Serotonin/Dopamine Interactions in a Hyperactive Mouse: Reduced Serotonin Receptor 1B Activity Reverses Effects of Dopamine Transporter Knockout

Knockout (KO) mice that lack the dopamine transporter (SL6A3; DAT) display increased locomotion that can be attenuated, under some circumstances, by administration of drugs that normally produce psychostimulant-like effects, such as amphetamine and methylphenidate. These results have led to suggestions that DAT KO mice may model features of attention deficit hyperactivity disorder (ADHD) and that these drugs may act upon serotonin (5-HT) systems to produce these unusual locomotor decreasing effects. Evidence from patterns of brain expression and initial pharmacologic studies led us to use genetic and pharmacologic approaches to examine the influence of altered 5-HT_1B receptor activity on hyperactivity in DAT KO mice. Heterozygous 5-HT_1B KO and pharmacologic 5-HT_1B antagonism both attenuated locomotor hyperactivity in DAT KO mice. Furthermore, DAT KO mice with reduced, but not eliminated, 5-HT_1B receptor expression regained cocaine-stimulated locomotion, which was absent in DAT KO mice with normal levels of 5-HT_1B receptor expression. Further experiments demonstrated that the degree of habituation to the testing apparatus determined whether cocaine had no effect on locomotion in DAT KO or reduced locomotion, helping to resolve differences among prior reports. These findings of complementation of the locomotor effects of DAT KO by reducing 5-HT_1B receptor activity underscore roles for interactions between specific 5-HT receptors and dopamine (DA) systems in basal and cocaine-stimulated locomotion and support evaluation of 5-HT_1B antagonists as potential, non-stimulant ADHD therapeutics.     

Affective Neural Responses Modulated by Serotonin Transporter Genotype in Clinical Anxiety and Depression

Serotonin transporter gene variants are known to interact with stressful life experiences to increase chances of developing affective symptoms, and these same variants have been shown to influence amygdala reactivity to affective stimuli in non-psychiatric populations. The impact of these gene variants on affective neurocircuitry in anxiety and mood disorders has been studied less extensively. Utilizing a triallelic assay (5-HTTLPR and rs25531) to assess genetic variation linked with altered serotonin signaling, this fMRI study investigated genetic influences on amygdala and anterior insula activity in 50 generalized anxiety disorder patients, 26 of whom also met DSM-IV criteria for social anxiety disorder and/or major depressive disorder, and 39 healthy comparison subjects. A Group x Genotype interaction was observed for both the amygdala and anterior insula in a paradigm designed to elicit responses in these brain areas during the anticipation of and response to aversive pictures. Patients who are S/L_G carriers showed less activity than their L_A/L_A counterparts in both regions and less activity than S/L_G healthy comparison subjects in the amygdala. Moreover, patients with greater insula responses reported higher levels of intolerance of uncertainty, an association that was particularly pronounced for patients with two L_A alleles. A genotype effect was not established in healthy controls. These findings link the serotonin transporter gene to affective circuitry findings in anxiety and depression psychopathology and further suggest that its impact on patients may be different from effects typically observed in healthy populations.     

The Cellular Distribution of Serotonin Transporter Is Impeded on Serotonin-Altered Vimentin Network

Background

The C-terminus of the serotonin transporter (SERT) contains binding domains for different proteins and is critical for its functional expression. In endogenous and heterologous expression systems, our proteomic and biochemical analysis demonstrated that an intermediate filament, vimentin, binds to the C-terminus of SERT. It has been reported that 5HT-stimulation of cells leads to disassembly and spatial reorientation of vimentin filaments.

