Circadian rhythmicity of the thioredoxin system in cultured murine peritoneal macrophages.

Macrophages play a pivotal role in atherosclerosis through a variety of events related to cellular oxidative stress. This process is mainly due to an excessive production of reactive oxygen species whose elimination occurs through antioxidant systems including the thioredoxin (Trx) system. In this paper, we investigated whether the Trx system would exhibit circadian rhythmicity in dexamethasone synchronized cultured macrophages and monitored the impact of the rhythmicity of Trx-1 on markers of atherosclerosis. We found that the clock-related genes BMAL-1, PER-2, CRY-1 and REV ERB α exhibited a robust circadian expression. However, the Trx genes family (Trx-1, Trx-2, TrxR1 and TXNIP) did not exhibit a circadian expression at the mRNA level in spite of the presence of E-box elements within the promoter regions of TrxR1 and TXNIP genes. Nevertheless, both Trx-1 and TXNIP exhibited a circadian expression at the protein level and proteasome inhibition abolished the rhythmicity of Trx-1. Moreover, we found a link between low Trx-1 level and elevated atherogenic markers such as 4-HNE, TNF-α and cholesterol accumulation in macrophages. Our results indicate that the Trx gene family does not exhibit the same circadian regulation and that the presence of E-box elements in the TXNIP promoter is not sufficient to ensure a circadian rhythmicity at the transcriptional level. In addition, since a link was found between a low level of Trx-1 protein during circadian rhythm and high levels of atherogenic markers, administration of Trx-1 at certain time points could be an interesting approach to protect against atherosclerosis development.

Expression of matrix metalloproteinase-2 and -9 and of tissue inhibitor of matrix metalloproteinase-1 in liver regeneration from oval cells in rat.

Oval cells participate in liver regeneration when hepatocyte replication is impaired. These precursor cells proliferate in periportal regions and organize in ductules. They are surrounded by a basement membrane, the degradation of which by matrix metalloproteinases (MMP) might trigger their terminal differentiation into hepatocytes. We studied the expression of MMP-2 and MMP-9 and that of one of their tissue inhibitors (TIMP-1) in a model of hepatic regeneration from precursor cells. Regeneration was induced by treating rats with 2-acetylaminofluorene followed by partial hepatectomy. MMP-2 and MMP-9 hepatic expression paralleled oval cell number with a peak at day 9-14 after hepatectomy. They were mainly detected in oval cells. TIMP-1 mRNA and oncostatin M receptor mRNA, a major regulator of TIMP-1 synthesis, markedly increased from day 1 after surgery until day 9 and then declined; they were mainly detected in interlobular bile duct cells and oval cells until day 14. In agreement with the in vivo data, the WB-F344 liver precursor cell line expressed MMP-2 and MMP-9, as well as TIMP-1 and oncostatin M receptor. These data suggest that (a) early increased TIMP-1 synthesis by biliary and oval cells favors basement membrane deposition around proliferating ductular structures through MMP inhibition, (b) delayed increased MMP expression, concomitant to decreased TIMP-1 synthesis, leads to basement membrane degradation, preceding oval cell differentiation, (c) the oncostatin M pathway might play a major role in increased TIMP-1 synthesis.

Beta(2)-adrenergic receptor agonists increase intracellular free Ca(2+) concentration cycling in ventricular cardiomyocytes through p38 and p42/44 MAPK-mediated cytosolic phospholipase A(2) activation.

We have recently reported that arachidonic acid mediates beta(2)-adrenergic receptor (AR) stimulation of [Ca(2+)](i) cycling and cell contraction in embryonic chick ventricular cardiomyocytes (Pavoine, C., Magne, S., Sauvadet, A., and Pecker, F. (1999) J. Biol. Chem. 274, 628-637). In the present work, we demonstrate that beta(2)-AR agonists trigger arachidonic acid release via translocation and activation of cytosolic phospholipase A(2) (cPLA(2)) and increase caffeine-releasable Ca(2+) pools from Fura-2-loaded cells. We also show that beta(2)-AR agonists trigger a rapid and dose-dependent phosphorylation of both p38 and p42/44 MAPKs. Translocation and activation of cPLA(2), as well as Ca(2+) accumulation in sarcoplasmic reticulum stores sensitive to caffeine and amplification of [Ca(2+)](i) cycling in response to beta(2)-AR agonists, were blocked by inhibitors of the p38 or p42/44 MAPK pathway (SB203580 and PD98059, respectively), suggesting a role of both MAPK subtypes in beta(2)-AR stimulation. In contrast, beta(1)-AR stimulation of [Ca(2+)](i) cycling was rather limited by the MAPKs, clearly proving the divergence between beta(2)-AR and beta(1)-AR signaling systems. This study presents the first evidence for the coupling of beta(2)-AR to cardiac cPLA(2) and points out the key role of the MAPK pathway in the intracellular signaling elicited by positive inotropic beta(2)-AR agonists in heart.

