A Upf3b-mutant mouse model with behavioral and neurogenesis defects.

Nonsense-mediated RNA decay (NMD) is a highly conserved and selective RNA degradation pathway that acts on RNAs terminating their reading frames in specific contexts. NMD is regulated in a tissue-specific and developmentally controlled manner, raising the possibility that it influences developmental events. Indeed, loss or depletion of NMD factors have been shown to disrupt developmental events in organisms spanning the phylogenetic scale. In humans, mutations in the NMD factor gene, UPF3B, cause intellectual disability (ID) and are strongly associated with autism spectrum disorder (ASD), attention deficit hyperactivity disorder (ADHD) and schizophrenia (SCZ). Here, we report the generation and characterization of mice harboring a null Upf3b allele. These Upf3b-null mice exhibit deficits in fear-conditioned learning, but not spatial learning. Upf3b-null mice also have a profound defect in prepulse inhibition (PPI), a measure of sensorimotor gating commonly deficient in individuals with SCZ and other brain disorders. Consistent with both their PPI and learning defects, cortical pyramidal neurons from Upf3b-null mice display deficient dendritic spine maturation in vivo. In addition, neural stem cells from Upf3b-null mice have impaired ability to undergo differentiation and require prolonged culture to give rise to functional neurons with electrical activity. RNA sequencing (RNAseq) analysis of the frontal cortex identified UPF3B-regulated RNAs, including direct NMD target transcripts encoding proteins with known functions in neural differentiation, maturation and disease. We suggest Upf3b-null mice serve as a novel model system to decipher cellular and molecular defects underlying ID and neurodevelopmental disorders.

The RHOX homeobox gene cluster is selectively expressed in human oocytes and male germ cells.

STUDY QUESTION: What human tissues and cell types express the X-linked reproductive homeobox (RHOX) gene cluster? SUMMARY ANSWER: The RHOX homeobox genes and proteins are selectively expressed in germ cells in both the ovary and testis. WHAT IS KNOWN ALREADY: The RHOX homeobox transcription factors are encoded by an X-linked gene cluster whose members are selectively expressed in the male and female reproductive tract of mice and rats. The Rhox genes have undergone strong selection pressure to rapidly evolve, making it uncertain whether they maintain their reproductive tissue-centric expression pattern in humans, an issue we address in this report. STUDY DESIGN, SIZE, DURATION: We examined the expression of all members of the human RHOX gene cluster in 11 fetal and 8 adult tissues. The focus of our analysis was on fetal testes, where we evaluated 16 different samples from 8 to 20 weeks gestation. We also analyzed fixed sections from fetal testes, adult testes and adult ovaries to determine the cell type-specific expression pattern of the proteins encoded by RHOX genes. PARTICIPANTS/MATERIALS, SETTING, METHODS: We used quantitative reverse transcription-polymerase chain reaction analysis to assay human RHOX gene expression. We generated antisera against RHOX proteins and used them for western blotting, immunohistochemical and immunofluorescence analyses of RHOXF1 and RHOXF2/2B protein expression. MAIN RESULTS AND THE ROLE OF CHANCE: We found that the RHOXF1 and RHOXF2/2B genes are highly expressed in the testis and exhibit low or undetectable expression in most other organs. Using RHOXF1- and RHOXF2/2B-specific antiserum, we found that both RHOXF1 and RHOXF2/2B are primarily expressed in germ cells in the adult testis. Early stage germ cells (spermatogonia and early spermatocytes) express RHOXF2/2B, while later stage germ cells (pachytene spermatocytes and round spermatids) express RHOXF1. Both RHOXF1 and RHOXF2/2B are expressed in prespermatogonia in human fetal testes. Consistent with this, RHOXF1 and RHOXF2/2B mRNA expression increases in the second trimester during fetal testes development when gonocytes differentiate into prespermatogonia. In the human adult ovary, we found that RHOXF1 and RHOXF2/2B are primarily expressed in oocytes. LIMITATIONS, REASONS FOR CAUTION: While the average level of expression of RHOX genes was low or undetectable in all 19 human tissues other than testes, it is still possible that RHOX genes are highly expressed in a small subset of cells in some of these non-testicular tissues. As a case in point, we found that RHOX proteins are highly expressed in oocytes within the human ovary, despite low levels of RHOX mRNA in the whole ovary. WIDER IMPLICATIONS OF THE FINDINGS: The cell type-specific and developmentally regulated expression pattern of the RHOX transcription factors suggests that they perform regulatory functions during human fetal germ cell development, spermatogenesis and oogenesis. Our results also raise the possibility that modulation of RHOX gene levels could correct some cases of human infertility and that their encoded proteins are candidate targets for contraceptive drug design.