Methodology/Principal Findings

We tested the impact of 5HT-stimulation on vimentin-SERT association and found that 5HT-stimulation accelerates the translocation of SERT from the plasma membrane via enhancing the level of association between phosphovimentin and SERT. Furthermore a progressive truncation of the C-terminus of SERT was performed to map the vimentin-SERT association domain. Deletion of up to 20, but not 14 amino acids arrested the transporters at intracellular locations. Although, truncation of the last 14 amino acids, did not alter 5HT uptake rates of transporter but abolished its association with vimentin.To understand the involvement of 5HT in phosphovimentin-SERT association from the plasma membrane, we further investigated the six amino acids between Δ14 and Δ20, i.e., the SITPET sequence of SERT. While the triple mutation on the possible kinase action sites, S₆₁₁, T₆₁₃, and T₆₁₆ arrested the transporter at intracellular locations, replacing the residues with aspartic acid one at a time altered neither the 5HT uptake rates nor the vimentin association of these mutants. However, replacing the three target sites with alanine, either simultaneously or one at a time, had no significant effect on 5HT uptake rates or the vimentin association with transporter.

Conclusions/Significance

Based on our findings, we propose that phosphate modification of the SITPET sequence differentially, one at a time exposes the vimentin binding domain on the C-terminus of SERT. Conversely, following 5HT stimulation, the association between vimentin-SERT is enhanced which changes the cellular distribution of SERT on an altered vimentin network.     

双链RNA依赖性蛋白激酶的结构与作用

dsRNA-依赖的蛋白激酶(PKR)在信号转导、细胞生长、分化和凋亡的控制中起重要作用。最近证实PKR是一个重要的凋亡效应物,是许多不同刺激物诱导凋亡的一个转导物,所以一些研究者开始关注是否PKR的调节可以作为一种新的抗肿瘤策略。由于PKR强大的生长抑制功能和促凋亡功能,使之可能成为又一个肿瘤基因治疗的靶点。该文介绍PKR的结构、活性调节、促凋亡活性及应用于肿瘤治疗的潜力。     

桩蛋白的结构与功能

桩蛋白(paxillin)是近年来发现的一种信号蛋白,主要定位于黏着斑,包含LD模体、LIM结构域、SH2和SH3结合结构域,在整个分子中还散在着多种磷酸化位点,共同构成了桩蛋白的多结构域性结构。桩蛋白分子本身的酶活性尚不清楚,但很可能作为细胞内的一种接头蛋白与多种功能蛋白质结合。另外．作为黏着斑的重要组成部分,桩蛋白不仅参与了整合蛋白介导的信号转导和黏着斑的组装,在细胞黏附和迁移过程中也发挥了重要作用。     

Serotonin Transporter Deficiency Increases Abdominal Fat in Female,but Not Male Rats

Depression and abdominal obesity often co‐occur, predominantly in women, and are associated with an increased risk for the development of glucose intolerance and subsequently type 2 diabetes. The underlying mechanisms are poorly understood. We found that female, but not male, depression‐prone serotonin transporter knockout (SERT^?/?) rats had a strong increase (54%) in abdominal fat, whereas no increases in plasma concentrations of glucose and insulin were observed. Surprisingly, application of a high‐fat, high‐sucrose (HFHS)‐choice diet, which results in increased abdominal fat deposition and increased plasma glucose levels in wild‐type rats, did not result in elevated plasma glucose levels in female SERT^?/? rats. Our results show that serotonin transporter deficiency affects abdominal fat deposition in a sex‐dependent way, but protects against rises in glucose levels, and thereby potentially glucose intolerance. The increased abdominal fat formation could result from serotonin‐mediated developmental changes and provides heuristic value for understanding the effects of the depression‐associated serotonin transporter promoter polymorphism in humans.     

Structural and Functional Characterization of a Caenorhabditis elegans Genetic Interaction Network within Pathways

