Neuropeptide Y modulates excitatory synaptic transmission in the olfactory bulb.

Although the olfactory bulb contains one of the highest concentrations of neuropeptide Y in the CNS, its function in the bulb remains unclear. In this study, we used whole-cell electrophysiological, molecular, and primary culture techniques to investigate neuropeptide Y gene expression and neuromodulatory actions of neuropeptide Y on rat olfactory bulb neurons. Northern analysis showed that neuropeptide Y mRNA increases with animal age or time in culture, in a parallel manner. In electrophysiology experiments, agonists that activate neuropeptide Y receptors (whole neuropeptide Y) and the Y2 receptor subtype (neuropeptide Y 13-36) reduced spontaneous excitatory activity in bulb interneurons. In investigating potential presynaptic effects, both agonists reduced the amplitude of calcium channel currents in the presynaptic (mitral/tufted) cell. Also consistent with a presynaptic effect, both agonists reduced the frequency but not the amplitude of miniature excitatory postsynaptic currents (or "minis") in interneurons. In examining potential postsynaptic effects, both agonists slightly increased membrane resistance but had no effect on currents evoked by glutamate. Together, these data suggest that neuropeptide Y inhibits excitatory neurotransmission between olfactory bulb neurons via a presynaptic effect on transmitter (glutamate) release.

Tumor suppressor protein p53 mRNA and subcellular localization are altered by changes in cellular copper in human Hep G2 cells.

Copper toxicity causes hepatic damage that can lead to the development of hepatocarcinoma. Similarly, copper deficiency has been reported to increase hepatocyte tumorigenesis. Thus, the objective of this work was to explore the role of copper toxicity and deficiency in the regulation of the tumor suppressor protein p53. Using Northern analysis, Western analysis, immunocytochemistry and the human hepatoma cell line Hep G2, this work showed that elevations in hepatocyte copper consistent with Wilson's disease (5.7-fold increase) induced p53 mRNA and confirmed that copper toxicity is correlated with apoptotic cell death. However, Western analysis and immunocytochemistry showed that post-transcriptional mechanisms are a significant part of the process, with p53 translocation from the cytosol into the nucleus of copper-treated cells. Treatment of Hep G2 cells with increasing concentrations of the copper chelator tetraethylenepentamine (TEPA, 0-50 micromol/L, 48 h) reduced cellular copper and increased mean p53 mRNA abundance by over fourfold with nuclear translocation of the wild-type protein. However, TEPA treatment did not result in a loss of cell viability or appear to induce apoptosis.

Abg1: a novel gene up-regulated by abscisic acid in guard cells of Vicia faba L.

A novel gene (abg1) was isolated by differential display RT-PCR from guard cells of Vicia faba L. Abg1 transcript accumulated in guard cells that were incubated with 5 microM S(+)-ABA for 1 h. The full-length abg1 cDNA was 753 bp, which included a 513 bp coding region. The deduced 17.8 kDa protein shared sequence similarity with several desiccation-related proteins reported in plants.

Licania michauxii Prance root extract induces hsp 70 mRNA and necrotic cell death in cultured human hepatoma and colon carcinoma cell lines.

An extract of Licania michauxii Prance root was found to be cytotoxic to cultured human hepatoma (HepG2) and colon carcinoma (Caco-2) cells. Morphological and nuclear characteristics of treated cells were consistent with necrotic death. Increases in the chaperone protein hsp 70 and hsp 70 mRNA were dose dependent reaching peak mRNA levels (40-fold above control) at 6 h. Increases in nuclear localization of hsp 70 was also observed with treatment. Heat treatment of cells for 45 min to induce hsp 70 prior to treatment with the extract provided transient protection from the necrotic response.

Effect of altered thyroid hormone status on rat brain ferritin H and ferritin L mRNA during postnatal development.

