ABSTRACT
Glucose enters eucaryotic cells via 2 different types of membrane associated carrier proteins, the Na+-coupled glucose transporters (SGLT) and glucose transporter facilitators (GLUT). Three members of the SGLT family function as sugar transporters (SGLT1 and SGLT2) or sensors (SGLT3). The human GLUT family consists of 14 members, of which 11 have been shown to catalyze sugar transport. The individual isotypes exhibit different substrate specificity, kinetic characteristics, and expression profiles, thereby allowing a tissue-specific adaptation of glucose uptake through regulation of their gene expression. Furthermore, some transporters (eg, GLUT4 and GLUT8) are regulated by their subcellular distribution. In addition to catalyzing glucose entry into cells, some isotypes (eg, GLUT2) seem to be involved in the mechanisms of glucosensing of pancreatic beta-cells, neuronal, or other cells, thereby playing a major role in the hormonal and neural control. Targeted disruption in mice has helped to elucidate the physiologic function of some isotypes (GLUT1, GLUT2, GLUT4). Furthermore, several congenital defects of sugar metabolism are caused by aberrant transporter genes (eg, the glucose-galactose malabsorption syndrome, SGLT1; the glucose transporter 1 deficiency syndrome; and the Fanconi-Bickel syndrome, GLUT2). In addition, a malfunction of glucose transporter expression or regulation (GLUT4) appears to contribute to the insulin resistance syndrome.
Subject(s)
Biological Transport, Active/physiology , Glucose/metabolism , Monosaccharide Transport Proteins/physiology , Animals , Gene Expression Regulation , Humans , Mice , Monosaccharide Transport Proteins/metabolism , Protein Isoforms , Signal TransductionABSTRACT
ADP-ribosylation factor-related protein 1 (ARFRP1) plays a specific role in Golgi function controlling recruitment of GRIP domain proteins and ARL1 to the trans-Golgi. Deletion of the mouse Arfrp1 gene causes embryonic lethality during early gastrulation, because epiblast cells detach from the ectodermal cell layer and do not differentiate to mesodermal tissue. Here we show that in Arfrp1(-/-) embryos E-cadherin is mistargeted to intracellular compartments, whereas in control embryos it is present at the cell surface of trophectodermal and ectodermal cells. In enterocytes of intestine-specific Arfrp1 null mutants (Arfrp1(vil)(-/-)), E-cadherin is associated with intracellular membranes, partially colocalizing with the cis-Golgi marker GM130 or with punctae close to the cell surface. In contrast, in control enterocytes E-cadherin is exclusively located in the lateral membranes. In addition, ARL1 is dislocated from Golgi membranes to the cytosol of Arfrp1(vil)(-/-) enterocytes. Depletion of endogenous ARFRP1 by RNA interference leads to a dislocation of E-cadherin from the cell surface in HeLa cells and to a reduced cell aggregation in Ltk(-)Ecad cells. ARFRP1 was coimmunoprecipitated in a complex with E-cadherin, alpha-catenin, beta-catenin, gamma-catenin, and p120(ctn) from lysates of Madin-Darby canine kidney cells stably expressing myc-ARFRP1. These data indicate that knock-out of Arfrp1 disrupts the trafficking of E-cadherin through the Golgi and suggest an essential role of the GTPase in trans-Golgi network function.
Subject(s)
ADP-Ribosylation Factors/metabolism , Cadherins/metabolism , Cell Membrane/metabolism , Golgi Apparatus/metabolism , ADP-Ribosylation Factors/genetics , Animals , Cadherins/genetics , Catenins/genetics , Catenins/metabolism , Cell Differentiation/physiology , Cell Membrane/genetics , Dogs , Ectoderm/metabolism , Embryo Loss/genetics , Embryo Loss/metabolism , Enterocytes/metabolism , Golgi Apparatus/genetics , HeLa Cells , Humans , Mesoderm/metabolism , Mice , Mice, Knockout , Protein Transport/physiology , RNA InterferenceABSTRACT
GLUT8 is a class 3 sugar transport facilitator which is predominantly expressed in testis and also detected in brain, heart, skeletal muscle, adipose tissue, adrenal gland, and liver. Since its physiological function in these tissues is unknown, we generated a Slc2a8 null mouse and characterized its phenotype. Slc2a8 knockout mice appeared healthy and exhibited normal growth, body weight development and glycemic control, indicating that GLUT8 does not play a significant role for maintenance of whole body glucose homeostasis. However, analysis of the offspring distribution of heterozygous mating indicated a lower number of Slc2a8 knockout offspring (30.5:47.3:22.1%, Slc2a8(+/+), Slc2a8(+/-), and Slc2a8(-/-) mice, respectively) resulting in a deviation (p=0.0024) from the expected Mendelian distribution. This difference was associated with lower ATP levels, a reduced mitochondrial membrane potential and a significant reduction of sperm motility of the Slc2a8 knockout in comparison to wild-type spermatozoa. In contrast, number and survival rate of spermatozoa were not altered. These data indicate that GLUT8 plays an important role in the energy metabolism of sperm cells.