A genetic interaction (GI) is defined when the mutation of one gene modifies the phenotypic expression associated with the mutation of a second gene. Genome-wide efforts to map GIs in yeast revealed structural and functional properties of a GI network. This provided insights into the mechanisms underlying the robustness of yeast to genetic and environmental insults, and also into the link existing between genotype and phenotype. While a significant conservation of GIs and GI network structure has been reported between distant yeast species, such a conservation is not clear between unicellular and multicellular organisms. Structural and functional characterization of a GI network in these latter organisms is consequently of high interest. In this study, we present an in-depth characterization of ~1.5K GIs in the nematode Caenorhabditis elegans. We identify and characterize six distinct classes of GIs by examining a wide-range of structural and functional properties of genes and network, including co-expression, phenotypical manifestations, relationship with protein-protein interaction dense subnetworks (PDS) and pathways, molecular and biological functions, gene essentiality and pleiotropy. Our study shows that GI classes link genes within pathways and display distinctive properties, specifically towards PDS. It suggests a model in which pathways are composed of PDS-centric and PDS-independent GIs coordinating molecular machines through two specific classes of GIs involving pleiotropic and non-pleiotropic connectors. Our study provides the first in-depth characterization of a GI network within pathways of a multicellular organism. It also suggests a model to understand better how GIs control system robustness and evolution.     

Molecular Identification and Functional Characterization of the Human Colonic Thiamine Pyrophosphate Transporter

Colonic microbiota synthesize a considerable amount of thiamine in the form of thiamine pyrophosphate (TPP). Recent functional studies from our laboratory have shown the existence of a specific, high-affinity, and regulated carrier-mediated uptake system for TPP in human colonocytes. Nothing, however, is known about the molecular identity of this system. Here we report on the molecular identification of the colonic TPP uptake system as the product of the SLC44A4 gene. We cloned the cDNA of SLC44A4 from human colonic epithelial NCM460 cells, which, upon expression in ARPE19 cells, led to a significant (p < 0.01, >5-fold) induction in [³H]TPP uptake. Uptake by the induced system was also found to be temperature- and energy-dependent; Na⁺-independent, slightly higher at acidic buffer pH, and highly sensitive to protonophores; saturable as a function of TPP concentration, with an apparent K_m of 0.17 ± 0.064 μm; and highly specific for TPP and not affected by free thiamine, thiamine monophosphate, or choline. Expression of the human TPP transporter was found to be high in the colon and negligible in the small intestine. A cell surface biotinylation assay and live cell confocal imaging studies showed the human TPP transporter protein to be expressed at the apical membrane domain of polarized epithelia. These results show, for the first time, the molecular identification and characterization of a specific and high-affinity TPP uptake system in human colonocytes. The findings further support the hypothesis that the microbiota-generated TPP is absorbable and could contribute toward host thiamine homeostasis, especially toward cellular nutrition of colonocytes.     

Functional Characterization of the Amanita muscaria Monosaccharide Transporter, AmMst1

Abstract: Fungal carbohydrate nutrition is an important aspect of ectomycorrhizal symbiosis. At the plant/fungus interface, fungal and root cortical cells compete for monosaccharides, generated from plant-derived sucrose. Therefore, the kinetic properties of the monosaccharide uptake systems are decisive for the monosaccharide yield of each partner. For the functional characterization of a hexose transporter (AmMst1) of the ectomycorrhizal fungus Amanita muscaria, the entire cDNA was expressed in a Saccharomyces cerevisiae strain unable to take up hexoses. Uptake experiments with ¹⁴C-labelled monosaccharides resulted in K_M values of 0.46 mM for glucose and 4.20 mM for fructose, revealing a strong preference of AmMst1 for glucose as substrate. Glucose uptake by AmMst1 was strongly favoured even in the presence of a large excess of fructose. Comparable affinities of AmMst1 for glucose, 3-O-methyl glucose and mannose were obtained. In contrast, AmMst1 imported galactose with a much lower efficiency, revealing that this transporter distinguishes pyranoses by steric hindrance at the C-4 position. While yeast contains numerous hexose transporter genes, the AmMst1 gene seems to be the main, if not the only, hexose transporter that is expressed in A. muscaria, as concluded from the comparison of hexose import properties of A. muscaria protoplasts and AmMst1 expressed in yeast.     