The iron binding protein ferritin is a heterogeneous mix of 24 heavy (H) and light (L) subunits. The H subunit is associated with iron utilization, while the L subunit is responsible for iron storage. Examination of the developmental pattern of mRNA abundance in rat brain revealed that ferritin L mRNA is highest at birth and declines during the first postnatal week. A similar decline was seen in ferritin H mRNA, but was followed by an increase in ferritin H mRNA in the second postnatal week which continued through postnatal day 21. The pattern of H mRNA regulation is similar to that in previous reports of total ferritin protein in the developing rat brain and is consistent with the fact that brain ferritin is predominately ferritin H. The effect of thyroid hormone on the developmental regulation of ferritin mRNAs was examined by the subcutaneous injection of a single dose of exogenous thyroxine (T(4); 2 microg/g) on postnatal day 1. Hypothyroidism was induced in pregnant dams with propylthiouracil (PTU; 0.05% in drinking water) from gestational day 7. Northern analysis from postnatal days 2-21 showed that T(4) increased ferritin H mRNA throughout development, while ferritin L mRNA was decreased compared to age-matched controls. PTU treatment decreased ferritin H and increased L mRNA in the later stages (days 14-21) of development. Given the distinct functions of ferritin H and L this suggests a role for thyroid hormone in the ability of the brain to regulate stored vs. utilizable iron during critical periods of development.

Self-selection of copper-containing diets by copper-deficient and overloaded rats.

To determine the effect of copper status on the preference for copper-containing food, male Sprague-Dawley rats were weaned to a copper-deficient, copper-adequate or high-copper diet. Four weeks later, alterations in copper status were confirmed by measurement of liver copper concentrations. Rats (n=10) were then given the choice between a copper-adequate or a copper-restricted diet of similar composition. Preference scores indicated that control rats preferred copper-deficient food. Preferences of rats on the high-copper diet were not different from control rats, suggesting that copper overload did not alter the pattern of selection. However, 7 of the 10 copper-deficient rats ate 80% or more of their intake as copper-adequate food resulting in preference scores that were significantly different from controls (p<0.03). This alteration in preference was corrected within 1 day of access to copper-adequate food.

Dopamine transporters participate in the physiological regulation of prolactin.

Three populations of hypothalamic neuroendocrine dopaminergic (NEDA) neurons, arising from the arcuate and periventricular nuclei of the hypothalamus release dopamine (DA) that acts at the pituitary gland to regulate the secretion of PRL. It is generally accepted that NEDA neurons lack functional DA transporters (DATs), which are responsible for uptake of DA from the synaptic cleft into the presynaptic axon terminal. This study localized DATs to the hypothalamo-pituitary axis and evaluated the effect of DAT blockade on the hypothalamo-pituitary regulation of PRL. After 7 days of treatment with cocaine (a nonspecific amine transporter blocker) or mazindol (a specific DAT blocker), the relative abundance of PRL messenger RNA (mRNA) in the anterior lobe (AL) of OVX rats was significantly decreased, whereas the relative abundance of tyrosine hydroxylase mRNA in the hypothalamus was significantly increased. The effect of cocaine or mazindol administration on DA turnover and serum PRL concentration was examined in estradiol (E2)-treated OVX rats. E2 administration (i.v.) resulted in a significant increase in serum PRL within 4 h; however, cocaine or mazindol administration abolished the E2-induced increase of PRL. Cocaine or mazindol significantly increased the concentration of DA at the site of the axon terminals within the median eminence (ME), intermediate lobe (IL) and neural lobe (NL), indicating blockade of uptake. Because formation of DOPAC requires uptake of DA, concentrations of DOPAC in the ME, IL and NL decreased following treatment with either cocaine or mazindol. These data, together with the presence of immunopositive DAT in the ME, pituitary stalk, IL, and NL, suggest that a functional DAT system is present within all three populations of NEDA neurons. Moreover, similarity between the effects of cocaine and mazindol treatment indicate that blockade of the DAT, but not other amine transporters, is responsible for suppression of PRL gene expression and secretion. Blockade of DATs prevent uptake of DA into NEDA neurons and consequently increases the amount of DA that diffuses into the portal vasculature and reaches the AL. These data provide evidence that DATs play a physiological role in the regulation of DA release from and TH expression in NEDA neurons and consequently PRL secretion and PRL gene expression and further support our previous observation that the regulation of PRL secretion involves all three populations of NEDA neurons.

Regulation of mitochondrial cytochrome b mRNA by copper in cultured human hepatoma cells and rat liver.

