissance. Ces diverses voies sont profondément altérées dans le cancer de la prostate, notamment lors des stades les plus avancés. Dans ce travail, une lignée immortalisée à partir de l’épithélium de prostate humaine, la lignée RWPE-1, a été utilisée pour étudier certains signaux régulant la prolifération cellulaire, ainsi que les connexions entre les voies de signalisation correspondantes. La prolifération des cellules RWPE-1 est sous la dépendance de l’EGF (Epidermal Growth Factor) qui intervient physiologiquement dans le développement épithélial. Les récepteurs apparentés à l’EGF-R sont également impliqués dans la prolifération au cours de la progression tumorale. La prolifération des cellules RWPE-1 en réponse à l’EGF est strictement dépendante de la voie ERK1/2, qui est donc considérée comme un point d’intégration des signaux. L’utilisation d’inhibiteurs du récepteur aux androgènes a permis de montrer le rôle essentiel qu’il joue dans l’activation d’ERK1/2 en réponse à l’EGF. Le récepteur aux androgènes s’associe avec plusieurs molécules de signalisation dans les cellules RWPE-1. Je démontre ici pour la première fois une association entre le récepteur aux androgènes et la kinase Raf-1, activatrice de la voie ERK1/2. Ainsi, le récepteur aux androgènes contrôlerait directement un processus essentiel à la prolifération épithéliale selon un mode d’action non-génomique. Par ailleurs, j’ai montré que la réponse proliférative des cellules RWPE-1 à l’IL-6 requiert l’activation de la voie ERK1/2, et l’activité kinase de l’EGF-R, suggérant la transactivation de ce récepteur par l’IL-6. L’utilisation de divers inhibiteurs chimiques a permis de démontrer que les métalloprotéases de la famille ADAM (a disintegrin and metalloprotease), notamment ADAM17, sont impliquées dans ce processus. Ainsi, l’activation de protéines ADAM par l’IL-6 conduirait au clivage d’un ligand membranaire de l’EGF-R, aboutissant à l’activation de la voie ERK1/2. Ce nouveau mécanisme pourrait être impliqué dans les situations inflammatoires conduisant à une prolifération excessive de l’épithélium prostatique, prélude à la transformation tumorale. En conclusion, les voies de signalisation étudiées sont fortement connectées dans les cellules épithéliales normales. Les deux nouveaux mécanismes décrits ici aboutissent à l’activation des kinases ERK1/2, point d’intégration et de convergence des voies de signalisation dans les cellules épithéliales de prostate normale.Prostate development and cell homeostasis involve strict control of androgen and growth factors induced signaling pathways. These signaling pathways are deeply altered in prostate cancer, especially during late stages. In this work, the RWPE-1 immortalized cell line derived from human prostate epithelium has been used to study the signaling pathways regulating cell proliferation and their crosstalk. Optimal RWPE-1 proliferation is dependent on EGF (Epidermal Growth Factor), that also controls normal epithelial development. EGF-R family is also involved in cancer cell proliferation. EGF-dependent RWPE- 1 cell proliferation relies strictly on the ERK1/2 pathway which is then seen as a signal integrating node. Specific inhibitors showed essential role of androgen receptor in EGF mediated ERK1/2 activation. Androgen receptor is associated with several signaling molecules in RWPE-1 cells. I show here for the first time the physical interaction between the androgen receptor and the ERK1/2 activating kinase Raf1. Then, the androgen receptor could directly regulate an essential pathway for epithelial cells proliferation through a non-genomic mechanism. In addition, I showed that IL-6 dependent RWPE-1 cells proliferation requires both ERK1/2 and EGF-R kinase activities, suggesting an IL-6 mediated transactivation of EGF-R. By using several inhibitors, I showed that ADAM (a disintegrin and metalloprotease) family metaloproteases, especialy ADAM17, are involved in this process. IL-6-mediated ADAM proteins activation could lead to the cleavage of a membrane bound EGF-R ligand, leading to ERK1/2 pathway activation. This new mechanism could be involved in the inflammatory situations inducing hyperproliferation of the prostate epithelium, the first step of the transformation process. To conclude, the signaling pathways I studied are strongly connected in normal epithelial cells. The two new mechanisms described in this study lead to ERK1/2 kinases activation, an integrating node of signaling pathways in normal prostate epithelial cells

