Satoshi Kunita

Input of Orexin/Hypocretin Neurons Revealed by a Genetically Encoded Tracer in Mice

The finding of orexin/hypocretin deficiency in narcolepsy patients suggests that this hypothalamic neuropeptide plays a crucial role in regulating sleep/wakefulness states. However, very little is known about the synaptic input of orexin/hypocretin-producing neurons (orexin neurons). We applied a transgenic method to map upstream neuronal populations that have synaptic connections to orexin neurons and revealed that orexin neurons receive input from several brain areas. These include the amygdala, basal forebrain cholinergic neurons, GABAergic neurons in the preoptic area, and serotonergic neurons in the median/paramedian raphe nuclei. Monoamine-containing groups that are innervated by orexin neurons do not receive reciprocal connections, while cholinergic neurons in the basal forebrain have reciprocal connections, which might be important for consolidating wakefulness. Electrophysiological study showed that carbachol excites almost one-third of orexin neurons and inhibits a small population of orexin neurons. These neuroanatomical findings provide important insights into the neural pathways that regulate sleep/wakefulness states.

Uterine sensitization-associated gene–1 (USAG-1), a novel BMP antagonist expressed in the kidney, accelerates tubular injury

Dialysis dependency is one of the leading causes of morbidity and mortality in the world, and once end-stage renal disease develops, it cannot be reversed by currently available therapy. Although administration of large doses of bone morphogenetic protein-7 (BMP-7) has been shown to repair established renal injury and improve renal function, the pathophysiological role of endogenous BMP-7 and regulatory mechanism of its activities remain elusive. Here we show that the product of uterine sensitization-associated gene-1 (USAG1), a novel BMP antagonist abundantly expressed in the kidney, is the central negative regulator of BMP function in the kidney and that mice lacking USAG-1 (USAG1 mice) are resistant to renal injury. USAG1 mice exhibited prolonged survival and preserved renal function in acute and chronic renal injury models. Renal BMP signaling, assessed by phosphorylation of Smad proteins, was significantly enhanced in USAG1 mice with renal injury, indicating that the preservation of renal function is attributable to enhancement of endogenous BMP signaling. Furthermore, the administration of neutralizing antibody against BMP-7 abolished renoprotection in USAG1 mice, indicating that USAG-1 plays a critical role in the modulation of renoprotective action of BMP and that inhibition of USAG-1 is a promising means of development of novel treatment for renal diseases.

Selective loss of GABAB receptors in orexin-producing neurons results in disrupted sleep/wakefulness architecture

Hypothalamic neurons that contain the neuropeptide orexin (hypocretin) play important roles in the regulation of sleep/wake. Here we analyze the in vivo and in vitro phenotype of mice lacking the GABAB1 gene specifically in orexin neurons (oxGKO mice) and demonstrate that GABAB receptors on orexin neurons are essential in stabilizing and consolidating sleep/wake states. In oxGKO brain slices, we show that the absence of GABAB receptors decreases the sensitivity of orexin neurons to both excitatory and inhibitory inputs because of augmented GABAA-mediated inhibition that increases the membrane conductance and shunts postsynaptic currents in these neurons. This increase in GABAA-mediated inhibitory tone is apparently the result of an orexin receptor type 1-mediated activation of local GABAergic interneurons that project back onto orexin neurons. oxGKO mice exhibit severe fragmentation of sleep/wake states during both the light and dark periods, without showing an abnormality in total sleep time or signs of cataplexy. Thus, GABAB receptors on orexin neurons are crucial in the appropriate control of the orexinergic tone through sleep/wake states, thereby stabilizing the state switching mechanisms.

Organ-specific Sulfation Patterns of Heparan Sulfate Generated by Extracellular Sulfatases Sulf1 and Sulf2 in Mice