Copper overload and deficiency are known to cause morphological and functional mitochondrial abnormalities. The reverse transcriptase-polymerase chain reaction (RT-PCR)-based method of differential display of mRNA was used to identify genes with altered expression in cultured human hepatoma cells (Hep G2) exposed to increasing concentrations of copper (0-100 microM, 24 h). Copper regulation of a cloned PCR product, identified as the gene for the mitochondrially encoded cytochrome b, was confirmed by Northern analysis and in situ hybridization. Copper toxicity increased cytochrome b mRNA abundance up to 3.6-fold, and copper chelation reduced it by 50%. Hepatic cytochrome b mRNA was also increased in rats fed a high-copper diet. Thapsigargin treatment resulted in a significant increase in cytochrome b mRNA, suggesting that an increase in intracellular calcium may be involved in the mechanism of copper action. Furthermore, although cyclohexamide (CHX) alone did not increase cytochrome b mRNA, the addition of CHX and copper resulted in a sixfold increase. These data suggest a role for cytochrome b in the response to increases or decreases in hepatic copper.

Regulation of metallothionein-3 mRNA by thyroid hormone in developing rat brain and primary cultures of rat astrocytes and neurons.

Metallothionein-3 (MT-3) is a brain specific member of the MT family. Unlike other members of this family, MT-3 has been shown to act as a neuronal growth inhibitory factor. MT-3 mRNA abundance increases throughout the developmental period, reaching adult levels by postnatal day 21. The role of thyroid hormone in the developmental regulation of MT-3 mRNA was tested because thyroid hormone is known to regulate brain gene expression. Furthermore, gestational hypothyroidism results in developmental brain abnormalities. Hypothyroidism was induced in pregnant dams by the administration of PTU from gestational day 7, resulting in a 4- to 6-fold increase in pup MT-3 mRNA abundance on the day of birth (day 0) and on postnatal day 3. Normal pups did not reach this level of brain MT-3 mRNA until postnatal day 21. Administration of thyroxine (T(4), 2 microg/g) to pups on postnatal day 1 or day 20 resulted in a decrease in MT-3 mRNA abundance on postnatal day 21, regardless of when the injection was given. Furthermore, addition of T(4) to primary cultures of brain (olfactory bulb) astrocytes and neurons from 4-day-old rats resulted in a significant decrease in MT-3 mRNA in 24 h. Given the neuronal growth inhibitory function of MT-3, these data suggest that MT-3 may play a role in the CNS-related consequences of hypo- and hyperthyroidism during development.

Developmental regulation of hepatic ceruloplasmin mRNA and serum activity by exogenous thyroxine and dexamethasone.

Ceruloplasmin (Cp) is a copper-dependent oxidase with roles that include the regulation of iron metabolism, participation in the acute-phase response to inflammation, and antioxidant systems. Although developmental increases in hepatic Cp gene expression and serum activity have been described, the molecular mechanisms that are responsible for this regulation are not fully understood. The studies described here explored the possible role of glucocorticoids and thyroxine (T4) in the early neonatal development of Cp by the administration of these hormones on postnatal Day 1 (24 hr after birth), and the measurement of both hepatic Cp mRNA and serum activity through postnatal Day 10. Administration of the synthetic glucocorticoid hormone, dexamethasone (2 micrograms/g body wt), resulted in an increase in Cp mRNA on Days 3-7 that was accompanied by an increase in serum Cp activity that reached statistical significance at Day 10. Exogenous T4 (2 micrograms/g body wt) significantly increased Cp mRNA 24 hr after administration. Serum Cp activity was also significantly elevated by the early neonatal administration of T4. Furthermore, gestational hypothyroidism resulted in a significant decrease in Cp activity after postnatal Day 3. These data suggest a role for thyroid hormone and possibly glucocorticoids in the normal developmental regulation of Cp.

Regulation of neuropeptide Y mRNA and peptide concentrations by copper in rat olfactory bulb.

Neuropeptide Y is highly abundant in both the peripheral and central nervous systems and is known to have diverse functions including regulation of feeding behavior, blood pressure, circadian rhythms, reproductive behavior and the response to stress. Northern analysis showed that copper deficiency increased brain NPY mRNA abundance particularly in the olfactory bulb (OB). These increases were not accompanied by alterations in food intake or blood pressure. After 4 weeks of a copper-restricted diet, OB copper concentrations decreased to 44% of control and NPY mRNA increased 1.5-fold. Addition of a copper chelator to the restricted diet, resulted in a two-fold increase in OB NPY mRNA over copper adequate controls. These results were confirmed in primary cultures of OB neurons suggesting that the regulation of NPY mRNA is at the level of the bulb rather than by a hormonal or other copper-regulated factor external to the OB. Immunoreactive NPY (IR-NPY) levels were not, however, increased following the 4 weeks of copper deficiency. Addition of the chelator resulted in a 1.4-fold increase in IR-NPY that, while statistically significant, was not proportional to the two-fold increase in NPY mRNA in the same study. This may suggest that copper deficiency inhibits the translational mechanisms responsible for the synthesis of NPY or that NPY is exported from the bulb in copper deficiency.