Transcriptome profiling of UPF3B/NMD-deficient lymphoblastoid cells from patients with various forms of intellectual disability.

The nonsense-mediated mRNA decay (NMD) pathway was originally discovered by virtue of its ability to rapidly degrade aberrant mRNAs with premature termination codons. More recently, it was shown that NMD also directly regulates subsets of normal transcripts, suggesting that NMD has roles in normal biological processes. Indeed, several NMD factors have been shown to regulate neurological events (for example, neurogenesis and synaptic plasticity) in numerous vertebrate species. In man, mutations in the NMD factor gene UPF3B, which disrupts a branch of the NMD pathway, cause various forms of intellectual disability (ID). Using Epstein Barr virus-immortalized B cells, also known as lymphoblastoid cell lines (LCLs), from ID patients that have loss-of-function mutations in UPF3B, we investigated the genome-wide consequences of compromised NMD and the role of NMD in neuronal development and function. We found that ~5% of the human transcriptome is impacted in UPF3B patients. The UPF3B paralog, UPF3A, is stabilized in all UPF3B patients, and partially compensates for the loss of UPF3B function. Interestingly, UPF3A protein, but not mRNA, was stabilised in a quantitative manner that inversely correlated with the severity of patients' phenotype. This suggested that the ability to stabilize the UPF3A protein is a crucial modifier of the neurological symptoms due to loss of UPF3B. We also identified ARHGAP24, which encodes a GTPase-activating protein, as a canonical target of NMD, and we provide evidence that deregulation of this gene inhibits axon and dendrite outgrowth and branching. Our results demonstrate that the UPF3B-dependent NMD pathway is a major regulator of the transcriptome and that its targets have important roles in neuronal cells.

T cell receptor (TCR) mini-gene mRNA expression regulated by nonsense codons: a nuclear-associated translation-like mechanism.

Premature termination codons (PTCs) are known to decrease mRNA levels. Here, we report our investigation of the mechanism for this downregulation using the TCR-beta gene, which acquires PTCs as a result of programmed rearrangements that occur during normal thymic development. We found that a mini-gene version of this gene, which contains only three TCR-beta exons, exhibited efficient downregulation in response to PTCs. This demonstrates that the full coding sequence is not necessary for appropriate regulation. Mutation of the translation start AUG and a downstream in-frame AUG that displayed similarity to the Kozak consensus sequence reversed the downregulatory response to PTCs. Thus, an AUG start codon is required to define the reading frame of a PTC. Specific suppressor tRNAs also reversed the downregulatory response, strongly implicating the involvement of a translation-like process. Remarkably, the addition of suppressor tRNAs or the inactivation of the start AUGs caused a dramatic rise in the levels of PTC-bearing transcripts in the nuclear fraction prepared by two independent methods. Collectively, our results provide evidence for a codon-based surveillance mechanism associated with the nucleus that downregulates aberrant transcripts encoding potentially toxic polypeptides from nonproductively rearranged genes.

The expression of several T cell-specific and novel genes is repressed by trans-acting factors in immature T lymphoma clones.

