Dynamics of insulin-stimulated translocation of GLUT4 in single living cells visualised using green fluorescent protein.

Insulin increases glucose uptake by promoting the translocation of the GLUT4 isoform of glucose transporters to the plasma membrane. We have studied this process in living single cells by fusing green fluorescent protein (GFP) to the N-terminus (GFP-GLUT4) or C-terminus (GLUT4-GFP), of GLUT4. Both chimeras were expressed in a perinuclear compartment of CHO cells, and in a vesicular distribution through the cytosol. Insulin promoted an increase in plasma membrane fluorescence as a result of net translocation of the chimeras to the cell surface. GLUT4-GFP, but not GFP-GLUT4, was re-internalised upon the removal of insulin suggesting that a critical internalisation signal sequence exists in the N-terminus of GLUT4. The use of GFP thus allows an analysis of GLUT4 trafficking in single living cells.

Repression of preprotachykinin-A promoter activity is mediated by a proximal promoter element.

The rat preprotachykinin-A promoter, which is able to direct reporter gene expression in adult dorsal root ganglia neurons grown in culture, has no detectable activity in HeLa and PC12 cells. DNAase 1 footprinting and electrophoretic mobility shift analyses with HeLa nuclear extract indicated the presence of a protein complex binding to a region of the rat preprotachykinn-A gene promoter between the TATA box and the major transcriptional start site. We demonstrate that the sequence of the preprotachykinin-A promoter spanning nucleotides -47 to +92 functions to repress reporter gene expression in HeLa and PC12 cells but not in adult rat dorsal root ganglia grown in culture, and that this repression is correlated with a protein(s) binding to the element between the TATA box and major transcription initiation site. These results indicate that the tissue-specific expression of the preprotachykinin-A gene could require the interaction of both positive and negative regulatory DNA elements.

The rat vasoactive intestinal polypeptide cyclic AMP response element regulates gene transcriptional responses differently in neonatal and adult rat sensory neurons.

We studied the ability of the rat vasoactive intestinal polypeptide (VIP) cyclic AMP responsive element (CRE) to regulate reporter gene expression through a c-fos promoter in rat sensory neurons transfected in culture by plasmid microinjection. The CRE enhanced the synergistic response of the promoter to combined potassium-evoked depolarisation and forskolin treatment in neonatal but not adult rat neurons. This corresponds to endogenous VIP expression which is induced synergistically by the same stimuli in neonatal but not adult rat neurons. We conclude that VIP expression in sensory neurons, which is induced by axotomy in vivo, could be regulated through the CRE.

Characterisation of a functional E box motif in the proximal rat preprotachykinin-A promoter.

Three E box motifs, which are upstream of the major transcriptional start site, have previously been characterised in the rat preprotachykinin-A (rPPT) promoter. Only one of these, in the proximal promoter spanning nucleotides -67 to -47, has been demonstrated to support reporter gene expression in clonal cell lines under basal growth conditions. Here we demonstrate that the reporter gene expression can be further induced by the action of phorbol 12-myristate 13-acetate (TPA) and nerve growth factor (NGF), respectively, in both HeLa and the neuronally derived PC12 cells. This response is due to the E box motif and not an overlapping consensus sequence for a putative AP1 element, a class of element previously demonstrated to respond to both TPA and NGF in these cell lines. Finally, we demonstrate that this E box motif can support similar levels of reporter gene expression in primary cultures of dorsal root ganglion neurons as observed in clonal cell lines, demonstrating that E box binding complexes can (1) function as a transcriptional regulator in dorsal root ganglion neurons and (2) bind to and therefore presumably regulate rPPT promoter activity.

Regulation of VIP and other neuropeptides by c-Jun in sensory neurons: implications for the neuropeptide response to axotomy.

Peripheral axotomy of adult rat sensory neurons causes induction of the transcription factor c-Jun and increased expression of the neuropeptides vasoactive intestinal polypeptide (VIP), galanin and neuropeptide Y. To determine whether VIP induction is dependent on transcriptional regulation by c-Jun, we exploited the fact that c-Jun and VIP are also induced in cultured sensory neurons. We blocked c-Jun synthesis by microinjecting antisense oligonucleotides and found that VIP expression, determined by quantitative immunofluorescence, was specifically reduced. Blockade of c-June expression also resulted in reduced neuropeptide Y expression but left galanin, substance P and calcitonin gene-related peptide unaffected. Since in vitro electrophoretic mobility shift assays showed that a nominal cyclic AMP responsive element (CRE) associated with the rat VIP gene could bind c-Jun-containing transcription factor complexes, we next investigated whether VIP expression in sensory neurons might depend on transcription factor binding to the CRE. When a DNA plasmid containing multiple copies of the CRE was injected into newly cultured sensory neurons to sequester transcription factors binding the endogenous CRE, there was a selective reduction in VIP expression. VIP induction in sensory neurons therefore probably results from transcriptional activation by c-Jun acting in combination with other factor(s), possibly acting through the CRE. These results show that c-Jun can regulate transcription of other genes affected by axotomy and imply that it could be a key regulator of the neuronal axotomy response.