Differential expression of the rat gamma-glutamyl transpeptidase gene promoters along with differentiation of hepatoblasts into biliary or hepatocytic lineage.

gamma-Glutamyl transpeptidase (GGT), a major enzyme of glutathione (GSH) homeostasis, is often used as a biliary marker to follow the differentiation of hepatic precursor cells. The expression of the GGT gene is driven by different promoters and yields multiple mRNAs, depending on the cell type or the stage of differentiation. In the present study, we analyzed the GGT mRNA expression pattern by quantitative reverse transcriptase-polymerase chain reaction or by in situ hybridization i) in the liver, in vivo, at early stages of development; ii) in oval cells, which proliferate and differentiate into hepatocytes in response to galactosamine injury in vivo; and finally, iii) during hepatoblast differentiation, in vitro. We show that GGT gene transcription originates from promoters P3, P4, and P5 in rat hepatic precursor cells. Differentiation of these cells induces profound alterations in GGT gene expression, leading to extinction of promoters P4 and P5, when they differentiate into the hepatocytic pathway, and to extinction of promoters P3 and P5 when they differentiate into the biliary pathway. This diversity in GGT mRNA expression provides unique molecular probes to follow hepatic precursor cell differentiation. Furthermore, the identification of factors governing GGT P5 and P4 promoter expression should provide further insight into the molecular events that occur as the liver precursor cell differentiates into the hepatic lineages.

Four repeat high-mol-wt MAP2 forms in rat dorsal root ganglia.

The high-mol-wt forms of brain microtubule-associated protein 2 (MAP2a/b) segregate within the dendrites during neuronal differentiation, whereas a low-mol-wt variant, MAP2c, is distributed within all the neuronal domains. Both MAP2b and MAP2c contain three tubulin binding repeats, whereas another low-mol-wt form, MAP2d, contains four repeats. Since high-mol-wt MAP2 species with four repeats have been cloned so far only from the sensory ND cell line, we have studied in this work the high-mol-wt forms expressed by dorsal root ganglia (DRG). Different clones obtained from PCR amplification products of portions of the C-terminal and of the 3' end of the middle MAP2b domains contained either three or four tubulin binding repeats at adult stages and only three postnatally. In adulthood, two exons located at the 3' end of the MAP2b middle domain were missing in several clones: exon 10 within clones with three or four repeats, exon 11 only within those containing four repeats. Several other clones obtained from PCR amplification products of portions of the N-terminal and of the 5' end of the middle MAP2b domains revealed exons 7A and 8. In contrast, Northern analysis revealed exon 8 but not exon 7A, which is probably expressed in trace amounts in the DRG. In this article, we have identified for the first time high-mol-wt MAP2 transcripts containing four tubulin binding repeats that seem to be expressed only by the DRG and also differing from brain MAP2b by a number of other exons.

New forms of HMW MAP2 are preferentially expressed in the spinal cord.

The high molecular weight forms of microtubule-associated protein 2 (MAP2a and b) play a central role in the specification of dendrites. RT-PCR amplification of a portion of the N-terminal and middle MAP2b domains of rat spinal cord cDNAs allowed identification of new variants containing both exon 8 (246 bp) and a new exon, 7A (237 bp), located at the beginning of the middle MAP2b region. The brain and the spinal cord express transcripts containing exon 8, whereas exon 7A alone or exons 7A+8 were detected, whatever the developmental stage, only in the spinal cord.

Diversity of high-molecular-weight tau proteins in different regions of the nervous system.