Cell surface proteins encoded by members of the immunoglobulin supergene family are sequentially expressed during T cell ontogeny. The molecular mechanisms responsible for the regulation of these surface molecules are not well understood. To investigate this issue, we used a series of well characterized T lymphoma cell clones with phenotypes characteristic of distinct stages of early thymocyte maturation. Somatic cell hybrids formed from these cell lines were employed to detect the presence of negative regulatory molecules. The expression of CD4 and CD8 was strongly repressed in hybrids formed between a CD4+ CD8+ lymphoma clone and "immature" CD4- CD8- lymphoma clones. Individual subunits of the T cell receptor (TCR)/CD3 complex displayed independent regulation in unique patterns in hybrid cells. Hybrids formed by fusing CD3+ and CD3- cells completely repressed CD3-delta mRNA expression while CD3-gamma, -epsilon, and -zeta transcripts were moderately inhibited or codominantly regulated. Similar to CD3-delta, interleukin 2R-alpha(IL-2R-alpha), and TCR-beta mRNA accumulation was trans-negatively regulated. Transcription rate measurements demonstrated that the inhibition of CD4, CD8, CD3-gamma, CD3-epsilon, TCR-beta, and IL-2R-alpha mRNA accumulation in hybrid cells was exerted, at least in part, at the transcriptional level. To test whether repressional regulation is a general feature of T cells, we examined the regulation of six novel genes which were selected solely on the basis of their differential expression between two of the cell lines used in this study. Five of the six novel gene transcripts were repressed in the somatic cell hybrids. Thus, inhibitor factors appear to play a general role in controlling T cell gene expression. The model system presented here may be useful for the identification and characterization of repressor molecules responsible for the regulation of genes expressed during T cell ontogeny.

Serine phosphorylation of SR proteins is required for their recruitment to sites of transcription in vivo.

Expression of most RNA polymerase II transcripts requires the coordinated execution of transcription, splicing, and 3' processing. We have previously shown that upon transcriptional activation of a gene in vivo, pre-mRNA splicing factors are recruited from nuclear speckles, in which they are concentrated, to sites of transcription (Misteli, T., J.F. Cáceres, and D.L. Spector. 1997. Nature. 387:523-527). This recruitment process appears to spatially coordinate transcription and pre-mRNA splicing within the cell nucleus. Here we have investigated the molecular basis for recruitment by analyzing the recruitment properties of mutant splicing factors. We show that multiple protein domains are required for efficient recruitment of SR proteins from nuclear speckles to nascent RNA. The two types of modular domains found in the splicing factor SF2/ ASF exert distinct functions in this process. In living cells, the RS domain functions in the dissociation of the protein from speckles, and phosphorylation of serine residues in the RS domain is a prerequisite for this event. The RNA binding domains play a role in the association of splicing factors with the target RNA. These observations identify a novel in vivo role for the RS domain of SR proteins and suggest a model in which protein phosphorylation is instrumental for the recruitment of these proteins to active sites of transcription in vivo.

Epigenetic regulation and downstream targets of the Rhox5 homeobox gene.

The discovery of the Rhox homeobox gene cluster on the X chromosome opens up new vistas in the regulation of reproductive processes in mammals. In mice, this cluster comprises more than 30 genes that are selectively expressed in reproductive tissues. A subset of Rhox genes are androgen and AR regulated in postnatal and adult Sertoli cells, making them candidates to mediate androgen-dependent steps during spermatogenesis. The best characterized of these androgen/AR-regulated genes is Rhox5 (Pem), the founding member of the Rhox gene cluster. Targeted deletion of Rhox5 in mice causes male subfertility marked by increased germ-cell apoptosis and decreased sperm count and motility. Microarray analyses identified a wide variety of genes regulated by Rhox5 in Sertoli cells. One of them is the tumour suppressor UNC5C, a pro-apoptotic molecule previously only known to be involved in brain development. Targeted deletion of Unc5c causes decreased germ-cell apoptosis in postnatal and adult testes, indicating that it also has a role in spermatogenesis and supporting a model in which Rhox5 promotes germ-cell survival by downregulating Unc5c. Rhox5 has two independently regulated promoters that have distinct expression patterns. The unique tissue-specific and developmentally regulated transcription pattern of these two promoters appear to be controlled by DNA methylation. Both promoters are methylated in tissues in which they are not expressed, suggesting that DNA methylation serves to repress Rhox5 expression in inappropriate cell types and tissues. In summary, the Rhox gene cluster is an epigenetically regulated set of genes encoding a large number of transcription factors that are strong candidates to regulate gametogenesis and other aspects of reproduction.

Activated T cells express a novel gene on chromosome 8 that is closely related to the murine ecotropic retroviral receptor.

