Defective synthesis and release of astrocytic thrombospondin-1 mediates the neuronal TDP-43 proteinopathy, resulting in defects in neuronal integrity associated with chronic traumatic encephalopathy: in vitro studies.

Transactivating DNA-binding protein-43 (TDP-43) inclusions and the accumulation of phosphorylated and ubiquitinated tau proteins (p-tau) have been identified in postmortem brain specimens from patients with chronic traumatic encephalopathy (CTE). To examine whether these proteins contribute to the development of CTE, we utilized an in vitro trauma system known to reproduce many of the findings observed in humans and experimental animals with traumatic brain injury. Accordingly, we examined the role of TDP-43 and Tau in an in vitro model of trauma, and determined whether these proteins contribute to the defective neuronal integrity associated with CNS trauma. Single or multiple episodes of trauma to cultured neurons resulted in a time-dependent increase in cytosolic levels of phosphorylated TDP-43 (p-TDP-43). Trauma to cultured neurons also caused an increase in levels of casein kinase 1 epsilon (CK1ε), and ubiquitinated p-TDP-43, along with a decrease in importin-ß (all factors known to mediate the "TDP-43 proteinopathy"). Defective neuronal integrity, as evidenced by a reduction in levels of the NR1 subunit of the NMDA receptor, and in PSD95, along with increased levels of phosphorylated tau were also observed. Additionally, increased levels of intra- and extracellular thrombospondin-1 (TSP-1) (a factor known to regulate neuronal integrity) were observed in cultured astrocytes at early stages of trauma, while at later stages decreased levels were identified. The addition of recombinant TSP-1, conditioned media from cultured astrocytes at early stages of trauma, or the CK1ε inhibitor PF4800567 hydrochloride to traumatized cultured neurons reduced levels of p-TDP-43, and reversed the trauma-induced decline in NR1 subunit of the NMDA receptor and PSD95 levels. These findings suggest that a trauma-induced increase in TDP-43 phosphorylation contributes to defective neuronal integrity, and that increasing TSP-1 levels may represent a useful therapeutic approach for the prevention of the neuronal TDP-43 proteinopathy associated with CTE. Read the Editorial Highlight for this article on page 531.

Mouse SGLT3a generates proton-activated currents but does not transport sugar.

Sodium-glucose cotransporters (SGLTs) are secondary active transporters belonging to the SLC5 gene family. SGLT1, a well-characterized member of this family, electrogenically transports glucose and galactose. Human SGLT3 (hSGLT3), despite sharing a high amino acid identity with human SGLT1 (hSGLT1), does not transport sugar, although functions as a sugar sensor. In contrast to humans, two different genes in mice and rats code for two different SGLT3 proteins, SGLT3a and SGLT3b. We previously cloned and characterized mouse SGLT3b (mSGLT3b) and showed that, while it does transport sugar like SGLT1, it likely functions as a physiological sugar sensor like hSGLT3. In this study, we cloned mouse SGLT3a (mSGLT3a) and characterized it by expressing it in Xenopus laevis oocytes and performing electrophysiology and sugar transport assays. mSGLT3a did not transport sugar, and sugars did not induce currents at pH 7.4, though acidic pH induced inward currents that increased in the presence of sugar. Moreover, mutation of residue 457 from glutamate to glutamine resulted in a Na(+)-dependent transport of sugar that was inhibited by phlorizin. To corroborate our results in oocytes, we expressed and characterized mSGLT3a in mammalian cells and confirmed our findings. In addition, we cloned, expressed, and characterized rat SGLT3a in oocytes and found characteristics similar to mSGLT3a. In summary, acidic pH induces currents in mSGLT3a, and sugar-induced currents are increased at acidic pH, but wild-type SGLT3a does not transport sugar.

Sugar binding residue affects apparent Na+ affinity and transport stoichiometry in mouse sodium/glucose cotransporter type 3B.

SGLT1 is a sodium/glucose cotransporter that moves two Na(+) ions with each glucose molecule per cycle. SGLT3 proteins belong to the same family and are described as glucose sensors rather than glucose transporters. Thus, human SGLT3 (hSGLT3) does not transport sugar, but extracellular glucose depolarizes the cell in which it is expressed. Mouse SGLT3b (mSGLT3b), although it transports sugar, has low apparent sugar affinity and partially uncoupled stoichiometry compared with SGLT1, suggesting that mSGLT3b is also a sugar sensor. The crystal structure of the Vibrio parahaemolyticus SGLT showed that residue Gln(428) interacts directly with the sugar. The corresponding amino acid in mammalian proteins, 457, is conserved in all SGLT1 proteins as glutamine. In SGLT3 proteins, glutamate is the most common residue at this position, although it is a glycine in mSGLT3b and a serine in rat SGLT3b. To test the contribution of this residue to the function of SGLT3 proteins, we constructed SGLT3b mutants that recapitulate residue 457 in SGLT1 and hSGLT3, glutamine and glutamate, respectively. The presence of glutamine at residue 457 increased the apparent Na(+) and sugar affinities, whereas glutamate decreased the apparent Na(+) affinity. Moreover, glutamate transported more cations per sugar molecule than the wild type protein. We propose a model where cations are released intracellularly without the release of sugar from an intermediate state. This model explains the uncoupled charge:sugar transport phenotype observed in wild type and G457E-mSGLT3b compared with SGLT1 and the sugar-activated cation transport without sugar transport that occurs in hSGLT3.

Transport direction determines the kinetics of substrate transport by the glutamate transporter EAAC1.

Glutamate transport by the excitatory amino acid carrier EAAC1 is known to be reversible. Thus, glutamate can either be taken up into cells, or it can be released from cells through reverse transport, depending on the electrochemical gradient of the co- and countertransported ions. However, it is unknown how fast and by which reverse transport mechanism glutamate can be released from cells. Here, we determined the steady- and pre-steady-state kinetics of reverse glutamate transport with submillisecond time resolution. First, our results suggest that glutamate and Na(+) dissociate from their cytoplasmic binding sites sequentially, with glutamate dissociating first, followed by the three cotransported Na(+) ions. Second, the kinetics of glutamate transport depend strongly on transport direction, with reverse transport being faster but less voltage-dependent than forward transport. Third, electrogenicity is distributed over several reverse transport steps, including intracellular Na(+) binding, reverse translocation, and reverse relocation of the K(+)-bound EAAC1. We propose a kinetic model, which is based on a "first-in-first-out" mechanism, suggesting that glutamate association, with its extracellular binding site as well as dissociation from its intracellular binding site, precedes association and dissociation of at least one Na(+) ion. Our model can be used to predict rates of glutamate release from neurons under physiological and pathophysiological conditions.