VNTR Polymorphisms of the Serotonin Transporter and Dopamine Transporter Genes in Male Opiate Addicts

VNTR polymorphisms of the serotonin transporter (hSERT) and dopamine transporter (DAT1) gene were studied in male opiate addicts. Samples of ethnic Russians and ethnic Tatars did not differ in genotype and allele frequencies. Homozygosity at hSERT (especially 10/10) was associated with early opiate addiction, while genotype 12/10 proved to be protective. In the case of DAT1, genotype 9/9 was associated with early opiate addiction. The combination of hSERT genotype 10/10 with DAT1 genotype 10/10 was shown to be a risk factor of opiate abuse under 16 years of age.     

Epigenetic Regulation of Serotonin Transporter in Psychiatric Disorders

SLC6A4 (solute carrier family 6,member 4) gene encodes a serotonin transporter (5-hydroxytryptamine transporter,HTT),which transports synaptic serotonin into presynaptic terminal.SLC6A4 is known to be the target of antidepressants such as selective serotonin reuptake inhibitors (SSRIs).Inhibition of HTT increases synaptic serotonin concentration and thereby exerts antidepressant efficacy.A large number of genetic studies suggest the contribution of genetic variations of SLC6A4 to various psychiatric disorders.The most studied genetic variation,HTT-linked polymorphic region (HTTLPR),is located at the promoter region of SLC6A4.     

Functional Characterization of a Na+-dependent Aspartate Transporter from Pyrococcus horikoshii

Excitatory amino acid transporters (EAATs) are crucial in maintaining extracellular levels of glutamate, the most abundant excitatory neurotransmitter, below toxic levels. The recent three-dimensional crystal structure of Glt_Ph, an archaeal homolog of the EAATs, provides elegant structural details of this family of proteins, yet we know little about the mechanism of the bacterial transporter. Conflicting reports in the literature have described Glt_Ph as an aspartate transporter driven by Na⁺ or a glutamate transporter driven by either Na⁺ or H⁺. Here we use purified protein reconstituted into liposomes to thoroughly characterize the ion and substrate dependence of the Glt_Ph transport. We confirm that Glt_Ph is a Na⁺-dependent transporter that is highly selective for aspartate over other amino acids, and we show that transport is coupled to at least two Na⁺ ions. In contrast to the EAATs, transport via Glt_Ph is independent of H⁺ and K⁺. We propose a kinetic model of transport in which at least two Na⁺ ions are coupled to the cotransport of each aspartate molecule by Glt_Ph, and where an ion- and substrate-free transporter reorients to complete the transport cycle.     

Structural and Functional Characterization of the Mumps Virus Phosphoprotein

The phosphoprotein (P) is virally encoded by the Rhabdoviridae and Paramyxoviridae in the order Mononegavirales. P is a self-associated oligomer and forms complexes with the large viral polymerase protein (L), the nucleocapsid protein (N), and the assembled nucleocapsid. P from different viruses has shown structural diversities even though their essential functions are the same. We systematically mapped the domains in mumps virus (MuV) P and investigated their interactions with nucleocapsid-like particles (NLPs). Similar to other P proteins, MuV P contains N-terminal, central, and C-terminal domains with flexible linkers between neighboring domains. By pulldown assays, we discovered that in addition to the previously proposed nucleocapsid binding domain (residues 343 to 391), the N-terminal region of MuV P (residues 1 to 194) could also bind NLPs. Further analysis of binding kinetics was conducted using surface plasmon resonance. This is the first observation that both the N- and C-terminal regions of a negative-strand RNA virus P are involved in binding the nucleocapsid. In addition, we defined the oligomerization domain (P_OD) of MuV P as residues 213 to 277 and determined its crystal structure. The tetrameric MuV P_OD is formed by one pair of long parallel α-helices with another pair in opposite orientation. Unlike the parallel orientation of each α-helix in the tetramer of Sendai virus P_OD, this represents a novel orientation of a P_OD where both the N- and the C-terminal domains are at either end of the tetramer. This is consistent with the observation that both the N- and the C-terminal domains are involved in binding the nucleocapsid.     