Background: Extracellular endosulfatases Sulf1 and Sulf2 hydrolyze 6-O-sulfate in heparan sulfate. Results: Disaccharide analysis showed that 2-O-, 6-O-, and N-trisulfated disaccharide units in heparan sulfate were increased to different degrees in different organs in Sulf1 and Sulf2 knock-out mice. Conclusion: Sulfs generate organ-specific sulfation patterns of heparan sulfate. Significance: This may indicate differences in activity between Sulf1 and Sulf2 in vivo. Heparan sulfate endosulfatases Sulf1 and Sulf2 hydrolyze 6-O-sulfate in heparan sulfate, thereby regulating cellular signaling. Previous studies have revealed that Sulfs act predominantly on UA2S-GlcNS6S disaccharides and weakly on UA-GlcNS6S disaccharides. However, the specificity of Sulfs and their role in sulfation patterning of heparan sulfate in vivo remained unknown. Here, we performed disaccharide analysis of heparan sulfate in Sulf1 and Sulf2 knock-out mice. Significant increases in ΔUA2S-GlcNS6S were observed in the brain, small intestine, lung, spleen, testis, and skeletal muscle of adult Sulf1−/− mice and in the brain, liver, kidney, spleen, and testis of adult Sulf2−/− mice. In addition, increases in ΔUA-GlcNS6S were seen in the Sulf1−/− lung and small intestine. In contrast, the disaccharide compositions of chondroitin sulfate were not primarily altered, indicating specificity of Sulfs for heparan sulfate. For Sulf1, but not for Sulf2, mRNA expression levels in eight organs of wild-type mice were highly correlated with increases in ΔUA2S-GlcNS6S in the corresponding organs of knock-out mice. Moreover, overall changes in heparan sulfate compositions were greater in Sulf1−/− mice than in Sulf2−/− mice despite lower levels of Sulf1 mRNA expression, suggesting predominant roles of Sulf1 in heparan sulfate desulfation and distinct regulation of Sulf activities in vivo. Sulf1 and Sulf2 mRNAs were differentially expressed in restricted types of cells in organs, and consequently, the sulfation patterns of heparan sulfate were locally and distinctly altered in Sulf1 and Sulf2 knock-out mice. These findings indicate that Sulf1 and Sulf2 differentially contribute to the generation of organ-specific sulfation patterns of heparan sulfate.

Blood pressure in 15 inbred mouse strains and its lack of relation with obesity and insulin resistance in the progeny of an NZO/HILtJ x C3H/HeJ intercross.

We characterized the systolic and diastolic blood pressures of 10-week-old males from 15 inbred mouse strains and found that blood pressures among strains were continuously distributed and that strain C3H/HeJ had the lowest mean systolic and diastolic pressure (100.5 ± 3.2 and 66.8 ± 3.5 mmHg), and a strain with obesity and diabetes, NZO/HILtJ, had the highest (132.4 ± 3.1 and 86.6 ± 6.9 mmHg). To understand the relationship of blood pressure with insulin resistance and obesity, we produced F1 and F2 progeny from reciprocal crosses of NZO, the strain with obesity, diabetes, and high blood pressure, and the strain with the lowest blood pressures, C3H/HeJ. Mean systolic pressures of 10-week-old (NZO × C3H)F1 and (C3H × NZO)F1 males were similar to each other (114.9 ± 3.8 and 117.2 ± 5.0 mmHg) and were intermediate to those of the parental strains. Systolic pressure of F2 males (n = 223) was distributed normally about the mean, suggesting that blood pressure is a polygenic trait. The body mass index (BMI) and plasma insulin levels of F2 progeny correlated significantly and positively with plasma leptin levels, suggesting that obesity is associated with insulin resistance. In contrast, systolic pressure did not correlate with BMI, plasma leptin levels, and plasma insulin levels, suggesting that genes underlying the development of hypertension in this intercross are not associated with the development of obesity and insulin resistance. Our results demonstrate that the progeny of NZO and C3H intercrosses are a practical and powerful tool for identifying blood pressure genes and for understanding human polygenic hypertension.

Parvovirus Nonstructural Proteins Induce an Epigenetic Modification through Histone Acetylation in Host Genes and Revert Tumor Malignancy to Benignancy

ABSTRACT Several malignant tumor cells become apoptotic and revert to the benign phenotype upon parvovirus infection. Recently, we demonstrated that the rat parvovirus RPV/UT also induces apoptosis in the rat thymic lymphoma cell line C58(NT)D. However, a minority of cells that escaped apoptosis showed properties different from the parental cells, such as resistance to apoptosis, enhanced cell adherence, and suppressed tumorigenicity. The present study was performed to determine the molecular mechanism of parvovirus-induced phenotypic modification, including oncosuppression. We demonstrated that the nonstructural (NS) proteins of RPV/UT induced apoptosis in C58(NT)D cells and suppressed tumor growth in vivo. Interestingly, NS proteins induced the expression of ciliary neurotrophic factor receptor alpha, which is up-regulated in revertant cell clones, and enhanced histone acetylation of its gene. These results indicate that parvoviral NS regulate host gene expression through histone acetylation, suggesting a possible mechanism of oncosuppression.

Identification and Characterization of Hemolysin-Like Proteins Similar to RTX Toxin in Pasteurella pneumotropica

Pasteurella pneumotropica is an opportunistic pathogen that causes lethal pneumonia in immunodeficient rodents. The virulence factors of this bacterium remain unknown. In this study, we identified the genes encoding two RTX toxins, designated as pnxI and pnxII, from the genomic DNA of P. pneumotropica ATCC 35149 and characterized with respect to hemolysis. The pnxI operon was organized according to the manner in which the genes encoded the structural RTX toxin (pnxIA), the type I secretion systems (pnxIB and pnxID), and the unknown orf. The pnxII gene was involved only with the pnxIIA that coded for a structural RTX toxin. Both the structural RTX toxins of deduced PnxIA and PnxIIA were involved in seven of the RTX repeat and repeat-like sequences. By quantitative PCR analysis of the structural RTX toxin-encoding genes in P. pneumotropica ATCC 35149, the gene expression of pnxIA was found to have increased from the early log phase, while that of pnxIIA increased from the late log to the early stationary phase. As expressed in Escherichia coli, both the recombinant proteins of PnxIA and PnxIIA showed weak hemolytic activity in both sheep and murine erythrocytes. On the basis of the results of the Southern blotting analysis, the pnxIA gene was detected in 82% of the isolates, while the pnxIIA gene was detected in 39%. These results indicate that the products of both pnxIA and pnxIIA were putative associations of virulence factors in the rodent pathogen P. pneumotropica.