We show in this work that high-molecular-weight (HMW) tau transcripts are present in all the regions of the CNS and PNS studied, i.e., the dorsal root ganglia (DRG), spinal cord, cerebellum, and forebrain. However, the relative amount of HMW and low-molecular-weight (LMW) tau variants and their sequence vary depending on the region. Two HMW tau variants that contain either both exons 4A and 6 or only exon 6 have been identified in the adult spinal cord by PCR amplification and sequenced. In contrast, a single HMW tau variant that contains exon 4A but not exon 6 was detected in the adult rat DRG. This means that at least part of the HMW tau expressed in the spinal cord is produced locally and not transported within this structure by fibers arising in the DRG. The expression of the HMW tau isoforms is developmentally regulated both quantitatively and qualitatively in the spinal cord. At immature stages very low levels of the HMW tau transcript containing both exons 4A and 6 are expressed, whereas the tau species containing only exon 6 is absent. Rat forebrain, rat cerebellum, and human forebrain express much lower levels of HMW tau transcripts compared with the spinal cord and the DRG. Their sequence contains both exons 4A and 6, i.e., is identical to that of the major HMW tau transcript detected in the adult rat spinal cord. The minor spinal cord species that contains only exon 6 was not identified in the rat forebrain and rat cerebellum but was present among the human brain PCR fragments.(ABSTRACT TRUNCATED AT 250 WORDS)

High and low molecular weight tau proteins are differentially expressed from a single gene.

Both high and low molecular weight (HMW and LMW) tau proteins are expressed in the immature and adult mouse spinal cord. Northern blot analysis, performed with probes complementary to domains common and uncommon to the LMW and HMW entities, suggested that HMW tau proteins found in the immature mouse spinal cord are not translated from the single transcript of 6 kb expressed at these stages, but are transported within this nervous structure by axons arising in the periphery. In contrast, another minor transcript of 8 kb was detected in the adult mouse spinal cord by a HMW tau specific probe, suggesting that a small fraction of the HMW tau forms present in adulthood are translated within mouse spinal cord neurons. LMW spinal cord tau forms are encoded by mRNAs of 6 kb that contain three and four homologous repeats at immature and mature stages, respectively, whereas adult HMW entities contain four repeats. PCR analysis performed with mouse genomic DNA also showed that the nonhomologous region specific for HMW tau is a single exon. Southern blot and gene mapping showed that the same gene, located on the murine chromosome 11, encodes all the LMW and HMW tau variants. All these tau forms, therefore, are produced by an alternative splicing mechanism that is neuron-specific and developmentally regulated.

Expression of high molecular weight tau in the central and peripheral nervous systems.

Using a novel PCR approach, we have cloned a cDNA encoding the entire high molecular weight tau molecule from rat dorsal root ganglia. The resulting 2080 bp cDNA differs from low molecular weight rat brain tau by the insertion of a novel 762 bp region (exon 4a) between exons 4 and 5. This cDNA clone is identical in sequence with a high molecular weight tau (HMW) cDNA from rat PC12 tumor cells and is closely related to a HMW tau cDNA from mouse N115 tumor cells. In vitro transcription/translation produces a protein that migrates on SDS-PAGE with the same apparent molecular weight as HMW tau purified from rat sciatic nerve. The HMW tau protein is generated from an 8 kb mRNA, which can be detected by northern blots in peripheral ganglia, but not in brain. A more sensitive assay using PCR and Southern blot analysis demonstrates the presence of exon 4a in spinal cord and in retina. In combination with immunohistochemical studies of spinal cord, these data suggest that HMW tau, though primarily in the peripheral nervous system, is also expressed in limited areas of the central nervous system, although its presence cannot be detected in the cerebral cortices.

[High molecular weight tau proteins and acquisition of neuronal polarity in peripheral nervous system]. / Protéines tau de haut poids moléculaire et acquisition de la polarité neuronale dans le système nerveux périphérique.

