Leon Carlock

Simultaneous reduction on the sarcolemmal and SR calcium ATPase activities and gene expression in cardiomyopathic hamster

Altered calcium regulation is a prominent feature in the hereditary cardiomyopathy of the Syrian hamster. However, the activity of the two systems necessary for intracellular calcium homeostasis in the heart, the sarcolemmal and sarcoplasmic reticulum calcium ATPase pumps, have not been correlated. Using age- and pair-matched myopathic and control hamsters, a simultaneous reduction in gene expression and enzyme activity for these two pumps has been demonstrated. The concomitant alteration in gene expression as early as 1 month of age, preceding noticeable myocytolysis suggests that the depressed activity in these two calcium ATPase systems is not due to cell necrosis but at least in part due to reduction in their mRNA levels. Reduced capacity of the calcium pumps would result in calcium overload as well as impaired contractility that leads to the eventual heart failure in this animal model.

Preprotachykinin and preproenkephalin mRNA expression within striatal subregions in response to altered serotonin transmission

The effects of lowered serotonin (5-hydroxytryptamine; 5-HT) neurotransmission on preprotachykinin (PPT) and preproenkephalin (PPE) mRNA levels were examined in subregions of the striatum. Adult male rats were treated systemically with para-chlorophenylalanine (pCPA; 350 mg/kg single i.p. injection) which reduced forebrain 5-HT amounts to approximately 20% of saline-injected controls at 24 and 48 h. As measured by Northern analysis, PPT and PPE mRNA levels were elevated 50% and 160% respectively in the anterior ventromedial striatum (region included nucleus accumbens). PPT mRNA levels were raised 90% in posterior striatum (at the level of the globus pallidus) by 48 h post-pCPA injection. To determine if increased PPT and PPE mRNA levels represented a transient response to brief 5-HT inhibition, additional experiments were performed to provide continual suppression of 5-HT within the striatum. First, rats received daily intraperitoneal injections of saline or the 5-HT1A receptor agonist, 8-OH-DPAT (1 mg/kg), for 7 days to reduce 5-HT release from raphestriatal terminals. In a parallel experiment, the serotonin neurotoxin, 5,7-dihydroxytryptamine (5,7-DHT, 5 micrograms), was stereotaxically injected into the striatum as a means to permanently remove 5-HT terminals. Although levels of each mRNA species were differentially sensitive to 5,7-DHT or 8-OH-DPAT, PPT and PPE mRNAs were lowered between 30-55% within the anterior dorsolateral and ventromedial striatum. Although these results support previous studies suggesting an overall positive regulatory role of serotonin on striatal tachykinin biosynthesis, PPT and PPE gene regulation in certain striatal subregions may by differentially sensitive to lowered 5-HT neurotransmission. This suggestion is supported by observations that acute systemic stimulation of 5-HT2A/C receptors with DOI (7 mg/kg single i.p. injection) raised PPT and PPE mRNA levels within anterior dorsolateral (30-60%) and posterior (100-200%) striata, but not within the anterior ventromedial striatum.

NMDA receptor overstimulation triggers a prolonged wave of immediate early gene expression: relationship to excitotoxicity.

Exposure of the rodent striatum to quinolinic acid (QA, N-methyl-D-aspartate receptor agonist) induces immediate early gene (IEG; c-fos, c-jun, jun-B, zif/268) expression that may extend 12-24 h after injection. In order to determine the specificity of the prolonged IEG response to the QA injection, the temporal pattern of c-fos mRNA expression was examined during the first 4 h after administration of saline or QA (40 micrograms). As early as 30 min after intrastriatal injection, both saline and QA increased c-fos mRNA levels. In the saline group, this increase in IEG expression was only transient and returned to baseline by 1 h. In contrast, c-fos mRNA levels within QA-injected animals continued to rise significantly at 1 and 4 h. In a second experiment, rats received 4 ng to 40-micrograms injections of QA followed by sacrifice at 6 h to determine if increasing QA doses caused the appearance of the prolonged IEG response phase. The prolonged IEG response was evident at 6 h only in animal groups that received higher dose ranges (4-40 micrograms) of QA. A final experiment was undertaken to determine if blockage of NMDA receptor stimulation would also inhibit the prolonged IEG response at 6 h in relationship to neuronal sparing evidenced at 24 h post-QA injection. The NMDA receptor antagonist, MK-801, blocked the prolonged IEG response at 6 h following QA (40 micrograms) injection while also preventing striatal neuropeptide mRNA decline by 24 h. Delaying the MK-801 administration for 1-2 h post-QA injection revealed that the intensity of the prolonged IEG mRNA response may be predictive of neuronal demise within the QA lesion site. These results suggest that prolonged IEG expression is associated with QA excitotoxicity of the rodent striatum and subsequent neuronal degeneration.

The identification of a functional nuclear localization signal in the Huntington disease protein.