Pregnancy-associated homeostasis and dysregulation: lessons from genetically modified animal models

Physiological alterations occur in many organ systems during pregnancy. These changes are necessary for the adaptation to pregnancy-specific physiological processes in mother and fetus, and the placenta plays a critical role in the maintenance of homeostasis in pregnancy. Dysregulation of these functional feto-maternal interactions leads to severe complications. There have been many attempts to create animal models that mimic the hypertensive disorders of pregnancy, especially pre-eclampsia. In this review, we summarize the physiology of pregnancy and placental function, and discuss the placental gene expression in normal pregnancy. In addition, we assess a number of established animal models focusing on a specific pathogenic mechanism of pre-eclampsia, including genetically modified mouse models involving the renin-angiotensin system. Validation of these animal models would contribute significantly to understanding the basic principles of pregnancy-associated homeostasis and the pathogenesis of pre-eclampsia.

Effect of different culture conditions on establishment of embryonic stem cells from BALB/cAJ and NZB/BINJ mice.

As the phenotype of a given single-gene mutation in mice is modulated by the genetic background of the inbred strain, embryonic stem (ES) cells derived from various inbred mouse strains are required to produce gene-targeted mice without the need for backcrossing and for detailed analysis of gene function in vivo. Here, we performed a comparative investigation of the effects of three culture conditions, LIF + KSR/ES medium described previously, High LIF + KSR/ES medium and iSTEM + LIF medium containing three inhibitors of glycogen synthase kinase 3, mitogen-activated protein kinase kinase, and fibroblast growth factor receptor signaling (3i), on the establishment of germline-competent ES cells derived from strains BALB/c and NZB mice. The results indicated that LIF + KSR/ES medium was permissive for the derivation of ES cells from NZB mice, which contribute to the somatic lineage in vivo, but not to the germline lineage. In contrast, ES cells that contribute to the makeup of chimeric mice were not propagated from blastocysts of BALB/c mice. Both germline and somatic competency were improved by increased LIF concentration in cultures of BALB/c ES cells, although we failed to establish germline-competent NZB ES cells using the same concentration of LIF. Unexpectedly, iSTEM + LIF medium containing 3i showed a negative effect on the derivation of NZB ES cells with normal chromosome numbers, but not on the maintenance of previously established ES cells. Our findings suggest that the stability of pluripotency in the inner cell mass isolated from blastocyst embryos may differ according to the genetic background of inbred mouse strains, and that although the concentration of LIF is a determinant for authentic pluripotency, including germline and somatic competency in BALB/c ES cells, additional factor(s) are required for commitment to germline lineage independent of somatic lineage in NZB ES cells.

Quantitative trait loci associated with blood pressure of metabolic syndrome in the progeny of NZO/HILtJ × C3H/HeJ intercrosses

In a previous study in 15 inbred mouse strains, we found highest and lowest systolic blood pressures in NZO/HILtJ mice (metabolic syndrome) and C3H/HeJ mice (common lean strain), respectively. To identify the loci involved in hypertension in metabolic syndrome, we performed quantitative trait locus (QTL) analysis for blood pressure with direction of cross as a covariate in segregating F2 males derived from NZO/HILtJ and C3H/HeJ mice. We detected three suggestive main-effect QTLs affecting systolic and diastolic blood pressures (SBP and DBP). We analyzed the first principle component (PC1) generated from SBP and DBP to investigate blood pressure. In addition to all the suggestive QTLs (Chrs 1, 3, and 8) in SBP and DBP, one suggestive QTL on Chr 4 was found in PC1 in the main scan. Simultaneous search identified two significant epistatic locus pairs (Chrs 1 and 4, Chrs 4 and 8) for PC1. Multiple regression analysis revealed three blood pressure QTLs (Bpq10, 100 cM on Chr 1; Bpq11, 6 cM on Chr 4; Bpq12, 29 cM on Chr 8) accounting for 29.4% of blood pressure variance. These were epistatic interaction QTLs constructing a small network centered on Chr 4, suggesting the importance of genetic interaction for development of hypertension. The blood pressure QTLs on Chrs 1, 4, and 8 were detected repeatedly in multiple studies using common inbred nonobese mouse strains, implying substantial QTL independent of development of obesity and insulin resistance. These results enhance our understanding of complicated genetic factors of hypertension in metabolic diseases.