Parkin Transcript Variants in Rat and Human Brain

Alternative splicing has an important role in expanding protein diversity. We have identified complementary DNA species from adult rat and fetal human brain encoding seven new splice variants of parkin, a gene mutated in autosomal recessive juvenile parkinsonism (ARJP). Alternative splicing affects almost all previously characterized exons, plus 3 new exons of 72, 156, and 180 nucleotides. This creates the potential to express hundreds of different isoforms. The encoded parkin isoforms have different amino acid composition, post-translational modifications, and, most important, molecular architectures. They diverge for the presence or absence of the ubiquitin-like domain, one or two C3HC4 ring fingers, the in-between ring fingers (IBR) domain, and a thiol proteases active site, which has not been previously characterized. Distinct expression patterns occur in primary cultures of neuronal and glial cells. Extensive splicing of parkin produces regional and structural diversity and may have important implications for the pathogenetic mechanisms underlying ARJP.     

Protein Arginylation in Rat Brain Cytosol: A Proteomic Analysis

Arginine can be post-translationally incorporated from arginyl-tRNA into the N-terminus of soluble acceptor proteins in a reaction catalyzed by arginyl-tRNA protein transferase. In the present study, several soluble rat brain proteins that accepted arginine were identified after arginine incorporation by two dimensional electrophoresis and mass spectrometry. They were identified as: contrapsin-like protease inhibitor-3, α-1-antitrypsin, apolipoprotein E, hemopexin, calreticulin and apolipoprotein A-I. All of these proteins shared a signal sequence for the translocation of proteins across endoplasmic reticulum membranes. After losing the signal peptide, these proteins expose amino acids described as compatible for post-translational arginylation. Although the enzymatic system involved in arginylation is confined mainly in cytosol and nucleus, all the substrates described herein enter to the exocytic pathway co-translationally. Therefore, we postulate that the substrates for arginylation could reach the cytosol by retro-translocation and be then arginylated.     

Postnatal Expression of Glucose-6-Phosphate Dehydrogenase in Different Brain Areas

The activity of glucose-6-phosphate dehydrogenase (G6PD) was studied in five brain areas of rats aged 5 to 90 days. The areas studied were: the olfactory bulb (OB), cortex, hippocampus, striatum and septum. The G6PD activity increased more than 2-fold from 5 to 90 days in the OB, while it was almost constant in the other areas. At every stage of development, the G6PD activity was significantly higher in the OB than in the other areas. The G6PD pattern was compared with 6-phosphogluconate dehydrogenase (6PGD), glutathione reductase (GR); glutathione peroxidase (GPX), catalase (CAT) and superoxide dismutase (SOD) in order to find synergistic interactions among activities of these enzymes during development. Over the considered period, the activity of 6PGD increased significantly in the OB, while no significant difference in activity was detected in the other areas. GR increased significantly and progressively at each developmental stage in all areas. GPX showed a progressive increase in the OB, while in other areas a significant increase was detected at 90 days only. CAT and SOD showed a different and independent pattern which differred from the G6PD pattern. CAT showed the highest level of activity at 5 days then progressively decreased or was constant until 90 days; SOD had the highest value at 5 days, than it decreased at 10 days and increased from 10 to 90 days. In all areas, G6PD activity showed three electrophoretic bands, whose relative activity changed with development. At histochemical level, we found a marked G6PD activity in the periglomerular zone of the OB, which increased with age, while other areas showed a homogeneous staining. The present results demonstrate that G6PD activity increases in the OB during the developmental stages and there is a coordinated simultaneous activation of 6PGD, GPX and GR. It is likely that this enzyme induction increases the antioxidant defense of periglomerular cells that are subject to a rapid renewal and thus much more exposed to oxidant stress.     

Postmortem Changes of Normetanephrine Determined by a Mass-Fragmentographic Technique in Different Rat Brain Areas

Abstract: A specific and sensitive gas chromatographic–mass spectrometric assay for measurement of normetanephrine (NMN) in different rat brain regions is presented. The results show that hypothalamus contains the highest concentrations of the norepinephrine metabolite. An increase of NMN concentrations has been detected in animals killed by decapitation in comparison with microwave–irradiated rats. This finding has to be taken into consideration when NMN is measured in the brain in order to assess the functional activity of noradrenergic neurons.     