Subject(s)
Glucose Transport Proteins, Facilitative/deficiency , Sperm Motility/physiology , Spermatozoa/metabolism , Adenosine Triphosphate/metabolism , Amino Acid Sequence , Animals , Base Sequence , DNA Primers/genetics , DNA, Complementary/genetics , Energy Metabolism , Female , Gene Targeting , Glucose Transport Proteins, Facilitative/genetics , Glucose Transport Proteins, Facilitative/physiology , Heterozygote , Immunohistochemistry , Male , Membrane Potential, Mitochondrial , Mice , Mice, Inbred C57BL , Mice, Knockout , Microscopy, Electron, Transmission , Molecular Sequence Data , Testis/metabolism , Testis/ultrastructureABSTRACT
GLUT11 (SLC2A11) is a class II sugar transport facilitator which exhibits highest similarity with the fructose transporter GLUT5 (about 42%). Here we demonstrate that separate exons 1 (exon 1A, exon 1B, and exon 1C) of the SLC2A11 gene generate mRNAs of three GLUT11 variants (GLUT11-A, GLUT11-B, and GLUT11-C) that differ in the amino acid sequence of their N-termini. All three 5'-flanking regions of exon 1A, exon 1B and exon 1C exhibited promoter activity when expressed as luciferase fusion constructs in COS-7 cells. 5'-RACE-PCR, quantitative real-time PCR, and Northern blot analysis performed with specific probes for exon 1A, 1B and 1C demonstrated that GLUT11-A is expressed in heart, skeletal muscle, and kidney, GLUT11-B in kidney, adipose tissue, and placenta, and GLUT11-C in adipose tissue, heart, skeletal muscle, and pancreas. Surprisingly, mice and rats lack the SLC2A11 gene. When expressed in Xenopus oocytes, all three GLUT11 isoforms transport glucose and fructose but not galactose. There was no apparent difference in the subcellular distribution of the three isoforms expressed in COS-7 cells. Our data indicate that different promoters and splicing of the human SLC2A11 gene generate three GLUT11 isoforms which are expressed in a tissue specific manner but do not appear to differ in their functional characteristics.
Subject(s)
Gene Expression Regulation/physiology , Glucose Transport Proteins, Facilitative/genetics , Glucose Transport Proteins, Facilitative/metabolism , Promoter Regions, Genetic , Alternative Splicing , Animals , COS Cells , Chlorocebus aethiops , Exons/genetics , Glucose/metabolism , Glucose Transport Proteins, Facilitative/biosynthesis , Glucose Transport Proteins, Facilitative/physiology , Humans , Mice , Organ Specificity/genetics , Protein Isoforms/biosynthesis , Protein Isoforms/genetics , Protein Isoforms/metabolism , Protein Isoforms/physiology , Protein Transport/genetics , RNA, Messenger/genetics , Rats , Sequence Homology, Nucleic Acid , Subcellular Fractions/metabolism , Substrate Specificity/genetics , Transcription, Genetic , Xenopus laevisABSTRACT
The glucose transporter 8 (GLUT8) is a recently identified member of the family of sugar transport facilitators. In human tissues GLUT8 is predominantly expressed in testis in a gonadotropin-dependent manner. It is shown here that the onset of mRNA synthesis of GLUT8 during the maturation of mouse testis coincides with the appearance of mature spermatozoa. Furthermore, immunohistochemistry with antiserum against the C-terminus of GLUT8 indicated that the protein was associated with spermatozoa within the seminiferous and the epididymal tubules. The GLUT8 immunoreactivity was detected within the head of mouse and human spermatozoa in the acrosomal region, and appeared to be located at the plasma membrane as well as within the cells. This specific expression and localization of GLUT8 suggests that the transport facilitator plays a major role in the fuel supply of mature spermatozoa, and that it is a potential target for inhibition of sperm cell function.