Positional cloning has shown that the Huntington disease (HD) mutation is an expanded trinucleotide repeat in the IT15 gene. Although this mutation clearly produces the HD phenotype, the function of the Huntington disease protein remains undefined. One recent immunocytochemical study suggested that the IT15 protein preferentially localizes to the nucleus of affected neuronal cells. If this result is accurate, it could link the biochemical function of this protein to nuclear activities such as gene regulation. To examine the nuclear transport of the Huntington disease protein, we searched for basic peptide motifs that could produce nuclear localization. One peptide (RRKGKEK) was identified that is highly homologous to a consensus nuclear localization signal. When fused to the cytoplasmic reporter protein, beta-galactosidase, nuclear localization was observed in stably transformed human cell lines. In a complementary study, an anti-peptide polyclonal antibody, raised against a sequence adjacent to the putative nuclear localization sequence, detected the IT15 protein in the nucleus of human cells. These results extend and confirm the previous localization studies and identify an IT15 peptide motif that can function for nuclear localization.

Proteolipid Protein mRNA Stability Is Regulated by Axonal Contact in the Rodent Peripheral Nervous System

Proteolipid protein (PLP) and its alternatively spliced isoform, DM20, are the main intrinsic membrane proteins of compact myelin in the CNS. PLP and DM20 are also expressed by Schwann cells, the myelin-forming cells in the PNS, and are necessary for normal PNS function in humans. We have investigated the expression of PLP in the PNS by examining transgenic mice expressing a LacZ transgene under the control of the PLP promoter. In these animals, myelinating Schwann cells expressed beta-galactosidase more prominently than nonmyelinating Schwann cells. PLP/DM20 mRNA levels, but not those of LacZ mRNA, increased during sciatic nerve development and decreased after axotomy, with resultant Wallerian degeneration. PLP/DM20 transcription rates, in nuclear run off experiments, however, did not increase in developing rat sciatic nerve despite robust increases in PLP/DM20 mRNA levels during the same period. In RNAse protection studies, PLP mRNA levels fell to undetectable levels following nerve transection whereas levels of DM20 were essentially unchanged despite both being transcribed from the same promoter. Finally, cotransfection studies demonstrated that PLP-GFP, but not DM20-GFP mRNA is down-regulated in Schwann cells cultured in the absence of forskolin. Taken together these data demonstrate that steady state levels of PLP mRNA are regulated at a posttranscriptional level in Schwann cells, and that this regulation is mediated by Schwann cell-axonal contact. Since the difference between these two mRNAs is a 105-bp sequence in PLP and not in DM20, this sequence is likely to play a role in the regulation of PLP mRNA.

Trafficking of PLP/DM20 and cAMP signaling in immortalized jimpy oligodendrocytes.

The synthesis, transport, and insertion of jimpy proteolipid protein and DM20 were studied in normal (158N) and jimpy (158JP) immortalized oligodendrocyte lines. Four different expression vectors encoding fusion proteins composed of native PLP and DM20 or jimpy PLP or DM20 were linked to enhanced green fluorescent protein (EGFP). All four transfected fusion proteins had similar distributions in the cell bodies and processes of the two cell types. Both normal and jimpy PLP‐EGFP and DM20‐EGFP were detected in both cell lines as far as 200 μm from the cell body, indicating synthesis and transport of mutated PLP and DM20 toward the plasma membrane. Immunocytochemistry of fixed normal and jimpy cells with the O10 antibody, which recognizes a conformationally sensitive PLP/DM20 epitope, confirmed that normal and jimpy PLP and DM20 were transported to the plasma membrane. Live staining of normal and jimpy cells transiently transfected with the native PLP showed positive staining, indicating PLP was correctly inserted into the membrane of both normal and jimpy oligodendrocytes. However, live staining of normal and jimpy cells transiently transfected with jimpy PLP showed no positive staining, indicating the mutated protein is abnormally inserted into the plasma membrane. Electrophysiological recordings of the resting membrane potential measured in the whole cell mode of the patch‐clamp technique showed the absence of a developmentally regulated negative shift in the membrane potential in jimpy cells compared to normal native or immortalized oligodendrocytes. Treatment of 158N cells and native oligodendrocytes with dibutyryl cAMP (dbcAMP) caused morphological and biochemical differentiation, but failed to do so in 158JP cells, suggesting an abnormal signaling pathway in jimpy. The defect in cAMP signaling in jimpy oligodendrocytes was associated with the suppression of increase in mRNA level of the inducible cAMP early repressor (ICER). When the jimpy oligodendrocyte line was transfected with normal PLP or DM20 and exposed to dbcAMP, the cells failed to differentiate. This finding suggests that improper insertion of jimpy protein into the plasma membrane alters the membrane in such a way that certain signaling pathways are permanently altered. The abnormal insertion of jimpy PLP/DM20 into the plasma membrane may be the basis for the lack of cell signaling and abnormal resting potential in jimpy oligodendrocytes. GLIA 40:300–311, 2002.

Transcription of the Huntington disease gene during the quinolinic acid excitotoxic cascade.

