Role of different proton-sensitive channels in releasing calcitonin gene-related peptide from isolated hearts of mutant mice

OBJECTIVE: Calcitonin gene-related peptide (CGRP), a potent vasodilator released from a subset of sensory Adelta- and C-fiber afferents, has been suggested to play a beneficial role in myocardial ischemia. The aim of the present study was to investigate some receptors possibly involved in the proton-mediated CGRP release from the heart. METHODS: CGRP release from freshly isolated hearts of mice lacking the capsaicin receptor (TRPV1-/-), the bradykinin receptor type 2 (B2-/-), or the acid-sensing ion channel type 3 (ASIC3-/-) and their wild-type littermates (TRPV1+/+, B2+/+, ASIC3+/+) were compared. Hearts were passed through a series of solutions based on oxygenated synthetic interstitial fluid (SIF). SIF buffered to pH 5.7 or 5.2 was used as an acidic test stimulus, and capsaicin (5x10(-7) M) was finally applied as a positive control. All eluates were processed using an enzyme immunoassay (EIA) for measurement of CGRP concentrations. RESULTS: SIF at pH 5.7 and 5.2 caused significant increases in CGRP release in TRPV1+/+ but not in mice lacking the TRPV1 receptor. The same acid stimuli caused no significant differences in CGRP release between ASIC3+/+ and ASIC3-/- or between B2+/+ and B2-/-, respectively. Capsaicin caused massive CGRP release in all mouse genotypes with the exception of TRPV1-/-. CONCLUSION: We conclude that cardiac acidosis is a strong stimulus to release CGRP from the mouse heart. This effect seems to be primarily mediated through activation of TRPV1 receptors that are known to be expressed by slowly conducting nociceptive primary afferent nerve fibers.     

Modulation of the polyamine biosynthetic pathway in transgenic rice confers tolerance to drought stress

We have generated transgenic rice plants expressing the Datura stramonium adc gene and investigated their response to drought stress. We monitored the steady-state mRNA levels of genes involved in polyamine biosynthesis (Datura adc, rice adc, and rice samdc) and polyamine levels. Wild-type plants responded to the onset of drought stress by increasing endogenous putrescine levels, but this was insufficient to trigger the conversion of putrescine into spermidine and spermine (the agents that are believed to protect plants under stress). In contrast, transgenic plants expressing Datura adc produced much higher levels of putrescine under stress, promoting spermidine and spermine synthesis and ultimately protecting the plants from drought. We demonstrate clearly that the manipulation of polyamine biosynthesis in plants can produce drought-tolerant germplasm, and we propose a model consistent with the role of polyamines in the protection of plants against abiotic stress.     

人心肌三磷酸腺苷敏感性钾通道的结构异质性及其与心房扩大的关联

目的探讨人心房肌和心室肌细胞膜上三磷酸腺苷敏感性钾通道(KATP)的结构差异性,及其主要调节亚单位磺酰脲类受体(SUR1和SUR2A)两者mRNA表达量与心房扩大的关系。方法应用逆转录聚合酶链式反应分析正常个体心房肌和心室肌组织中KATP主要配基SUR1和SUR2A mRNA表达量的差异(共7例,左房/左室),对比正常个体左右心房(左房7例,右房6例)SUR1和SUR2A mRNA表达量的差异,并比较病人组扩大心房(8例)和正常心房(29例)两种配基的mRNA表达量差异。结果 KATP通道配基SUR1在正常个体心房中mRNA的表达高于心室(0.438 00±0.197 42 vs 0.219 7±0.077 11,P<0.05),SUR2A则在心室的表达明显高于心房(0.543 7±0.091 61 vs 0.331 9±0.087 35,P<0.05)。正常个体左房和右房中两种调节亚基其mRNA的表达量无差异,P>0.05。病人组扩大心房中SUR1表达明显增加(0.595 9±0.081 56 vs 0.331 8±0.051 08,P<0.05;心房扩大后SUR2A的表达量也有增加(0.556 1±0.175 76 vs 0.380 1±0.108 94,P<0.05)。结论正常人心房肌和心室肌细胞膜上的KATP通道存在结构异质性,心房肌的主要配基为SUR1,而心室肌主要是SUR2A,两种配基其mRNA的表达量随心房的扩大而改变。     

Modulation of potassium channels by antiarrhythmic and antihypertensive drugs.