A novel cDNA clone (20.5) which is differentially expressed between two closely related T-lymphoma cell clones was isolated by subtraction-enriched differential screening. SL12.4 cells, from which the cDNA was isolated, have characteristics of thymocytes at an intermediate stage in development. A sister cell clone derived from the same tumor, SL12.3, does not express this mRNA, has a distinct phenotype, and expresses fewer genes required for mature T-cell function. The cDNA sequence predicts a highly hydrophobic protein (approximately 49.5 kilodaltons) which contains seven putative membrane spanning domains. The gene was expressed on concanavalin A-activated T lymphocytes and was designated Tea (T-cell early activation gene). The Tea gene mapped to chromosome 8 and appeared to be conserved among mammalian and avian species. The Tea gene is distinct from, but bears extensive amino acid and DNA sequence similarity with, the murine ecotropic retroviral receptor which is encoded by the Rec-1 gene. Neither gene product displayed significant homology with other known transmembrane-spanning proteins. Thus, the Tea and Rec-1 genes establish a new family encoding multiple membrane-spanning proteins.

T cell receptor-beta mRNA splicing: regulation of unusual splicing intermediates.

The expression of functional T cell receptor-beta (TCR-beta) transcripts requires the activation of programmed DNA rearrangement events. It is not clear whether other mechanisms dictate TCR-beta mRNA levels during thymic ontogeny. We examined the potential role of RNA splicing as a regulatory mechanism. As a model system, we used an immature T cell clone, SL12.4, that transcribes a fully rearranged TCR-beta gene but essentially lacks mature 1.3-kb TCR-beta transcripts in the cytoplasm. Abundant TCR-beta splicing intermediates accumulate in the nucleus of this cell clone. These splicing intermediates result from inefficient or inhibited excision of four of the five TCR-beta introns; the only intron that is efficiently spliced is the most 5' intron, IVSL. The focal point for the regulation appears to be IVS1C beta 1 and IVS2C beta 1, since unusual splicing intermediates that have cleaved the 5' splice site but not the 3' splice site of these two introns accumulate in vivo. The block in 3' splice site cleavage is of interest since sequence analysis reveals that these two introns possess canonical splice sites. A repressional mechanism involving a labile repressor protein may be responsible for the inhibition of RNA splicing since treatment of SL12.4 cells with the protein synthesis inhibitor cycloheximide reversibly induces a rapid and dramatic accumulation of fully spliced TCR-beta transcripts in the cytoplasm, concomitant with a decline in TCR-beta pre-mRNAs in the nucleus. This inducible system may be useful for future studies analyzing the underlying molecular mechanisms that regulate RNA splicing.

The dihydropyridine-sensitive calcium channel subtype in cone photoreceptors.

High-voltage activated Ca channels in tiger salamander cone photoreceptors were studied with nystatin-permeabilized patch recordings in 3 mM Ca2+ and 10 mM Ba2+. The majority of Ca channel current was dihydropyridine sensitive, suggesting a preponderance of L-type Ca channels. However, voltage-dependent, incomplete block (maximum 60%) by nifedipine (0.1-100 microM) was evident in recordings of cones in tissue slice. In isolated cones, where the block was more potent, nifedipine (0.1-10 microM) or nisoldipine (0.5-5 microM) still failed to eliminate completely the Ca channel current. Nisoldipine was equally effective in blocking Ca channel current elicited in the presence of 10 mM Ba2+ (76% block) or 3 mM Ca2+ (88% block). 15% of the Ba2+ current was reversibly blocked by omega-conotoxin GVIA (1 microM). After enhancement with 1 microM Bay K 8644, omega-conotoxin GVIA blocked a greater proportion (22%) of Ba2+ current than in control. After achieving partial block of the Ba2+ current with nifedipine, concomitant application of omega-conotoxin GVIA produced no further block. The P-type Ca channel blocker, omega-agatoxin IVA (200 nM), had variable and insignificant effects. The current persisting in the presence of these blockers could be eliminated with Cd2+ (100 microM). These results indicate that photoreceptors express an L-type Ca channel having a distinguishing pharmacological profile similar to the alpha 1D Ca channel subtype. The presence of additional Ca channel subtypes, resistant to the widely used L-, N-, and P-type Ca channel blockers, cannot, however, be ruled out.

Rapid induction of nuclear transcripts and inhibition of intron decay in response to the polymerase II inhibitor DRB.