Several variants of the microtubule-associated tau proteins, are expressed during brain development and in adulthood. These entities are required to define the polarity of the neuron and the architecture of the axon but differ in sequence and in their microtubule polymerizing activity. Here, we describe a new group of high molecular weight tau proteins that contain one or two additional exons of 711 and 198 bp in their middle region and a variable N-terminal domain. These high molecular weight tau variants are preferentially expressed in the peripheral nervous system. Immunohistochemical studies showed that they are also present in the dorsal horn of the spinal cord where they are probably transported by sensory fibers arising in the periphery. However, a minor fraction of these proteins is present in the motor neurons of the ventral horn. Similar studies were performed with the neuroblastoma N115 cell line which can be differentiated in vitro and expresses only high molecular weight tau forms. In the non differentiated cells, tau antibodies label the domain of the cell body localized around the centrosome whereas, after differentiation, the cell process facing this structure is also stained. These data suggest that axonal polarity is predetermined by the localization of tau proteins in the domain of the cell body defined by the centrosome.

Primary structure of high molecular weight tau present in the peripheral nervous system.

The tau proteins are a family of brain microtubule binding proteins that are required during axonal outgrowth and are found in neurofibrillary tangles in Alzheimer disease. A protein of higher molecular weight, immunologically related to tau, is expressed in the adult peripheral system and in cultured neuronal cell lines of neural crest origin. The predicted amino acid sequence of the high molecular weight tau from N115 cells has been determined from the sequence of its 2340-base-pair cDNA. High molecular weight tau contains an open reading frame encoding 733 amino acid residues. It contains sequences homologous to those present in the N-, middle, and C-terminal domains of adult brain tau proteins, including four homologous repeats, which are the tubulin binding sites, and an amino acid stretch, which is present only in the N-terminal domain of the mature brain variants. The middle region contains a previously unidentified nonhomologous stretch of 237 amino acid residues as well as a domain of 66 residues homologous to exon 6 of the bovine gene that is absent in all bovine, rat, and mouse tau cDNAs sequenced so far. A cDNA probe specific to the nonhomologous tau insert hybridizes to the 8- to 9-kilobase tau mRNA in N115 cells but not to the 6-kilobase tau mRNA in brain. Probes for the domains common to brain tau isoforms hybridize to both messages. The sequence of high molecular weight tau protein also suggests that it, like low molecular weight tau, is an elongated hydrophilic molecule. This cDNA should allow us to study the role of the domains specific to these tau forms in the specialization of the peripheral nervous system and for study of their expression in normal and pathological states.

Thyroid hormone effects on neuronal differentiation during brain development.

Neurite outgrowth and acquisition of neuronal polarity depend on microtubule assembly and this process is impaired when hypothyroidism is established at late fetal stages in the rat. Taking in account these observations the effects of thyroid hormone deficiency in the developing cerebellum were studied with probes for different tubulin isoforms and for two microtubule-associated proteins, tau and MAP2, which are specific for the axons and the dendrites, respectively. The results showed that thyroid hormone deficiency: 1) desynchronizes the spatio-temporal program of axonal and dendritic differentiation in the cerebellum. 2) Modifies the developmental pattern of expression of various tubulin isoforms. 3) Delays replacement of the immature tau variants by the mature forms. The adult variants of tau proteins specify adult and stable axons whereas the juvenile forms are expressed when axons are growing actively. According to these criteria the hypothyroid brain remains immature at stages when proper connectivity is normally established. Thyroid hormone appears therefore as an epigenic signal that synchronizes axonal and dendritic outgrowth, two major parameters of the construction of the neuronal network.

Regulation of five tubulin isotypes by thyroid hormone during brain development.

Nucleic acid probes derived from the 3' noncoding region of five tubulin cDNAs were used to study the effects of thyroid hormone deficiency on the expression of the mRNAs encoding two alpha (alpha 1 and alpha 2)- and three beta (beta 2, beta 4, and beta 5)-tubulin isotypes in the developing cerebral hemispheres and cerebellum. The content of alpha 1, which markedly declines during development in both brain regions, is maintained at high levels in the hypothyroid cerebellum, whereas it is decreased in the cerebral hemispheres. The alpha 2 level also declines during development and is decreased in both regions by thyroid hormone deficiency, but only during the two first postnatal weeks. Thyroid hormone deficiency slightly increases at all stages the beta 2 level in the cerebellum, whereas a decrease is observed at early stages in the cerebral hemispheres. The beta 5 level seems to be independent of thyroid hormone in the cerebral hemispheres, whereas it decreases at early stages in the hypothyroid cerebellum. Finally, the expression of the brain-specific beta 4 isotype is markedly depressed by thyroid hormone deficiency, particularly in the cerebellum. These data suggest that the genes encoding the tubulin isotypes are, directly or not, differently regulated by thyroid hormone during brain development. This might contribute to abnormal neurite outgrowth seen in the hypothyroid brain and therefore to impairment in brain functions produced by thyroid hormone deficiency.

