Controlled targeting of tyrosine hydroxylase protein toward processes of locus coeruleus neurons during postnatal development

Locus Coeruleus Dysfunction in Transgenic Rats with Low Brain Angiotensinogen

AIMS

Transgenic TGR(ASrAOGEN)680 (TGR) rats with specific downregulation of glial angiotensinogen (AOGEN) synthesis develop cardiovascular deficits, anxiety, altered response to stress, and depression. Here, we evaluated whether these deficits are associated with alteration of the integrity of the noradrenergic system originating from locus coeruleus (LC) neurons.

METHODS

Adult TGR rats were compared to control Sprague Dawley rats in terms of the following: tissue levels of transcripts encoding noradrenergic markers, tissue tyrosine hydroxylase (TH) protein level, in vivo TH activity, density of TH-containing fibers, behavioral response to novelty, locomotor activity, and polysomnography.

RESULTS

TH expression was increased in the LC of TGR rats compared to controls. In LC terminal fields, there was an increase in density of TH-containing fibers in TGR rats that was associated with an elevation of in vivo TH activity. TGR rats also displayed locomotor hyperactivity in response to novelty. Moreover, polysomnographic studies indicated that daily paradoxical sleep duration was increased in TGR rats and that the paradoxical sleep rebound triggered by total sleep deprivation was blunted in these rats.

CONCLUSIONS

Altogether, these results suggest that disruption of astroglial AOGEN synthesis leads to cardiovascular, cognitive, behavioral, and sleep disorders that might be partly due to LC dysfunction.

Early undernutrition decreases the number of neurons in the locus coeruleus of rats

The effects of perinatal undernutrition on the number of neurons and apoptotic cells of the locus coeruleus (LC) of female and male rats at postpartum days 7, 12, 20, 30 and 60 were studied. Undernutrition reduces the number of neurons in both sexes without affecting cell death, as indicated by the ratio of apoptotic cells to neurons. The data suggest that in the undernourished groups lower rates of neurogenesis and proliferation (neurogenetic/proliferation rates) might avoid these animals achieving the number of LC neurons as in the control subjects. Although food restriction in both sexes apparently provokes the loss of cells, the effect does not appear to be equal in females and males, as shown by post weaning food rehabilitation. The results suggest that severe food deprivation may interfere with the ontogenetic processes underlying neuronal differentiation of the LC. Morphological damage in the LC due to undernutrition might alter the physiology of sexual and/or feeding behaviours in which this structure is implicated.

Electrophysiological properties of catecholaminergic neurons in the norepinephrine-deficient mouse

To determine how norepinephrine affects the basic physiological properties of catecholaminergic neurons, brain slices containing the substantia nigra pars compacta and locus coeruleus were studied with cell-attached and whole-cell recordings in control and dopamine beta-hydroxylase knockout (Dbh -/-) mice that lack norepinephrine. In the cell-attached configuration, the spontaneous firing rate and pattern of locus coeruleus neurons recorded from Dbh -/- mice were the same as the firing rate and pattern recorded from heterozygous littermates (Dbh +/-). During whole-cell recordings, synaptic stimulation produced an alpha-2 receptor-mediated outward current in the locus coeruleus of control mice that was absent in Dbh -/- mice. Normal alpha-2 mediated outward currents were restored in Dbh -/- slices after pre-incubation with norepinephrine. Locus coeruleus neurons also displayed similar changes in holding current in response to bath application of norepinephrine, UK 14304, and methionine-enkephalin. Dopamine neurons recorded in the substantia nigra pars compacta similarly showed no differences between slices harvested from Dbh -/- and control mice. These results indicate that endogenous norepinephrine is not necessary for the expression of catecholaminergic neuron firing properties or responses to direct agonists, but is necessary for auto-inhibition mediated by indirect alpha-2 receptor stimulation.

Angiotensin II AT-1A receptor immunolabeling in rat medial nucleus tractus solitarius neurons: subcellular targeting and relationships with catecholamines

The angiotensin II AT-1A receptor (AT-1A) is the major mediator of the hypertensive actions of angiotensin II (ANG II) in the medial nucleus of the solitary tract (mNTS). The localization of the AT-1A receptor at surface or intracellular sites is an important determinant of its signaling properties, including intercellular or intracrine communication. However, the spatial localization of this protein, particularly within small distal or intermediate size dendrites of mNTS neurons, is unknown. Within the mNTS, ANG II and catecholamines interact in the regulation of autonomic function; however, it is unknown if AT-1A receptors are present at functional sites in catecholamine containing dendrites, or are contacted by catecholamine containing axon terminals. We compared surface and intracellular distributions of the AT-1A receptor in dendritic processes from the mNTS using immunogold electron microscopy in conjunction with immunoperoxidase labeling for tyrosine hydroxylase (TH) and morphometric analysis. Collapsed across all AT-1A-labeled dendritic profiles, immunogold labeling was more frequent in intracellular sites as compared with the plasma membrane. Small (<0.6 microm) dendritic profiles contained a higher ratio of particles associated with the surface membrane when compared with larger profiles. Approximately 27% of all AT-1A receptor-labeled dendritic profiles also contained labeling for TH. Approximately 12% of dendritic profiles single labeled for the AT-1A receptor were contacted by TH containing axons or axon terminals. The present results provide the first quantitative demonstration of select plasmalemmal and intracellular localizations of AT-1A receptors in dendritic processes of mNTS neurons, including those containing TH, or contacted by catecholaminergic axon terminals. These results suggest that AT-1A receptors are positioned for modulation of catecholamine signaling in the mNTS.