Expression and Localization of Brain Ankyrin Isoforms and Related Proteins During Early Developmental Stages of Rat Nervous System

Abstract: Expression and localization of two isoforms of brain ankyrin, 440- and 220-kDa ankyrin_B, were studied in the developing nervous system of the rat fetus. The 440-kDa ankyrin_B appeared on as early as embryonic day 13, and its level increased progressively toward the day of birth, which was similar to the expression pattern of growth-associated protein (GAP)-43, a well-established axonal protein. On the other hand, 220-kDa ankyrin_B was expressed at a low level but constitutively throughout the latter prenatal period and was a major isoform even before embryonic day 14. Whereas the localization of 440-kDa ankyrin_B was essentially confined to the axons, judging from the similarity with that of GAP-43, 220-kDa ankyrin_B showed a rather general distribution in neural tissue. The localization of L1, known as an ankyrin_B-binding protein, was similar to that of 440-kDa ankyrin_B in the brain tissue, whereas it was similar to that of 220-kDa ankyrin_B in cultured neurons, suggesting that the interaction of L1 with brain ankyrins in neurons is affected by their environment.     

β-Amyloid Precursor Protein Isoforms in Various Rat Brain Regions and During Brain Development

To address the question of the possible functions of different Alzheimer's disease beta-amyloid precursor protein (beta-APP) isoforms in the brain, we studied their expression at different times during postnatal rat brain development and in various regions of the adult rat brain. Polyclonal antibodies directed to two peptide antigens were used. The majority of all beta-APP forms was found to be soluble as revealed by western blot analysis. The highest level of most beta-APP forms was reached in the second postnatal week, which is the time of brain maturation and completion of synaptic connections. Strikingly high concentrations of the Kunitz protease inhibitor-containing beta-APP were present in the adult olfactory bulb, where continuous synaptogenesis occurs in the adult animal. These findings support the idea of an involvement of beta-APPs in the processes of cell differentiation and, probably, in the establishment of synaptic contacts.     

Heterogeneous Expression of Transketolase in Rat Brain

Abstract: Transketolase (TK; EC 2.2.1.1) is a key pentose phosphate shunt enzyme that plays an important role in the production of reducing equivalents and pentose sugars. TK activity declines in the brains of patients with Alzheimer's disease or Wernicke-Korsakoff syndrome, as well as in thiamine-deficient rats. Understanding the role of TK in the pathophysiology of these neurodegenerative conditions requires knowledge of its regional, cellular, and subcellular distribution within the brain. The current study employed in situ hybridization and immunocytochemistry to examine the distribution of TK mRNA and its encoded protein in adult rat brain. TK mRNA and protein were widely distributed throughout the brain. However, they were enriched in selective perikarya in the piriform cortex, nucleus of the diagonal band, red nucleus, dorsal raphe, pontine nucleus, locus coeruleus, trapezoid, inferior olive, and several cranial nerve nuclei. Lower expression of TK mRNA and protein occurred in layer V of cortex, olfactory tubercle, ventral pallidum, medial septal nucleus, hippocampus, thalamic and hypothalamic nuclei, mammillary body, central gray, and the substantia nigra. TK immunoreactivity also occurred in the nuclei of ubiquitously distributed glial cells, as well as ependymal cells. The heterogeneous distribution of TK may reflect a variety of metabolic activities among different brain regions but does not provide a simple molecular explanation for selective cell death in either thiamine deficiency or other conditions where TK is reduced.     

Distribution of Ankyrin Isoforms and Their Proteolysis After Ischemia and Reperfusion in Rat Brain

Abstract: The distribution of brain-type ankyrin (ankyrin_B, 212 kDa) and erythrocyte-type ankyrin (ankyrin_R, 239 kDa) was investigated in the subcellular fractions of rat forebrain (P1, 1,000 g pellet; P2, 15,000 g pellet; P3, 100,000 g pellet; S, 100,000 g supernatant) by immunoblotting using specific antibodies. The P2 fraction contained ∼40% of the 212- and 163-kDa isoforms of ankyrin_B and the 239-kDa isoform of ankyrin_R. Further subfractionation of the P2 by Percoll gradient centrifugation followed by separation of myelin showed association of the three ankyrin isoforms with the synaptosome-rich fraction but not with the myelin-rich fraction. The plasma membrane-rich P3 fraction contained a concentration of ankyrin isoforms similar to that in the P2 fraction. In vitro proteolysis of ankyrin in the P2 fraction with calpain showed that the 212-kDa ankyrin_B was more susceptible to calpain than was ankyrin_R. In the two-vessel occlusion model, ischemia for 30 min generated the 160-kDa fragment of ankyrin_R, and reperfusion for 60 min after 30 min of ischemia remarkably increased the 160-kDa fragment. The reperfusion also significantly decreased the 212-kDa isoform of ankyrin_B. Both ischemia-reperfusion and in vitro proteolysis with calpain generated the 160-kDa fragment of ankyrin_R, suggesting the involvement of calpain.     