Regulation by thyroid hormone of microtubule assembly and neuronal differentiation.

In this review we examine successively: 1) the major effects of thyroid hormone deficiency seen during brain development with special emphasis on the changes in neuronal morphology and migration occurring postnatally in the cerebellum. 2) The effects of this hormone on microtubule assembly during neurite outgrowth and acquisition of neuronal polarity. 3) The changes in expression of the different tubulin isoforms occurring during development in the normal and hypothyroid rat brain. 4) The regulation by thyroid hormone of the transition occurring during development between the juvenile and adult microtubule-associated protein Tau.

Splicing of juvenile and adult tau mRNA variants is regulated by thyroid hormone.

The effect of thyroid hormone on the expression of tau transcripts was studied during postnatal brain development. The level of tau mRNA was only slightly changed postnatally in the cerebral hemispheres of hypothyroid rats, whereas the level of tau mRNA in the cerebellum was maintained at a higher level than in the euthyroid controls. As shown by in situ hybridization studies, such an alteration in tau mRNA expression can be ascribed to an effect of thyroid hormone on the rate of migration of the granule cells in the cerebellum; that tau mRNAs remain high in the cerebellum as long as the granule cells are migrating correlates with the observation that hypothyroidism slows the rate of migration of granule cells. RNase protection assays also showed that thyroid hormone deficiency delays the transition between the immature and mature tau transcripts in both brain regions. Thus, one of the effects of thyroid hormone is to regulate the splicing mechanism that allows replacement of the juvenile tau variants by the adult entities during neuronal differentiation.

Expression of Tau protein and Tau mRNA in the cerebellum during axonal outgrowth.

UNLABELLED: "In situ" hybridization and immunohistochemical analysis of the expression of Tau mRNAs and Tau proteins in the developing cerebellum showed that: 1. At early postnatal stages Tau mRNAs are expressed in the deeper region of the external granular layer (EGL II) i.e. in the cells that begin to migrate from the proliferative zone. Little labeling was seen in the upper layer (EGL I) where the cerebellar interneurons actively proliferate during the first two postnatal weeks. Anti-Tau antibodies failed to detect Tau proteins both in EGL I and II. 2. Tau transcripts were also clearly detected in the migrating cells present in the molecular layer; no Tau immunoreactivity was seen in this layer. This suggests that Tau mRNAs remain very poorly translated in the migrating granule cells and in the other interneurons. 3. Tau proteins begin to be detected at postnatal day 8 in the molecular layer but only at the level of the parallel fibers that are present in the Purkinje cell dendritic field. This suggests that the Tau mRNAs transcribed in the migrating cells are not actively translated for several days and that Tau proteins accumulate only in the more mature sections of their axons, the parallel fibers. IN CONCLUSION: Tau mRNAs are transcribed in the migrating cells several days before Tau proteins are actively translated and transported to their axons. Tau proteins accumulation occurs only at the end of granule cell migration i.e. when the parallel fibers interact with their post-synaptic counterparts, the dendrites of the Purkinje cells. Thus, axonal outgrowth and differentiation seem to be a multistep process.

Timing of expression of tau and its encoding mRNAs in the developing cerebral neocortex and cerebellum of the mouse.

The expression of tau mRNA and of the corresponding encoded protein variants was studied during postnatal development in two brain regions differing in their timing of differentiation: the cerebral neocortex and the cerebellum. (a) The expression of tau mRNA was different in the two regions. Maximal contents were found at early stages in the cerebral neocortex, with a 10-fold decrease at later stages. In the cerebellum, two peaks of tau mRNA were observed soon after birth and in adulthood, with minimal values at postnatal day 6. (b) The expression of total tau proteins was similar to that of their encoding mRNAs in the cerebral neocortex, i.e., high concentrations after birth and low contents at later stages. In contrast, two peaks of tau proteins were observed in the cerebellum: the first perinatally and the second with a maximum at postnatal day 15. (c) Both in the cerebral neocortex and especially in the cerebellum, increasing concentrations of mature tau variants were expressed at late developmental stages, i.e., when total tau protein contents were decreased. In conclusion, the fluctuations in expression of tau and of its encoding mRNA seen in the cerebellum seem to reflect differences in the timing of differentiation of the various cell types, i.e., the macroneurons and the interneurons, present in this brain region. The adult tau variants appear in both the neocortex and the cerebellum only at late developmental stages, i.e., when most of the circuitry has been established, although these two regions markedly differ in their timing of differentiation.