Free zinc increases at the site of injury after cortical stab wounds in mature but not immature rat brain.

The accumulation of free zinc (Zn2+) appears to play a role in the neuronal degeneration that occurs after brain injury. Given that neonates respond to brain injury with increased plasticity compared to adults, this study compared the effect of age on free Zn2+ and the Zn2+-binding protein metallothionein-3 (MT-3) after injury. Unilateral cortical stab wounds were produced in 3-day-old and adult rats. Four weeks later, brains were removed for in situ visualization of free Zn2+ and measurement of MT-3 mRNA. Free Zn2+ and MT-3 mRNA accumulated after 4 weeks at the site of injury site when injury occurred in adults. However, 4 weeks after neonatal injury there was no increase in free Zn2+ or MT-3 mRNA in or around the site of injury.

Mechanisms of copper conservation in organs.

Organ copper is conserved in response to dietary copper restriction. In organs such as brain and heart, conservation is highly efficient, resulting in the loss of little organ copper. In contrast, conservation of copper in liver is induced only after a significant amount of organ copper is lost. Thus, the conservation of copper during dietary restriction is highly organ specific. Although the long-term pattern of organ copper conservation in rats has now been described through use of the continuous feeding of a single stable isotope, the mechanisms responsible for this conservation have not been identified or studied. These mechanisms may include copper-regulated changes in gene expression as well as other mechanisms. We now have the molecular tools that will permit the isolation of copper-regulated genes that may play a role in the conservation of organ copper. Identification of these mechanisms will allow the exploration of the effects of mild short-term and long-term copper deficiency and the role of copper in other physiologic and biochemical systems.

Response of rat adrenal neuropeptide Y and tyrosine hydroxylase mRNA to acute stress is enhanced by long-term voluntary exercise.

Neuropeptide Y (NPY) and catecholamines are synthesized in response to stress. Adrenal NPY mRNA and tyrosine hydroxylase (TH) mRNA were measured by Northern analysis 2 h after a single 20 min bout of shaker stress in exercised and sedentary male Sprague-Dawley rats. Long-term exercise (18 weeks of voluntary wheel running) alone did not significantly alter adrenal NPY mRNA or TH mRNA levels. However, increases in stress-induced NPY and TH mRNA abundances were significantly enhanced by long-term exercise (P < 0.01). These results suggest that long-term physical activity may enhance the ability to synthesize NPY and catecholamines under conditions of stress.

Regulation of ceruloplasmin by retinoic acid in the developing rat.

Ceruloplasmin (Cp), the major copper-binding protein in the plasma, is an acute phase protein with ferrioxidase activity. Both its oxidase activity and hepatic mRNA abundance increase during the developmental period. To test the possible role of retinoic acid, a derivative of vitamin A known to participate in cellular differentiation and development, on the developmental regulation of Cp, neonatal rat pups were injected with 2 micrograms 13-cis-retinoic acid (RA)/g body weight on postnatal day 1. Serum Cp activity and hepatic Cp mRNA were measured over the next 3 weeks in RA-treated and vehicle-treated controls. Serum Cp activity increased 2.5-fold 24 h after RA administration. However, hepatic Cp mRNA abundance was not elevated during this time period, suggesting that the action of RA on Cp activity was the result of post-transcriptional changes.

Cloning and initial characterization of the promoter region of the rat cysteine-rich intestinal protein gene.