大鼠肝及脑组织中微粒体血红素加氧酶同工酶研究

采用离子交换层析和免疫印迹法分离、纯化和分析血红素和苯肼诱导后大鼠肝脏、脑组织.结果显示：纯化诱导后的大鼠肝脏,获得 HO-1和 HO-2,前者活性高于后者为2∶1.未诱导的大鼠肝脏仅获得HO-2,但诱导剂作用后,HO-1活性明显增加,而HO-2未见改变.HO-1和HO-2表观分子质量分别为30 ku和36 ku.诱导剂未作用的肝脏及作用的脑层析后仅获得HO-2活性的洗脱峰.免疫印迹法检测发现大鼠肝脏HO-2抗体与脑HO-2间有交叉反应,与肝脏HO-1无反应.实验表明在诱导剂作用的大鼠肝脏内含HO-1和HO-2同工酶,其中HO-1为诱导型酶.诱导剂作用的脑仅含HO-2.两种构型在表观分子质量,诱导性和免疫化学特性方面明显不同.     

Electroconvulsive Therapy Induces Neurogenesis in Frontal Rat Brain Areas

Electroconvulsive therapy (ECT) is an effective therapy for several psychiatric disorders, including severe major depression, mania and certain forms of schizophrenia. It had been proposed that ECT acts by modulating local plasticity via the stimulation of neurogenesis. In fact, among antidepressant therapies, ECT is the most robust enhancer of neurogenesis in the hippocampus of rodents and non-human primates. The existence of ECT-triggered neurogenesis in other brain areas, particularly in those adjacent to the other main locus of neurogenesis, the subventricular zone (SVZ), had so far remained unknown. Here we show that ECT also strongly enhances neurogenesis in frontal brain areas, especially in the rostro-medial striatum, generating specific, small-size calretinin-positive interneurons. We provide here the first evidence that ECT stimulates neurogenesis in areas outside the hippocampus. Our data may open research possibilities that focus on the plastic changes induced by ECT in frontal limbic circuitry.     

At Least Three Neurotransmitter Systems Mediate a Stress-Induced Increase in c-fos mRNA in Different Rat Brain Areas

1. Protooncogene c-fos mRNA levels were determined in the rat cerebral cortex, hippocampus, and cerebellum after exposure to a combined forced swimming and confinement stress. The stress resulted in an increase in c-fos mRNA levels in all three brain areas.2. In an effort to elucidate the neurotransmitter systems involved in this stress-induced increase, animals were injected, prior to exposure to the stress, with either diazepam, MK-801, or propranolol.3. In both the cerebral cortex and the hippocampus the stress-induced increase in c-fos mRNA was inhibited by MK-801, suggesting that it is mediated via NMDA receptors. In the hippocampus, propranolol had a similar effect, indicating that -adrenergic receptors are also involved in the stress-induced increase in c-fos mRNA.4. On the other hand, the increase in c-fos mRNA produced by the stress of the injection was inhibited in the cerebral cortex by diazepam or propranolol and in the hippocampus only by diazepam. Furthermore, administration of MK-801 resulted in an increase in c-fos mRNA in the hippocampus of the nonstressed animals. In the cerebellum no one of the three drugs employed affected c-fos mRNA levels in either stressed or nonstressed animals.5. Our results thus show that various forms of stress activate, in different brain areas, neurons with either NMDA, -adrenergic, and/or GABA-A receptors.     

Subcellular Localisation of 14-3-3 Isoforms in Rat Brain Using Specific Antibodies

Abstract: The 14-3-3 protein family, which is present at particularly high concentrations in mammalian brain, is known to be involved in various cellular functions, including protein kinase C regulation and exocytosis. Despite the fact that most of the 14-3-3 proteins are cytosolic, a small but significant proportion of 14-3-3 in brain is tightly and selectively associated with some membranes. Using a panel of isoform-specific antisera we find that the ε, η, γ, β, and ζ isoforms are all present in purified synaptic membranes but absent from mitochondrial and myelin membranes. In addition, the η, ε, and γ isoforms but not the β and ζ isoforms are associated with isolated synaptic junctions. When different populations of synaptosomes were fractionated by a nonequilibrium Percoll gradient procedure, the ε and γ isoforms were present and the β and ζ isoforms were absent from the membranes of synaptosomes sedimenting in the more dense parts of the gradient. The finding that these proteins are associated with different populations of synaptic membranes suggests that they are selectively expressed in different classes of neurones and raises the possibility that some or all of them may influence neurotransmission by regulating exocytosis and/or phosphorylation.     