Anticipation of food intake induces phosphorylation switch to regulate basolateral amino acid transporter LAT4 (SLC43A2) function

KEY POINTS : Amino acid absorption requires luminal uptake into and subsequent basolateral efflux out of epithelial cells, with the latter step being critical to regulate the intracellular concentration of the amino acids. The basolateral essential neutral amino acid uniporter LAT4 (SLC43A2) has been suggested to drive the net efflux of non-essential and cationic amino acids via parallel amino acid antiporters by recycling some of their substrates; its deletion has been shown to cause defective postnatal growth and death in mice. Here we test the regulatory function of LAT4 phosphorylation sites by mimicking their phosphorylated and dephosphorylated states in Xenopus laevis oocytes and show that dephosphorylation of S274 and phosphorylation of S297 increase LAT4 membrane localization and function. Using new phosphorylation site-specific antibodies, we observe changes in LAT4 phosphorylation in mouse small intestine that correspond to its upregulation at the expected feeding time. These results strongly suggest that LAT4 phosphorylation participates in the regulation of transepithelial amino acid absorption. ABSTRACT : The essential amino acid uniporters LAT4 and TAT1 are located at the basolateral side of intestinal and kidney epithelial cells and their transport function has been suggested to control the transepithelial (re)absorption of neutral and possibly also cationic amino acids. Uniporter LAT4 selectively transports the branched chain amino acids leucine, isoleucine and valine, and additionally methionine and phenylalanine. Its deletion leads to a postnatal growth failure and early death in mice. Since LAT4 has been reported to be phosphorylated in vivo, we hypothesized that phosphorylation regulates its function. Using Xenopus laevis oocytes, we tested the impact of LAT4 phosphorylation at Ser274 and Ser297 by expressing mutant constructs mimicking phosphorylated and dephosphorylated states. We then investigated the in vivo regulation of LAT4 in mouse small intestine using new phosphorylation site-specific antibodies and a time-restricted diet. In Xenopus oocytes, mimicking non-phosphorylation of Ser274 led to an increase in affinity and apparent surface membrane localization of LAT4, stimulating its transport activity, while the same mutation of Ser297 decreased LAT4's apparent surface expression and transport rate. In wild-type mice, LAT4 phosphorylation on Ser274 was uniform at the beginning of the inactive phase (ZT0). In contrast, at the beginning of the active phase (ZT12), corresponding to the anticipated feeding time, Ser274 phosphorylation was decreased and restricted to relatively large patches of cells, while Ser297 phosphorylation was increased. We conclude that phosphorylation of small intestinal LAT4 is under food-entrained circadian control, leading presumably to an upregulation of LAT4 function at the anticipated feeding time

Tissue-specific deletion of mouse basolateral uniporter LAT4 (Slc43a2) reveals its crucial role in small intestine and kidney amino acid transport