Agents that modulate cardiac and smooth muscle K+ channels have stimulated considerable interest in recent years because of their therapeutic potential in a number of cardiovascular diseases. Foremost among these drugs are the so-called Class III antiarrhythmic agents, which act by prolonging cardiac action potentials, and K+ channel openers, which hyperpolarize and thereby relax smooth muscle cells. Many of the newly developed Class III antiarrhythmic agents probably act by specific block of one subtype of delayed rectifier K+ current, IKr, whereas other agents block more than one type of cardiac K+ current. Much controversy exists over the specific type of K+ channel (or channels) in smooth muscle that are activated by the K+ channel openers. Both groups of K+ channel modulators have great therapeutic promise, but the Class III antiarrhythmic agents may suffer from a side-effect that is directly linked to their specific mechanism of action.     

The role of polyamine biosynthesis in hematopoietic precursor cell proliferation in mice

Under the influence of a selective irreversible inhibitor of ornithine decarboxylase (ODC), DL-alpha-difluoromethylornithine (DFMO), early hematopoiesis was enhanced. In the bone marrow, the absolute number of cells that give rise to spleen colonies in lethally irradiated mice (CFU-S), granulocytic colonies in diffusion chambers in mice (CFU-DG), and granulocyte-monocyte colonies in agar in vitro (CFU-C) was increased 2-4 fold. This could be abrogated by administration of putrescine, confirming the association of the stimulatory effect with polyamine biosynthesis most likely via depression of ornithine decarboxylase activity and subsequent synthesis of putrescine. Analysis of cell cycle characteristics by 3H-TdR suicide technique demonstrated that the proportion of CFU-S, CFU-DG, and CFU-C in S-phase was significantly increased. Additionally, the stimulatory effect was reflected by enhanced colony formation in diffusion chambers implanted intraperitoneally in mice receiving DFMO. This could also be eliminated by treatment of the host animal with putrescine, again suggesting that polyamine biosynthesis plays an important role at the early stages of hematopoiesis in vivo. Effect of DFMO on colony formation in vitro (CFU- C) was inhibitory and not reversible with putrescine. It could be partially eliminated by aminoguanidine, which neutralizes diamine oxidase present in fetal calf serum used in the CFU-C assay. These data suggest that the effect of DFMO in vitro was nonspecific.     

Pharmacological activation of normal and arrhythmia-associated mutant KCNQ1 potassium channels

KCNQ1 alpha-subunits coassemble with KCNE1 beta-subunits to form channels that conduct the slow delayed rectifier K+ current (IKs) important for repolarization of the cardiac action potential. Mutations in KCNQ1 reduce IKs and cause long-QT syndrome, a disorder of ventricular repolarization that predisposes affected individuals to arrhythmia and sudden death. Current therapy for long-QT syndrome is inadequate. R-L3 is a benzodiazepine that activates IKs and has the potential to provide gene-specific therapy. In the present study, we characterize the molecular determinants of R-L3 interaction with KCNQ1 channels, use computer modeling to propose a mechanism for drug-induced changes in channel gating, and determine its effect on several long-QT syndrome-associated mutant KCNQ1 channels heterologously expressed in Xenopus oocytes. Scanning mutagenesis combined with voltage-clamp analysis indicated that R-L3 interacts with specific residues located in the 5th and 6th transmembrane domains of KCNQ1 subunits. Most KCNQ1 mutant channels responded to R-L3 similarly to wild-type channels, but one mutant channel (G306R) was insensitive to R-L3 possibly because it disrupted a key component of the drug-binding site.     