Acute Impact of Selected Pyridoindole Derivatives on Fos Expression in Different Structures of the Rat Brain

The impacts of three pyridoindole derivatives (PDs), designated as PD144, PD143, and PD104, which have previously been shown to have antidepressant (PD144) and anxiolytic (PD143, PD104) properties, were investigated on the Fos expressions in 11 different rat brain areas, including the medial prefrontal cortex, striatum, septum, accumbens nucleus (shell, core), bed nucleus of the stria terminalis, hypothalamic paraventricular nucleus, central amygdala, locus coeruleus, dorsal raphe nucleus, and the solitary tract nucleus. Control rats received vehicle, while the other three groups the PDs in a dose of 25 mg/kg/b.w. The animals were transcardially perfused with a fixative 90 min after the treatments. Coronal sections of 40-µm thickness were processed for Fos-immunostaining by avidin–biotin-peroxidase complex and visualized by nickel-intensified diaminobenzidine complex. Fos-labeled sections were counterstained with neuropeptides including corticoliberine (CRH), oxytocin (OXY), vasopressin (AVP), and vasoactive intestinal polypeptide (VIP) and processed for immunofluorescence staining using Alexa Fluor 555 dye. In all the three groups of animals, the upregulation of PDs-induced Fos expression only in 2 of 11 brain areas was investigated, namely, in the hypothalamic paraventricular nucleus (PVN) and the central amygdaloid nucleus (CeA). The other brain structures studied were devoid of Fos expression. Counterstaining of the Fos-labeled CeA-containing sections with VIP antibody revealed that the Fos expression stimulated by the PDs was upregulated in all the CeA subdivisions (lateral, ventral, capsular), except the medial one. Dual immunoprocessings showed Fos/CRH-labeling in both the PVN and the amygdala and Fos/OXY in the PVN. No Fos/AVP colocalizations were seen in the PVN. The obtained data provide the first view on the intracerebral effects of three new PDs derivatives, which effects were restricted only to the PVN and CeA areas. The present data may help to improve our understanding of the impact of the selected PDs on the brain and to anticipate possible behavioral and neuroendocrine consequences.     

豌豆肌动蛋白异型体的表达与系统发生分析

豌豆 (PisumsativumLinn .)肌动蛋白基因至少可以分为 3类异型体 :PEAcⅠ、PEAcⅡ和PEAcⅢ ,它们的编码区序列相似性很高 ,而非编码区序列存在显著的差异。RT_PCR和以 3′端非翻译区作探针的Southern杂交结果显示豌豆肌动蛋白异型体基因在根、茎、叶、卷须、花粉和幼嫩果实中均表达 ,但表达强度存在明显差异。利用连续稀释电泳对PEAcⅠ的转录本水平进行分析后发现它倾向于在幼嫩的器官中表达 ,且在 7d的茎中表达最强 ;在一个月内的叶片中表达也较强 ,此后明显下降 ;卷须中表达变化不显著 ,在花粉中表达很弱 ,在幼嫩荚果中的表达亦较多。PEAcⅡ表达特点与PEAcⅠ具有某些相似性。根据肌动蛋白序列重建的系统发生树表明豌豆肌动蛋白 3类异型体间的分歧明显 ,但起源于单、双子叶植物分化前的共同基因祖先。推测豌豆肌动蛋白异型体基因在转录调控和细胞功能上存在差异。     

豌豆肌动蛋白异型体的表达与系统发生分析

豌豆(Pisum sativum Linn.)肌动蛋白基因至少可以分为3类异型体: PEAcⅠ、PEAcⅡ和PEAcⅢ,它们的编码区序列相似性很高,而非编码区序列存在显著的差异.RT-PCR和以3′端非翻译区作探针的Southern杂交结果显示豌豆肌动蛋白异型体基因在根、茎、叶、卷须、花粉和幼嫩果实中均表达,但表达强度存在明显差异.利用连续稀释电泳对PEAcⅠ的转录本水平进行分析后发现它倾向于在幼嫩的器官中表达,且在7 d的茎中表达最强;在一个月内的叶片中表达也较强,此后明显下降;卷须中表达变化不显著,在花粉中表达很弱,在幼嫩荚果中的表达亦较多.PEAcⅡ表达特点与PEAcⅠ具有某些相似性.根据肌动蛋白序列重建的系统发生树表明豌豆肌动蛋白3类异型体间的分歧明显,但起源于单、双子叶植物分化前的共同基因祖先.推测豌豆肌动蛋白异型体基因在转录调控和细胞功能上存在差异.