The transcriptional inhibitor 5, 6-dichloro-1-beta-d-ribofuranosylbenzimidazole (DRB) is an adenosine analog that has been shown to cause premature transcriptional termination and thus has been a useful tool to identify factors important for transcriptional elongation. Here, we establish an efficient system for studying DRB-sensitive steps of transcriptional elongation. In addition, we establish two novel effects of DRB not previously reported: intron stabilization and the induction of long transcripts by a mechanism other than premature termination. We found that DRB had a biphasic effect on T-cell receptor-beta (TCRbeta) transcripts driven by a tetracycline (tet)-responsive promoter in transfected HeLa cells. In the first phase, DRB caused a rapid decrease (within five minutes) of pre-mRNA and its spliced intron (IVS1(Cbeta1)), consistent with the known ability of DRB to inhibit transcription. In the second phase (which began ten minutes to two hours after treatment, depending on the dose), DRB dramatically increased the levels of IVS1(Cbeta1)-containing transcripts by a mechanism requiring de novo RNA synthesis. DRB induced the appearance of short 0.4 to 0.8 kb TCRbeta transcripts in vivo, indicating DRB enhances premature transcriptional termination. A approximately 475 nt prematurely terminated transcript (PT) was characterized that terminated at an internal poly(A) tract in the intron IVS1(Cbeta1). We identified three other effects of DRB. First, we observed that DRB induced the appearance of heterodisperse TCRbeta transcripts that were too long ( approximately 1 kb to >8 kb) to result from the type of premature termination events previously described. Their production was not promoter-specific, as we found that long transcripts were induced by DRB from both the tet-responsive and beta-actin promoters. Second, DRB upregulated full-length normal-sized c-myc mRNA, which provided further evidence that DRB has effects besides regulation of premature termination. Third, DRB stabilized lariat forms of the intron IVS1(Cbeta1), indicating that DRB exerts post-transcriptional actions. We propose that our model system will be useful for elucidating the factors that regulate RNA decay and transcriptional elongation in vivo.

The oncofetal gene Pem encodes a homeodomain and is regulated in primordial and pre-muscle stem cells.

The oncofetal gene, Pem, is expressed in a stage specific manner during murine ontogeny. The carboxy terminal portion of the predicted Pem protein has significant similarity to homeodomains of the Drosophila prd family. The Pem gene is expressed in undifferentiated embryonal stem (ES) and embryonal carcinoma (EC) cell lines. Pem mRNA is induced 35-fold in ES cells differentiated in the absence of retinoic acid. Pem mRNA is increased in EC cells differentiated towards parietal or visceral endoderm, consistent with the abundant Pem expression in embryonic yolk sac. In 10T mesenchymal stem cells committed to muscle cell differentiation, Pem mRNA expression is dramatically increased. The elevation in Pem expression preceded the induction of the muscle master regulatory gene, myoD. We conclude that the Pem gene encodes a candidate transcription factor which is developmentally regulated.

TcR-alpha mRNA accumulation does not dictate cell surface TcR/CD3 expression.

The TcR-alpha chain is the last subunit of the TcR/CD3 complex to be expressed during thymic ontogeny. Since the presence of all subunits are required for efficient expression of this complex on the cell surface, this has lead to the hypothesis that the TcR-alpha chain is the limiting subunit which controls cell surface TcR/CD3 expression during thymocyte differentiation. We have examined this issue using a T-lymphoma cell clone, RS4.2, which has a CD4- CD8- Thyl+ J11d+ IL2R+ phenotype, identical with immature thymocytes which have the capacity to generate all major T cell subsets. The RS4.2 cell clone accumulates abundant amounts of TcR-beta, CD3-gamma, -delta, -epsilon and -zeta transcripts, but expresses trace levels of TcR-alpha transcripts and cell surface TcR/CD3. TcR-alpha mRNA levels can be dramatically augmented in RS4.2 cells by three distinct mechanisms: in response to treatment with either phorbol myristate acetate (PMA), calcium ionophore (A23187), or cycloheximide (CHX). However, the expression of TcR/CD3 on the cell surface fails to be increased by any of these agents. In fact, PMA induces a rapid down-regulation of cell surface TcR/CD3 expression. In contrast, these agents trigger an increase in cell surface IL2R expression which coincides with augmented IL2R-alpha mRNA levels. Thus, in RS4.2 cells, IL2R surface expression is controlled by transcript levels, while TcR/CD3 surface expression is regulated by post-transcriptional events, independent of TcR-alpha mRNA accumulation.