Oligomeric Structure and Functional Characterization of the Urea Transporter from Actinobacillus pleuropneumoniae

Urea transporters (UTs) facilitate urea permeation across cell membranes in prokaryotes and eukaryotes. Bacteria use urea as a means to survive in acidic environments and/or as a nitrogen source. The UT from Actinobacillus pleuropneumoniae, ApUT, the pathogen that causes porcine pleurisy and pneumonia, was expressed in Escherichia coli and purified. Analysis of the recombinant protein using cross-linking and blue-native gel electrophoresis established that ApUT is a dimer in detergent solution. Purified protein was reconstituted into proteoliposomes and urea efflux was measured by stopped-flow fluorometry to determine the urea transport kinetics of ApUT. The measured urea flux was saturable, could be inhibited by phloretin, and was not affected by pH. Two-dimensional crystals of the biologically active ApUT show that it is also dimeric in a lipid membrane and provide the first structural information on a member of the UT family.     

Serotonin Transporter Gene-Linked Polymorphism Affects Detection of Facial Expressions

Previous studies have demonstrated that the serotonin transporter gene-linked polymorphic region (5-HTTLPR) affects the recognition of facial expressions and attention to them. However, the relationship between 5-HTTLPR and the perceptual detection of others'' facial expressions, the process which takes place prior to emotional labeling (i.e., recognition), is not clear. To examine whether the perceptual detection of emotional facial expressions is influenced by the allelic variation (short/long) of 5-HTTLPR, happy and sad facial expressions were presented at weak and mid intensities (25% and 50%). Ninety-eight participants, genotyped for 5-HTTLPR, judged whether emotion in images of faces was present. Participants with short alleles showed higher sensitivity (d′) to happy than to sad expressions, while participants with long allele(s) showed no such positivity advantage. This effect of 5-HTTLPR was found at different facial expression intensities among males and females. The results suggest that at the perceptual stage, a short allele enhances the processing of positive facial expressions rather than that of negative facial expressions.     

Functional Characterization of a Silicon Transporter Gene Implicated in Silicon Distribution in Barley