Elevated blood pressure in transgenic lipoatrophic mice and altered vascular function

The role of perivascular fat in the control of vascular function was studied using lipoatrophic A-ZIP/F1 transgenic mice. Only a small amount of brown fat was found around the aorta but not around mesenteric arteries. Blood pressure of A-ZIP/F1 mice became higher than wild-type (WT) mice from 10 weeks of age. The presence of perivascular fat reduced the contraction of WT aorta to phenylephrine and serotonin, whereas this effect was either absent or less prominent in A-ZIP/F1 aorta. In WT mice, transfer of solution incubated with aorta with fat to aorta with fat removed caused a relaxation response, but not in A-ZIP/F1 mice, indicating the release of a relaxation factor from perivascular fat in WT aorta. This factor was acting through the activation of calcium-dependent potassium channels. Perfusion of phenylephrine to the isolated mesenteric bed caused a higher increase in perfusion pressure in A-ZIP/F1 than in WT mice. Contractile response of aorta to angiotensin II (Ang II) was mediated by Ang II type 1 receptors and was higher in A-ZIP/F1 than in WT mice. Expression of Ang II type 1 receptors but not Ang II type 2 receptors was higher in aorta of A-ZIP/F1 than WT mice. Treatment with an Ang II type 1 receptor antagonist (TCV 116, 10 mg/kg per day) for 2 weeks normalized the blood pressure of A-ZIP/F1 mice. These results suggest that the absence of perivascular fat tissue, which enhances the contractile response of the blood vessels to agonists, and an upregulation of vascular Ang II type 1 receptors in A-ZIP/F1 mice, are some of the mechanisms underlying the blood pressure elevation in these lipoatrophic mice.     

New findings in gene knockout, mutant and transgenic mice

During the past year, some novel genetic modifications were shown to alter the lifespan of mice, thus expanding the list of genes and physiological processes that influence mammalian aging. Considerable progress was also made in identifying putative mechanisms of extended longevity in previously described gene knockouts, mutants and transgenics. In addition, new leads concerning mechanisms of aging were derived from studies of gene knockout mice in which aging is accelerated. Among the important findings from the period July 2006 to July 2007: Core body temperature was shown to influence longevity in homeothermic animals; a Surf1 gene knockout extended lifespan in mice; separate studies using Little and Snell dwarf mice found stress resistance enhancements correlated with longevity gains; and mice heterozygous for deletion of insulin receptor substrate 2 (IRS-2) lived longer than normal animals, while animals with homozygous or heterozygous deletion of IRS-2 selectively in the brain exhibited comparable extension of lifespan and various symptoms of delayed aging.     

New findings in transgenic, gene knockout and mutant mice

Mice with experimentally induced or spontaneous genetic alterations continue to provide new and often unexpected information on the mechanisms of mammalian aging. Papers published during the last year (July 1, 2005 through June 30, 2006) contain many exciting findings, including development and characterization of a new animal model for the study of aging. Highlights of these recent developments will be briefly discussed in this Review.     

In vivo stabilization of mutant human transthyretin in transgenic mice

Transthyretin (TTR) is a 55 kD homotetrameric serum protein transporter of retinol binding protein charged with retinol and thyroxine (T4). The highly amyloidogenic human TTR variant in which leucine at position 55 is replaced by proline (L55P TTR) is responsible for aggressive fatal amyloidosis with peripheral and autonomic neuropathy, cardiomyopathy and nephropathy. Mice bearing one or two copies of a 19.2 kB human genomic fragment containing the entire coding sequence and the known control regions of the L55P TTR transgene, failed to develop TTR amyloidosis even though their sera contained mutant human TTR. The frequency of TTR tissue deposition was increased when the L55P TTR transgene was bred onto a murine TTR-null background. Denaturation of sera from the transgenic animals and murine TTR-knockouts expressing the human L55P TTR transgene revealed that the TTR tetramer was much more stable in the presence of the murine protein because the TTR circulates as hybrid human/murine heterotetramers. Intraperitoneal administration of diflunisal, a non-steroidal anti-inflammatory drug that binds to TTR in its T4-binding site and inhibits fibril formation in vitro, to human L55P TTR transgenic animals in which the murine TTR gene had been silenced, also stabilizes the circulating mutant protein to in vitro urea denaturation.     