Expression of the mRNA for tau proteins during brain development and in cultured neurons and astroglial cells.

Two tau cDNA probes of 1.6 and 0.3 kilobases (kb) have been used to study the expression of the tau mRNAs during mouse brain development and in highly homogeneous primary cultures of neurons and astrocytes. (1) Whatever the stage, a 6-kb mRNA was detected with the two probes. In the astrocytes a 6-kb mRNA hybridized clearly only with the 1.6-kb probe. (2) During brain development the abundance of tau mRNA increases from a late fetal stage (-4 days) until birth, remains high until 6 days postnatal, and then markedly decreases to reach very low values in adulthood. Such a marked decrease in the abundance of tau mRNA parallels that of alpha-tubulin mRNA. These data suggest that: (1) depending on the stage of development and on the cell type (neurons or astrocytes) tau mRNAs of the same size encode several tau proteins differing in molecular weight: several tau proteins are expressed either during early stages of development (juvenile tau proteins of 48 kilodaltons) or in adulthood (mature tau proteins of 50-70 kilodaltons) or are specific of the astrocyte (83 kilodaltons). (2) The expression of the two major components of axonal microtubules, tubulin and tau proteins, seems to be developmentally coordinated.

Both adult and juvenile tau microtubule-associated proteins are axon specific in the developing and adult rat cerebellum.

Several antibodies directed against the heterogeneous microtubule-associated protein group tau have been used to determine the immunocytochemical localization of these proteins in the developing rat cerebellum. Immunoblot analysis of brain extracts showed that both monoclonal and polyclonal anti-tau antibodies revealed not only the adult tau proteins (50,000-70,000 mol. wt) but also the immature (48,000 mol. wt) tau form. Immunocytochemical studies showed that, whatever the stage of development, anti-tau antibodies stained several types of axonal fibres. The Purkinje cell bodies and their dendrites were never significantly labelled. This means that immature tau is, as adult tau, localized essentially in axons. Axonal labelling seems to follow the cerebellar developmental pattern. For instance, the climbing fibres which reach the cerebellum during the embryonic life were stained soon after birth by the anti-tau antibodies. In contrast, the parallel fibres, that begin to develop perinatally, do not express tau at early (5 days) postnatal stages; a clear labelling of the deeper parallel fibres (which are more mature than the superficial ones) was seen at day 10 after birth in the vicinity of the developing dendrites of the Purkinje cells. This suggests that (1) the appearance of tau immunoreactivity reflects a certain stage of maturity of the parallel fibre; (2) both immature and mature tau microtubule-associated proteins seem to be axon specific in the developing rat cerebellum.(ABSTRACT TRUNCATED AT 250 WORDS)

Expression of microtubule-associated proteins during the early stages of neurite extension by brain neurons cultured in a defined medium.

Immunoblotting analysis was used to identify the microtubule-associated proteins (MAPs) present in cultures of mouse brain neurons. Polyclonal antibodies were raised against the two main adult brain MAPs, i.e., MAP2 (300 kDa) and tau (60-70 kDa). Whatever the stage of the culture, which was performed in a defined medium (3 or 6 days), the anti-MAP2 serum detected several high-molecular-weight components (including MAP2) and an entity with 62-65 kDa. Anti-tau revealed essentially a major peak of 48 kDa (young tau) but also slightly cross-reacted with the 62-65 kDa entity. During the culture period (0-6 days) the cells developed progressively a dense neuritic network; the concentration of the different MAPs increased in parallel but at different rates depending on the different species. The increase in concentration of the high-molecular-weight components occurred before that of 48-kDa tau. This suggests that high-molecular-weight MAPs and 48-kDa tau might be involved respectively in the initiation and elongation of neurites. In contrast, and since the main developmental changes in tau composition seen in vivo did not occur during the time course of the culture, this transition might be related to later events of neuronal differentiation.