&NA; Although Huntington disease (HD) is characterized by the selective neurodegeneration of the basal ganglia and cerebral cortex, efforts to define the disease pathology have been complicated by the widespread expression of the disease gene (IT15) throughout the body. In this study, we examined IT15 mRNA levels during the quinolinic acid (QA) excitotoxic cascade to determine whether neuronal and/or glial expression is regulated by neurodegeneration. Following an initial increase between 1 h and 6 h, IT15 mRNA levels declined in a pattern homologous to a group of neuron‐specific genes. Decreased mRNA levels after 24 h demonstrated that glial transcription is not activated by neurodegeneration or gliosis. The 1 h and 24 h mRNA levels strongly suggest that IT15 transcription preferentially localizes to degenerating neurons.

Identification and cloning of a brain autoantigen in neuro-behavioral SLE.

In murine models of SLE, particular patterns of abnormalities of social interaction and memory collectively known as neurobehavioral dysfunction (NBD) correlate with the occurrence of brain reactive autoantibodies. Study of the immunopathogenic effects of these antibodies has been limited by the absence of isolated autoantibodies and antigens. In order to identify the molecular targets, we isolated autoantibodies highly specific for brain plasma membranes from MRL/lpr mice. After immunoscreening a brain expression library with these brain specific autoantibodies, we identified a single cDNA clone of unique sequence and relevant anatomic distribution. Transcript for this cDNA is wide spread among mammalian species but appears to be present only in the brain. Addition features, suggesting this cDNA is pertinent for further study include (1) the expressed protein, called lupus brain antigen 1, reacts with the screening immunoglobulins as well as immunoglobulins from other strains of murine neuro-SLE not used to screen the library, but not with immunoglobulins from normal mice, (2) the transcript distribution within the brain is similar to immunochemical localization of binding of the spontaneous autoantibodies and (3) the localization of transcript within the brain, in the hippocampus, hypothalamus an cingulate gyrus, corresponds to anticipated anatomical regions of clinical dysfunction. Further, the transcript is a large, potentially structural molecule of unique sequence. Antibodies to this molecule may mediate changes in behavior either by direct interactions with the cognate antigen or by indirect influences through neuro-endocrine axes.

Variable subcellular localization of a neuron-specific protein during NTera 2 differentiation into post-mitotic human neurons

The current report describes the molecular characterization of the human (the D4S234 locus) and mouse (the m234) homologs of a gene that was isolated during our genomic analysis of the Huntington disease gene region. Sequence comparisons of full-length cDNA clones revealed that the mouse and human homologs encoded evolutionarily conserved 21-kDa proteins with greater than 90% amino acid sequence identity. Extensive sequence identity between the D4S234 gene and the rat p1A75 gene (a previously identified rat neuron-specific gene) showed that these genes are interspecies homologs. Furthermore, the D4S234 protein exhibited significant amino acid similarity to a 19-kDa mouse protein that localizes to the Golgi apparatus of embryonic neurons. However, nonconservative sequence differences suggested that these genes are independent members of a multigene family. Northern analyses revealed that rodent D4S234 expression occurred predominantly in the brain and included all brain regions. Neuron-specific expression was demonstrated using Northern analysis of cultured glial cells and quinolinic acid-treated rat brain samples. Minimal amounts of the rodent D4S234 mRNA were detected prenatally; however, elevated adult levels were detected within 1 month of birth. Sequence analyses of the human and mouse D4S234 proteins identified an evolutionarily conserved hydrophobic sequence and a consensus nuclear localization signal in both genes. Immunofluorescence microscopy, using an antipeptide antibody, established that the human D4S234 protein preferentially localized to the nucleus of mitotic cultured cells. Since the rat p1A75 protein was previously mapped to the neuronal cytoplasm by in situ hybridization, the subcellular localization of the D4S234 protein was subsequently examined during differentiation of the NTera 2 (NT2) cell line. Following differentiation into postmitotic NT2-N neurons, the D4S234 protein demonstrated cytoplasmic staining and reduced or undetectable nuclear staining in many cells. The variation in the intracellular localization of the D4S234 protein in mitotic and nonmitotic cells suggests that the subcellular localization of this protein is developmentally regulated and provides clues about the biochemical function of this protein.

Timing the excitotoxic induction of heat shock protein 70 transcription

The time course of heat-shock protein 70 (HSP70) transcriptional induction was compared with neuronal- and non-neuronal-specific mRNAs following intrastriatal quinolinate (QA) injection. Within one hour of QA exposure, immediate-early gene (IEG; c-fos) activation preceded slight increases in glutamic acid decaroxylase (GAD) mRNA levels. However, glial fibrillary acid protein (GFAP) and HSP70 mRNA levels remained constant. After one hour, HSP70 mRNA levels surged 6 fold during a delayed transcriptional phase that was induced between 4-12 hours. This phase was characterized by massive increases in c-fos and GFAP mRNAs while GAD transcripts fell drastically suggestive of neuronal death. Therefore HSP70 genes may play an important role in glial/immune activation following rapid excitotoxic damage by direct injections of quinolinate.