An activator element within the preprotachykinin-A promoter.

The rat Preprotachykinin-A promoter (PPT) directs high levels of expression in dorsal root ganglia (DRG) neurons in culture either endogenously or when linked to a receptor construct. It is not active in any of the established tissue culture cell lines which we have analyzed. To search for transcriptional regulators within this promoter we have started to dissect the promoter into individual elements to determine their function. A DNA element which had previously been suggested to regulate transcription from DNA sequence analysis of the rat PPT promoter occurs at position -200 relative to the major start of transcription within the PPT promoter. The equivalent element from the bovine PPT promoter had previously been proposed to be a cAMP responsive element (CRE). The sequence of this enhancer has similarities with both the AP1 and CRE DNA consensus sequences. We have demonstrated that one copy of this rat PPT element linked to a heterologous basal promoter will enhance transcription in HeLa and PC12 cell lines as well as adult rat DRG neurons grown in culture. It is also demonstrated that the rat PPT element will bind proteins in HeLa nuclear extract distinct from those binding to the well-characterized Gibbon Ape Leukemia Virus (GALV) AP1 or somatostatin CRE sites by gel retardation analysis. This PPT element, when cloned in a heterologous reporter construct, although showing properties of both AP1 and CRE elements, was functionally distinguished from both the somatostatin CRE element and the GALV AP1 enhancer when these elements were tested in the same reporter construct. This PPT element has a constitutive level of activity in adult rat DRG neurons, which is fivefold higher than that driven by the reporter construct promoter. It is also significantly different from the same reporter construct linked to the somatostatin CRE and analyzed in DRG neurons.

GLUT4 vesicle dynamics in living 3T3 L1 adipocytes visualized with green-fluorescent protein.

Insulin stimulates glucose uptake into its target cells by a process which involves the translocation of the GLUT4 isoform of glucose transporter from an intracellular vesicular compartment(s) to the plasma membrane. The step(s) at which insulin acts in the vesicle trafficking pathway (e.g. vesicle movement or fusion with the plasma membrane) is not known. We expressed a green-fluorescent protein-GLUT4 (GFP-GLUT4) chimaera in 3T3 L1 adipocytes. The chimaera was expressed in vesicles located throughout the cytoplasm and also close to the plasma membrane. Insulin promoted a substantial translocation of GFP-GLUT4 to the plasma membrane. Time-lapse confocal microscopy demonstrated that the majority of GFP-GLUT4-containing vesicles in the basal state were relatively static, as if tethered (or attached) to an intracellular structure. A proportion (approx. 5%) of the vesicles spontaneously lost their tether, and were observed to move rapidly within the cell. Other vesicles appear to be tethered only on one edge and were observed in a rapid stretching motion. The data support a model in which GLUT4-containing vesicles are tightly tethered to an intracellular structure(s), and indicate that a primary site of insulin action must be to release these vesicles, allowing them to then translocate to and fuse with the plasma membrane.

Two naturally occurring insulin receptor tyrosine kinase domain mutants provide evidence that phosphoinositide 3-kinase activation alone is not sufficient for the mediation of insulin's metabolic and mitogenic effects.

We have recently reported (1) that two naturally occurring mutants of the insulin receptor tyrosine kinase domain, Arg-1174 --> Gln and Pro-1178 --> Leu (Gln-1174 and Leu1178, respectively), both found in patients with inherited severe insulin resistance, markedly impaired receptor tyrosine autophosphorylation, with both mutant receptors being unable to mediate the stimulation of glycogen synthesis or mitogenesis by insulin when expressed in Chinese hamster ovary cells. However, these mutations did not fully prevent IRS-1 phosphorylation in response to insulin in these cells, suggesting that IRS-1 alone may not be sufficient to mediate insulin's metabolic and mitogenic effects. In the present study, we have demonstrated that these mutations also impair the ability of the insulin receptor to activate the transcription factor Elk-1 and promote GLUT4 translocation to the plasma membrane. Although at low concentrations of insulin, the mutant receptors were impaired in their ability to stimulate the tyrosine phosphorylation of IRS-1, at higher insulin concentrations we confirmed that the cells expressing the mutant receptors showed significantly increased tyrosine phosphorylation of IRS-1 compared with parental nontransfected cells. In addition, at comparable insulin concentrations, the association of the p85alpha subunit of phosphoinositide 3-kinase (PI3-kinase) with IRS-1 and the enzymatic activity of IRS-1-associated PI3-kinase were significantly enhanced in cells expressing the mutant receptors. In contrast, no significant stimulation of the tyrosine phosphorylation of Shc, GTP loading of Ras, or mitogen-activated protein kinase phosphorylation was seen in cell lines expressing these mutant receptors. Thus, no activation of any measurable mitogenic or metabolic response was detectable, despite significant insulin-induced phosphorylation of IRS-1 and its association with PI3-kinase in cells stably expressing the mutant insulin receptors. These findings suggest that PI3-kinase activation alone may be insufficient to mediate a wide range of the metabolic and mitogenic effects of insulin. Additionally, the data provide support for the notion that insulin activation of Ras is more closely linked with Shc, and not IRS-1, phosphorylation.