Glutamate, the major excitatory neurotransmitter in the CNS, is implicated in both normal neurotransmission and excitotoxicity. Numerous in vitro findings indicate that the ionotropic glutamate receptor, AMPAR, can rapidly traffic from intracellular stores to the plasma membrane, altering neuronal excitability. These receptor trafficking events are thought to be involved in CNS plasticity as well as learning and memory. AMPAR trafficking has recently been shown to be regulated by glial release of the proinflammatory cytokine tumor necrosis factor ␣ (TNF␣) in vitro. This has potential relevance to several CNS disorders, because many pathological states have a neuroinflammatory component involving TNF␣. However, TNF␣-induced trafficking of AMPARs has only been explored in primary or slice cultures and has not been demonstrated in preclinical models of CNS damage. Here, we use confocal and image analysis techniques to demonstrate that spinal cord injury (SCI) induces trafficking of AMPARs to the neuronal membrane. We then show that this effect is mimicked by nanoinjections of TNF␣, which produces specific trafficking of GluR2-lacking receptors which enhance excitotoxicity. To determine if TNF␣-induced trafficking affects neuronal cell death, we sequestered TNF␣ after SCI using a soluble TNF␣ receptor, and significantly reduced both AMPAR trafficking and neuronal excitotoxicity in the injury penumbra. The data provide the first evidence linking rapid TNF␣-induced AMPAR trafficking to early excitotoxic secondary injury after CNS trauma in vivo, and demonstrate a novel way in which pathological states hijack mechanisms involved in normal synaptic plasticity to produce cell death.
MicroRNAs (miRNAs) are small RNAs that regulate gene expression pathways. Previous studies have shown interactions between hepatitis C virus (HCV) and host miRNAs. We measured miR-122 and miR-21 levels in HCV-infected human liver biopsies relative to uninfected human livers and correlated these with clinical patient data. miR-122 is required for HCV replication in vitro, and miR-21 is involved in cellular proliferation and tumorigenesis. We found that miR-21 expression correlated with viral load, fibrosis and serum liver transaminase levels. miR-122 expression inversely correlated with fibrosis, liver transaminase levels and patient age. miR-21 was induced Btwofold, and miR-122 was downregulated on infection of cultured cells with the HCV J6/JFH infectious clone, thus establishing a link to HCV. To further examine the relationship between fibrosis and the levels of miR-21 and miR-122, we measured their expression levels in a mouse carbon tetrachloride fibrosis model. As in the HCV-infected patient samples, fibrotic stage positively correlated with miR-21 and negatively correlated with miR-122 levels. Transforming growth factor b (TGF-b) is a critical mediator of fibrogenesis. We identified SMAD7 as a novel miR-21 target. SMAD7 is a negative regulator of TGF-b signaling, and its expression is induced by TGF-b. To confirm the relationship between miR-21 and the TGF-b signaling pathway, we measured the effect of miR-21 on a TGF-b-responsive reporter. We found that miR-21 enhanced TGF-b signaling, further supporting a relationship between miR-21 and fibrosis. We suggest a model in which miR-21 targeting of SMAD7 could increase TGF-b signaling, leading to increased fibrogenesis.
Members of the fibroblast growth factor (FGF) family of molecules are critical to limb outgrowth. Here, we examine the expression of Fgfs in three types of limbs-embryonic (developing), mature (differentiated), and regenerating-as well as in the surrounding non-limb tissues in the Mexican axolotl, Ambystoma mexicanum. We have previously cloned partial cDNAs of Fgf4, 8, and 10 from the axolotl (Christensen et al., 2001); the complete Fgf10 cDNA sequence is presented here. Axolotl Fgf10 showed deduced amino acid sequence identity with all other vertebrate Fgf10 coding sequences of >62%, and also included conserved 5 and 3 untranslated regions in nucleotide sequence comparisons. Semiquantitative reverse transcriptase-polymerase chain reaction showed that fibroblast growth factors are differentially expressed in axolotl limbs. Only Fgf8 and 10 were highly expressed during axolotl limb development, although Fgf4, 8, and 10 are all highly expressed during limb development of other vertebrates. Fgf4 expression, however, was highly expressed in the differentiated salamander limb, whereas expression levels of Fgf8 and 10 decreased. Expression levels of Fgf8 and 10 then increased during limb regeneration, whereas Fgf4 expression was completely absent. In addition, axolotl limb regeneration contrasted to limb development of other vertebrates in that Fgf8 did not seem to be as highly expressed in the distal epithelium; rather, its highest expression was found in the blastema mesenchyme. Finally, we investigated the expression of these Fgfs in non-limb tissues. The Fgfs were clearly expressed in developing flank tissue and then severely downregulated in mature flank tissue. Differential Fgf expression levels in the limb and shoulder (limb field) versus in the flank (nonlimb field) suggest that FGFs may be instrumental during limb field specification as well as instrumental in maintaining the salamander limb in a state of preparation for regeneration.
Urodele amphibians (newts and salamanders) have the ability to regenerate amputated limbs throughout their life span. Because fibroblast growth factors (Fgfs) play important roles in developing limbs, we initiated studies to investigate these growth factors in regenerating limbs. Partial cDNAs of Fgf4, 8, and 10 were cloned from both the Mexican axolotl, Ambystoma mexicanum, and locally collected spotted salamander, Ambystoma maculatum, two salamanders well recognized for their regenerative capabilities. cDNAs from the two Ambystoma species were virtually identical, ranging from 97-100% nucleotide identity. Axolotl Fgf4, 8, and 10 showed nucleotide sequence identity with chick Fgf4, 8, and 10 of 79%, 83%, and 72%, respectively. RT-PCR showed that these growth factors are expressed in regenerating axolotl limbs as well as in developing salamander larvae at the three-digit forelimb stage. Fgf8 and 10 are upregulated during regeneration and thus may be involved in distal signaling similar to that of the developing chick limb. Fgf4, however, was undetectable by RT-PCR in the distal tips of regenerates, suggesting that it does not play the same role in limb regeneration that it does in limb development. We also investigated the role these Fgfs may have in the nerve-dependence of regeneration. They were expressed similarly in aneurogenic and innervated limbs, suggesting that they are not the neurotrophic factors responsible for nerve-dependence. Denervation prevented Fgf8 and 10 upregulation, suggesting Fgf pathways are downstream of nerve-dependence. These data highlight important similarities and differences in Fgf expression between limb development and limb regeneration. J. Exp. Zool. 290:529-540, 2001.
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