A model system for T-lymphocyte differentiation: regulation of CD4 and CD8 gene expression in SL12.4 T-lymphoma cell clones.

The T-cell surface proteins CD4 (L3T4) and CD8 (Lyt2) are first expressed on thymocytes as they undergo maturation in the thymus. Two immature T-lymphoma cell clones SL12.4 and RS4.2 which constitutively express low or undetectable levels of CD4 and CD8 were used to investigate the activation of CD4 and CD8 gene expression. The protein synthesis inhibitors cycloheximide (CHX) and pactamycin rapidly and reversibly increased CD4 and CD8 mRNA in the cloned cell lines, suggesting that a labile inhibitor protein(s) may regulate the expression of these transcripts. Cell surface CD4 and CD8 proteins were transiently detectable following a pulse of CHX. Thymic epithelial cell lines also induced CD4 and CD8 mRNA and cell surface protein, as well as TCR-alpha mRNA when co-cultivated with SL12.4 T lymphoma cells. The increase in CD4 and CD8 was modest, but stable for at least 22 cell generations after the thymic epithelial inducer cells were removed. Epithelial cells of non-thymic origin did not cause induction of these T-cell differentiation markers in SL12.4 T-lymphoma cells. Since the induction elicited by thymic epithelial cells and protein synthesis inhibitors differed dramatically in kinetics and reversibility, it is likely that these inducers act, at least in part, via different mechanisms. This lymphoma model system may be useful for analysis of molecular events which occur in immature thymocytes undergoing differentiation.

Irradiation selectively inhibits expression from the androgen-dependent Pem homeobox gene promoter in sertoli cells.

How radiation blocks spermatogenesis in certain strains of rats, such as LBNF(1), is not known. Because the block depends on androgen, we propose that androgen affects Sertoli cell function in irradiated LBNF(1) rats, resulting in the failure of spermatogonial differentiation. To begin to identify genes that may participate in this irradiation-induced blockade of spermatogenesis, we investigated the expression of several Sertoli genes in response to irradiation. The expression of the PEM: homeobox gene from its androgen-dependent Sertoli-specific proximal promoter (Pp) was dramatically reduced more than 100-fold in response to irradiation. In contrast, most other genes and gene products reported to be localized to the Sertoli cell, including FSH receptor (FSHR), androgen receptor (AR), SGP1, and the transcription factor CREB, did not exhibit significant changes in expression, whereas transferrin messenger RNA (mRNA) expression dramatically increased in response to irradiation. Irradiation also decreased Pp-driven PEM: mRNA levels in mouse testes (approximately 10-fold), although higher doses of irradiation than in rats were required to inhibit PEM: gene expression in testes of mice, consistent with their greater radioresistance. The decrease in Pem gene expression in mouse testis was also selective, as the expression of CREB, GATA-1, and SGP1 were little affected by irradiation. We conclude that the dramatic irradiation-triggered reduction of Pem expression in Sertoli cells is a conserved response that may be a marker for functional changes in response to irradiation.

A processed homeobox gene expressed in a stage-, tissue- and region-specific manner in epididymis.

Processed genes are generated by reverse transcription of mRNA and integration at a novel site in the genome and are typically transcriptionally silent. Here, we report that a processed gene on rat chromosome 4 that is highly related to the X chromosome-encoded rat Pem (r.Pem) homeobox gene is transcriptionally active. This processed gene, r.Pem2, is expressed at high levels in epididymis but not in any other tissues that express the r.Pem gene, including testis. Although r.Pem2, is expressed at high levels in epididymis but not in any other tissues that express the r.Pem gene, including testis. Although r.Pem2 lacks all the introns present in the r.Pem gene, it contains splice donor and acceptor sequences within the coding region, permitting it to be spliced and to potentially encode a 57 amino acid polypeptide. r.Pem2 transcripts accumulate in the caput and cauda regions of the epididymis but not in the initial segment. The r.Pem2 gene exhibits different regulation from the r.Pem gene; its expression is induced later during prepubertal development (between days 23 and 30 post partum) and independently of the presence of testosterone. Although the functional significance of r.Pem2 is unknown, its developmental regulation and its apparent acquisition of splicing sites during evolution are unique.