Delayed maturation of catecholamine phenotype in nucleus tractus solitarius of rats with glial angiotensinogen depletion

Cerebral catecholamines and angiotensins are both involved in the regulation of cardiovascular function. Recent in vitro studies have suggested that angiotensin II modulates noradrenergic neurotransmission by controlling both the expression and neuritic trafficking of tyrosine hydroxylase (TH), the rate-limiting enzyme in catecholamine biosynthesis. To assess the potential existence of such mechanisms in vivo, we compared TH phenotype ontogeny in the nucleus tractus solitarius (NTS), which is the first central relay of the baroreflex, between control Sprague-Dawley rats and TGR(ASrAOGEN) rats (TG) with glial specific angiotensinogen (AOGEN) depletion. TG displayed a delayed increase in both TH-mRNA and TH protein levels, which sharply rises in the NTS of control rats within the fourth week. The delayed maturation of TH phenotype also affected the presence of TH protein in the neuropil, not only within the NTS region but also within the ventrolateral medulla. This was evidenced by a large decrease in the density of TH-containing neuronal processes in TG at 4 weeks only, without noticeable modification of the labeling of the neuritic marker MAP2, suggesting that neuritic trafficking of TH protein was transiently altered. These results indicate that glial AOGEN is crucial to coordinate within the fourth week the mechanisms driving the maturation of NTS catecholaminergic neurons and suggest that impairment of the central angiotensinergic system early in development can lead to cardiovascular dysfunction related to altered maturation of catecholaminergic neurons located in both the dorsal and the ventrolateral medulla.

Singular subsets of locus coeruleus neurons may recover tyrosine hydroxylase phenotype transiently expressed during development

The number of tyrosine hydroxylase (TH)-expressing neurons appears to be precisely determined in basal conditions within the noradrenergic pontine nucleus locus coeruleus (LC). However, additional neurons exhibiting TH phenotype have been observed in the adult rat LC following a single administration of RU 24722, a potent inducer of TH expression specific to the LC. The neurons acquiring TH phenotype following treatment had a topographical localization similar to that of the neurons, which transiently expressed TH during postnatal development and lost TH phenotype during the third postnatal week. The idea that the fluctuation of TH phenotype in singular subsets of LC neurons during development may be selectively restored in adults is of particular interest. The present study attempted to determine whether the cells in which TH expression was repressed during the third postnatal week could correspond to those which exhibited TH phenotype in response to RU 24722 treatment in adults. We first verified that no massive cell death occurred in the LC during the period ranging from days 13 to 30. Then, we observed that both cell populations exhibited the same altered steady-state concentration of TH-mRNA as compared to cells that permanently expressed TH. Finally, we demonstrated the presence of TH-negative neurons expressing the homeodomain transcription factor Phox2a, specific for the determination of noradrenergic phenotype, providing further evidence that "resting-noradrenergic" neurons exist in the adult rat LC under basal conditions. These neurons provide interesting prospective for gain of noradrenergic function when classical noradrenergic LC neurons are impaired.

In situ examination of tyrosine hydroxylase activity in the rat locus coeruleus using (3',5')-[(3)H(2)]-alpha-fluoromethyl-tyrosine as substrate of the enzyme

Tyrosine hydroxylase (TH) activity can be modified by changes in the specific activity of the enzyme (SA(TH)) or in the levels of active enzyme. We developed a methodology making it possible to measure with excellent anatomical resolution TH enzymatic activity and TH protein quantity by quantitative autoradiography and immunoautoradiography, respectively, from adjacent sections taken at serial intervals along the longitudinal extent of a same brain. SA(TH) was estimated by the slope of linear regressions established between TH activity and TH quantity measured at each anatomical plane. To evaluate TH activity, we used (3',5')-[(3)H(2)]-(D, L)-alpha-fluoromethyl-tyrosine [(3)H(2)]-MFMT, which is transformed by TH to [(3)H]-MFM-dopa, a potent and irreversible substrate for aromatic amino acid decarboxylase. We found that the SA(TH) in the cell body area of the LC (PKA) was 48% lower than that evaluated in the surrounding pericoerulean neuropil (PCN). In the PCN, 22% only of TH level exhibited a level of enzymatic activity above threshold. We also examined how SA(TH) was distributed in the LC 15 min and 3 days after RU 24722 treatment, a potent phasic and tonic activator of TH enzyme in noradrenergic neurons. Two distinct mechanisms have been observed: the short-term effect was due to an increase in the SA(TH) in the PKA only, while the long-term effect was mainly caused by an increase in the number of active TH proteins in the PCN. These results suggest that the fine regulation of TH activity which occurs in the different compartments of LC neurons may be critical in the functions involving the LC.

Plasticity of tyrosine hydroxylase gene expression within BALB/C and C57Black/6 mouse locus coeruleus

The plasticity of tyrosine hydroxylase (TH) phenotype in the locus coeruleus (LC) of two pure inbred strains of mice, Balb/C (C) and C57Black/6 (B6), was investigated at the molecular level by radioactive in situ hybridization. The results demonstrated that in basal conditions, C mouse LC contains less TH-mRNA-expressing cells than B6. After RU 24722-treatment, which induces long lasting TH gene expression in the LC, we previously reported an increase in TH-expressing cell number in C mouse LC only, equalizing TH phenotype between the two strains. Here, we demonstrate that strain specific plasticity of TH phenotype detected in spatially organized cells is associated with the regulation of TH-mRNA expression above a detectable level. These results suggest that interstrain differences and pharmacologically-induced phenotypic plasticity in TH phenotype may occur at the transcriptional level.