KEY POINTS LAT4 is a broadly expressed uniporter selective for essential branched chain amino acids, methionine and phenylalanine, which are involved in epithelial transport. Its global deletion leads to an early malnutrition-like phenotype and death within 10 days after birth. Here, we tested the impact of deleting LAT4 selectively in the mouse intestine. This affected slightly the absorption of amino acids (AAs) and delayed gastrointestinal motility; however, it had no major phenotypic effect, even when combined with aromatic AA uniporter TAT1 knockout (KO). Conversely, kidney tubule-selective deletion of LAT4 led to a substantial aminoaciduria that strongly increased under a high protein diet. Combining a partial tubular LAT4 deletion with TAT1 KO implicated their synergistic action on AA reabsorption. These results show that LAT4 plays an important role for kidney AA reabsorption, but that its functional role in intestinal AA absorption is largely dispensable. ABSTRACT Amino acid (AA) transporter LAT4 (Slc43a2) functions as facilitated diffusion uniporter for essential neutral AAs and is highly expressed at the basolateral membrane of small intestine (SI) and kidney tubule epithelia. Previously, we showed that LAT4 global knockout (KO) mice were born at the expected Mendelian ratio but died within 10 days. Their failure to gain weight and a severe malnutrition-like phenotype contrasted with apparently normal feeding, suggesting a severe intestinal AA absorption defect. In the present study, using conditional global and tissue-specific LAT4 KO mouse models, we nullified this hypothesis, demonstrating that the selective lack of intestinal LAT4 does not impair postnatal development, although it leads to an absorption defect accompanied by delayed gastrointestinal motility. Kidney tubule-specific LAT4 KO led to a substantial aminoaciduria as a result of a reabsorption defect of AAs transported by LAT4 and of other AAs that are substrates of the antiporter LAT2, demonstrating, in vivo, the functional co-operation of these two transporters. The major role played by basolateral uniporters in the kidney was further supported by the observation that, in mice lacking TAT1, another neutral AA uniporter, a partial LAT4 KO led to a synergistic increase of urinary AA loss. Surprisingly in the SI, the same combined KO induced no major effect, suggesting yet unknown compensatory mechanisms. Taken together, the lethal malnutrition-like phenotype observed previously in LAT4 global KO pups is suggested to be the consequence of a combinatorial effect of LAT4 deletion in the SI, kidney and presumably other tissues

Phosphorylation of mouse intestinal basolateral amino acid uniporter LAT4 is controlled by food-entrained diurnal rhythm and dietary proteins

Adaptive regulation of epithelial transporters to nutrient intake is essential to decrease energy costs of their synthesis and maintenance, however such regulation is understudied. Previously we demonstrated that the transport function of the basolateral amino acid uniporter LAT4 (Slc43a2) is increased by dephosphorylation of serine 274 (S274) and nearly abolished by dephosphorylation of serine 297 (S297) when expressed in Xenopus oocytes. Phosphorylation changes in the jejunum of food-entrained mice suggested an increase in LAT4 transport function during food expectation. Thus, we investigated further how phosphorylation, expression and localization of mouse intestinal LAT4 respond to food-entrained diurnal rhythm and dietary protein content. In mice entrained with 18% protein diet, LAT4 mRNA was not submitted to diurnal regulation, unlike mRNAs of luminal symporters and antiporters. Only in duodenum, LAT4 protein expression increased during food intake. Concurrently, S274 phosphorylation was decreased in all three small intestinal segments, whereas S297 phosphorylation was increased only in jejunum. Interestingly, during food intake, S274 phosphorylation was nearly absent in ileum and accompanied by strong phosphorylation of mTORC1 target S6. Entraining mice with 8% protein diet provoked a shift in jejunal LAT4 localization from the cell surface to intracellular stores and increased S274 phosphorylation in both jejunum and ileum during food anticipation, suggesting decreased transport function. In contrast, 40% dietary protein content led to increased LAT4 expression in jejunum and its internalization in ileum. Ex vivo treatments of isolated intestinal villi fraction demonstrated that S274 phosphorylation was stimulated by protein kinase A. Rapamycin-sensitive insulin treatment and amino acids increased S297 phosphorylation, suggesting that the response to food intake might be regulated via the insulin-mTORC1 pathway. Ghrelin, an oscillating orexigenic hormone, did not affect phosphorylation of intestinal LAT4. Overall, we show that phosphorylation, expression and localization of intestinal mouse LAT4 responds to diurnal and dietary stimuli in location-specific manner