Changes in arterial blood pressure alter activity of electrophysiologically identified single units of the bed nucleus of the stria terminalis.

The bed nucleus of the stria terminalis may play a role in cardiovascular function by way of its connectivity to the diagonal band of Broca/ventral septal area. The present study sought to determine whether changes in systemic blood pressure affect the electrical activity of single units within the bed nucleus of the stria terminalis. Extracellular voltage recordings from neurons in the bed nucleus were performed in urethane-anaesthetized rats catheterized for arterial blood pressure measurements and for the intravenous administration of pressor and depressor drugs. Afferent or efferent connectivity of each recorded neuron was determined following electrical stimulation of nearby nuclei with and without known barosensitive regions. Of neurons demonstrating efferent connectivity (antidromically evoked potentials) with the diagonal band of Broca/ventral septal area or habenular nuclei, 24 and 20%, respectively, responded to changes in blood pressure with either increases or decreases in firing frequency. Paraventricular nucleus-projecting neurons were not affected by alterations in arterial blood pressure. Orthodromic potentials (inhibitory and/or excitatory) in the bed nucleus were also observed following stimulation of these nearby nuclei. Of these orthodromically activated neurons, changes in arterial pressure affected 31% of neurons receiving input from the diagonal band of Broca/ventral septal area, 33% of neurons with connectivity to the habenular nuclei and 60% of neurons with connectivity to the paraventricular nucleus. These data show that the bed nucleus of the stria terminalis contains a sub-population of cells that are sensitive to deviations in resting arterial pressure and that these cells receive synaptic modulation from several limbic/forebrain sources. Furthermore, the results are consistent with a role for the bed nucleus in the control of cardiovascular function and as a relay nucleus for modified baroreceptor input toward the diagonal band of Broca/ventral septal area.

Central vasopressin V1-blockade prevents salicylate but not acetaminophen antipyresis.

Recent evidence has suggested that the endogenous antipyretic arginine vasopressin (AVP) may participate in drug-induced antipyresis. This study sought to further those investigations by comparing the effects of two other antipyretic drugs, sodium salicylate and acetaminophen, administered intraperitoneally, during AVP V1-receptor blockade within the ventral septal area (VSA) of the rat brain. During endotoxin-evoked fever, V1-receptor blockade within the VSA of the conscious unrestrained rat significantly antagonized the antipyretic effects of salicylate. The effects of the V1-antagonist on salicylate-induced antipyresis were dose related. In contrast, the antipyresis elicited by acetaminophen was unaffected by VSA V1-antagonist pretreatment. Neither saline nor the V1-antagonist microinjected into the VSA of febrile or nonfebrile rats had any significant effects on the normal progression of endotoxin fever or normal core temperature, respectively. These data suggest that the mechanism of action of salicylate-induced antipyresis includes activation of AVP V1-type receptors within the VSA, as has been shown for indomethacin. However, the lack of effect of the V1-antagonist on antipyresis induced by acetaminophen indicates that not all antipyretic drugs act through the same mechanism in the brain.

Antipyresis due to centrally administered vasopressin differentially alters thermoregulatory effectors depending on the ambient temperature.

The intracerebroventricular (i.c.v.) administration of arginine vasopressin (AVP), in the febrile rat elicits an antipyresis at cold, warm and neutral ambient temperatures. These experiments were conducted, therefore, to elucidate the thermoregulatory effector mechanisms responsible for this antipyretic effect. At 25 degrees C, AVP-induced antipyresis was mediated by tail skin vasodilation while metabolic rate was unaffected. At 4 degrees C, the antipyresis produced by AVP was approximately double that seen at 25 degrees C. This effect appeared to be mediated exclusively by inhibition of heat production since the metabolic rate decreased markedly following AVP. This antipyresis at 4 degrees C was accompanied by cutaneous vasoconstriction. At 32 degrees C, neither vasomotor tone, metabolic rate nor evaporative heat loss could be shown to contribute to the small antipyretic effect elicited by AVP. We conclude from these data that i.c.v. AVP is producing antipyresis by affecting the febrile body temperature set-point mechanism since the thermoregulatory strategy to lose heat varies at different ambient temperatures and the decrease in body temperature cannot be shown to be due to changes in a single effector mechanism.