Silicon (Si) is a beneficial element for plant growth. In barley (Hordeum vulgare), Si uptake by the roots is mainly mediated by a Si channel, Low Silicon1 (HvLsi1), and an efflux transporter, HvLsi2. However, transporters involved in the distribution of Si in the shoots have not been identified. Here, we report the functional characterization of a homolog of HvLsi1, HvLsi6. HvLsi6 showed permeability for Si and localized to the plasma membrane. At the vegetative growth stage, HvLsi6 was expressed in both the roots and shoots. The expression level was unaffected by Si supply. In the roots, HvLsi6 was localized in epidermis and cortex cells of the tips, while in the leaf blades and sheaths, HvLsi6 was only localized at parenchyma cells of vascular bundles. At the reproductive growth stage, high expression of HvLsi6 was also found in the nodes. HvLsi6 in node I was polarly located at the transfer cells surrounding the enlarged vascular bundles toward the numerous xylem vessels. These results suggest that HvLsi6 is involved in Si uptake in the root tips, xylem unloading of Si in leaf blade and sheath, and intervascular transfer of Si in the nodes. Furthermore, HvLsi2 was found to be localized at the parenchyma cell layer adjacent to the transfer cells with opposite polarity of HvLsi6, suggesting that the coupling of HvLsi6 and HvLsi2 is involved in the intervascular transfer of Si at the nodes. Si translocated via the enlarged vascular bundles is unloaded to the transfer cells by HvLsi6, followed by HvLsi2 to reload Si to the diffuse vascular bundles, which are connected to the upper part of the plant, especially the panicles, the ultimate Si sink.Silicon (Si) is a beneficial element for plant growth. It enhances the resistance of plants to various biotic and abiotic stresses (Epstein, 1999; Ma and Takahashi, 2002; Ma and Yamaji, 2006). For example, Si reduces the epidemics of both leaf and panicle blast in rice (Oryza sativa; Datnoff and Rodrigues, 2005) and decreases the incidence of powdery mildew in cucumber (Cucumis sativus), barley (Hordeum vulgare), and wheat (Triticum aestivum; Fauteux et al., 2005). Si also suppresses insect pests such as stem borer (Chilo suppressalis), brown planthopper (Nilaparvata lugens), and rice green leafhopper (Nephotettix cincticeps; Savant et al., 1997). Resistance to the damage by wild rabbit in wheat is also enhanced by an increased amount of Si in leaf tissue (Cotterill et al., 2007). Si is also able to alleviate lodging, drought, and low- and high-temperature stresses (Ma, 2004). The beneficial effects of Si under phosphate deficiency, phosphate excess, and manganese and salt toxicity stresses have been observed in many plants (Ma and Takahashi, 2002). Usually, the more Si that accumulates in the shoots, the greater its effect in enhancing the plant’s response. This is because most effects of Si are expressed through the formation of silica gel, which is deposited on leaves, stems, and other organs of plants (Ma and Yamaji, 2006). Therefore, for the plant to benefit from Si, a high accumulation is required. However, Si accumulation greatly varies with plant species, and this difference has been attributed to the ability of plants to take up Si.Transporters responsible for Si uptake by roots have been identified in several plant species, including barley, maize (Zea mays), pumpkin (Cucurbita moschata), rice, wheat (Ma et al., 2011), and most recently in horsetail (Equisetum arvense; EaNIP3s [for Nod26-like major intrinsic protein3]; Grégoire et al., 2012). Two different types of transporter, Si-permeable channel and efflux transporter, are involved in the Si-uptake process. Low Silicon1 (Lsi1) belongs to a NIP subfamily of aquaporin-like proteins and functions as a Si-permeable channel. Lsi1 in rice is localized in the distal side of root exodermis and endodermis (Ma et al., 2006), but Lsi1 in barley, maize, and pumpkin is localized in the epidermis and cortex (Chiba et al., 2009; Mitani et al., 2009b, 2011). On the other hand, Lsi2 functions as an efflux Si transporter and belongs to a putative anion transporter family without any similarity to Lsi1. Lsi2 in rice is also localized at the root exodermis and endodermis as Lsi1, but it is polarly localized at the proximal side (Ma et al., 2007). By contrast, Lsi2 in barley and maize is localized only to the endodermis of roots. Furthermore, these transporters do not show polar localization in barley and maize (Mitani et al., 2009a). Therefore, Si uptake mediated by Lsi1 and Lsi2 shows different pathways between rice and other plant species (Ma et al., 2011).Following uptake by the roots through Lsi1 and Lsi2, Si is translocated to the aboveground part and distributed in different tissues. Lsi6, a homolog of Lsi1, is involved in xylem unloading of Si in rice (Yamaji et al., 2008). Lsi6 is localized on the adaxial side of the xylem parenchyma cells in the leaf sheaths and leaf blades. Knockout of Lsi6 resulted in altered distribution of Si in the leaf cells. Furthermore, at the reproductive growth stage of rice, Lsi6 is also highly expressed at the nodes (Yamaji and Ma, 2009). At node I below the panicle, Lsi6 is mainly localized at the xylem transfer cells with polarity facing toward the xylem vessel (Yamaji and Ma, 2009). Knockout of Lsi6 decreased Si accumulation in the panicle but increased Si accumulation in the flag leaf. These findings indicate that Lsi6 is also required for the intervascular transfer of Si in rice, transferring Si from the enlarged vascular bundles coming from the roots to the diffuse vascular bundles connected to the panicle.Barley is a Si-accumulating species, although the accumulation extent is lower than that of rice. Transporters responsible for Si uptake in barley roots have been identified (Chiba et al., 2009; Mitani et al., 2009a); however, transporters for Si distribution in aboveground plant tissues are unknown. In this study, we functionally characterized a rice Lsi6 homolog gene in barley, HvLsi6, in terms of transport activity and expression pattern, as well as cellular and subcellular localizations. We found that HvLsi6 is probably involved in Si uptake in the root tip, xylem unloading in the leaf, and intervascular transfer of Si at the nodes in barley. We further found that HvLsi2 was also expressed in the nodes and involved in the intervascular transfer by coupling with HvLsi6.