Cysteine-rich intestinal protein (CRIP) is an intestinal Zn(2+)-binding protein containing a single copy of the double Zn(2+)-finger arrangement known as the LIM motif. CRIP is developmentally regulated and can be induced by glucocorticoid hormones during the early suckling period. In this report we show that CRIP mRNA levels are induced by dexamethasone in cultured rat intestinal epithelial cells (IEC-6). Analysis of the 2644 bp of the 5'-flanking region of the CRIP gene revealed that the CRIP promoter lacks classical CAAT and TATA boxes but contains GC-rich regions in the proximal end of the promoter that probably function in transcription initiation. In addition to binding sites for transcription factors such as Sp-1, AP-2, OCT and GATA-2, there are multiple glucocorticoid-response elements. CRIP promoter constructs fused to the chloramphenicol acetyltransferase reporter gene and transfected into IEC-6 cells confirmed glucocorticoid responsiveness and the presence of negative acting elements. Mobility-shift assays revealed the presence of nuclear factors that bind to the CRIP promoter as a result of dexamethasone treatment. These experiments provide the initial data required to explore further the regulation of this tissue-specific developmentally regulated Zn(2+)-finger protein.

Long-term measurement of organ copper turnover in rats by continuous feeding of a stable isotope.

Utilizing the continuous feeding of a single stable isotope and inductively coupled plasma mass spectrometry, we have developed a method that allows the measurement of organ copper turnover in the rat for at least 8 weeks. Previous methods, based on tracer studies using radioisotopes of copper, were severely limited by the short half-lives of the radioisotopes (12.8 and 61.8 h). Taking advantage of the known ratio of the two naturally occurring stable isotopes of copper (63Cu and 65Cu), dietary copper was replaced by a single isotope of copper (63Cu) for the entire 8-week period. Disappearance of the other isotope (65Cu) from tissues was then monitored as a measure of copper turnover. Because this method is not a tracer study, it has the unique advantage of uniformly labeled physiological and kinetic compartments. Half-lives of individual first-order kinetic compartments within organs and plasma were obtained by analysis of the 8-week copper turnover curves in copper-adequate and copper-restricted rats. Mean decreases in organ copper following 56 days of copper restriction were plasma, 99%; liver, 62%; heart, 3%; muscle, 26%; kidney, 66%; and brain, < 1%. Comparison of normal organ turnover to turnover in copper-restricted rats revealed that this method can be used during periods of severe copper restriction and that copper conservation during these periods is organ specific.

Expression of cysteine-rich intestinal protein in rat intestine and transfected cells is not zinc dependent.

The cysteine-rich intestinal protein (CRIP) is a member of a superfamily of proteins containing the LIM motif (a double zinc finger) that has been shown to bind zinc. The role of zinc in the regulation of CRIP was examined in adult rats, cultured intestinal epithelial cells and in a transient transfection system. When adult male rats were fed diets with various amounts of zinc, the amount of ileal CRIP mRNA was only 19% lower in rats fed a zinc-deficient diet (1 mg Zn/kg) and was not different in the zinc-supplemented group (180 mg Zn/kg) compared with the zinc-adequate group (30 mg Zn/kg). In contrast, metallothionein mRNA levels were 76% lower and 80% greater than control levels in the zinc-deficient and zinc-supplemented groups, respectively. Using the chloramphenicol acetyltransferase (CAT) reporter gene, 5'-deletion products of the CRIP genomic promoter were tested for basal and zinc-induced CAT activity in transiently transfected IEC-6 cells. Treatment of the cells with zinc did not alter CAT activity of any construct. These results suggest that CRIP is not directly regulated by zinc in the intestine of rats.

Regulation of cysteine-rich intestinal protein by dexamethasone in the neonatal rat.

The cysteine-rich intestinal protein (CRIP) is an intestinal zinc-binding protein containing a single copy of a cysteine-rich domain known as the LIM motif. CRIP mRNA and protein levels increased in the rat small intestine throughout the suckling period, reaching highest levels by the late weanling stage. A similar developmental pattern of CRIP protein levels was also detected by an increase in zinc binding to CRIP-containing HPLC fractions of intestinal cytosol. Administration of the synthetic glucocorticoid hormone dexamethasone to neonates caused the precocious rise of CRIP mRNA and protein. In adult rats, CRIP mRNA levels were not significantly altered by dexamethasone. Maximal CRIP mRNA content was detected in cells from the mid-villus, as confirmed by expression of cryptdin mRNA. In this report we show the glucocorticoid regulation of the LIM motif-containing protein CRIP and suggest that glucocorticoid hormones play a role in developmental regulation of CRIP.