In vivo stabilization of mutant human transthyretin in transgenic mice.

Transthyretin (TTR) is a 55 kD homotetrameric serum protein transporter of retinol binding protein charged with retinol and thyroxine (T4). The highly amyloidogenic human TTR variant in which leucine at position 55 is replaced by proline (L55P TTR) is responsible for aggressive fatal amyloidosis with peripheral and autonomic neuropathy, cardiomyopathy and nephropathy. Mice bearing one or two copies of a 19.2 kB human genomic fragment containing the entire coding sequence and the known control regions of the L55P TTR transgene, failed to develop TTR amyloidosis even though their sera contained mutant human TTR. The frequency of TTR tissue deposition was increased when the L55P TTR transgene was bred onto a murine TTR-null background. Denaturation of sera from the transgenic animals and murine TTR-knockouts expressing the human L55P TTR transgene revealed that the TTR tetramer was much more stable in the presence of the murine protein because the TTR circulates as hybrid human/murine heterotetramers. Intraperitoneal administration of diflunisal, a non-steroidal anti-inflammatory drug that binds to TTR in its T4-binding site and inhibits fibril formation in vitro, to human L55P TTR transgenic animals in which the murine TTR gene had been silenced, also stabilizes the circulating mutant protein to in vitro urea denaturation.     

Modulation of hematopoiesis in mice with a truncated mutant of the interleukin-2 receptor gamma chain

The interleukin-2 (IL-2) receptor gamma chain is indispensable for IL-2- , IL-4-, IL-7-, IL-9-, and IL-15-mediated signaling. Mutations of the human gamma chain cause the X-linked severe combined immunodeficiency (XSCID), showing that T and natural killer cells absolutely require the gamma chain for their development in humans. To elucidate the roles of the gamma chain in hematopoiesis, we have generated mice, by gene targeting, that express a form of the gamma chain lacking the cytoplasmic region. Male mice carrying the truncated gamma-chain mutant, which mimics mutations in patients with XSCID, showed a decrease in the number of lymphocytes and an increase in monocytes; the number of T cells was profoundly reduced and no natural killer cells were detected, which is similar to the characteristic of human XSCID. Unlike human XSCID, the levels of B cells were also reduced. In spite of the severe decrease in CD45R+/sIgM+ B cells, the level of IgM in serum of the 8-week-old mutant mice was higher than that of control littermates. Interestingly, the stem cell population with surface phenotypes of CD34, c-kit, and Sca-1 was significantly increased. Furthermore, the colony-forming assay showed that the mutant mice had 15-fold higher numbers of hematopoietic progenitor cells in the spleen as compared with that of controls. These results indicate that functional loss of the gamma chain causes significant effects on the immunological system in mice.     

Modulation of erythrocyte potassium chloride cotransport, potassium content, and density by dietary magnesium intake in transgenic SAD mouse

Prevention of erythrocyte dehydration is a potential therapeutic strategy for sickle cell disease. Increasing erythrocyte magnesium (Mg) could inhibit sickle cell dehydration by increasing chloride (CI) and water content and by inhibiting potassium chloride (K-CI) cotransport. In transgenic SAD 1 and (control) C57BL/6 normal mice, we investigated the effect of 2 weeks of diet with either low Mg (6 +/- 2 mg/kg body weight/d) or high Mg (1,000 +/- 20 mg/kg body weight/ d), in comparison with a diet of standard Mg (400 +/- 20 mg/ kg body weight/d). The high- Mg diet increased SAD 1 erythrocyte Mg and K contents and reduced K-CI cotransport activity, mean corpuscular hemoglobin concentration (MCHC), cell density, and reticulocyte count. SAD 1 mice treated with low-Mg diet showed a significant reduction in erythrocyte Mg and K contents and increases in K-CI cotransport, MCHC, cell density, and reticulocyte counts. In SAD 1 mice, hematocrit (Hct) and hemoglobin (Hb) decreased significantly with low Mg diet and increased significantly with high-Mg diet. The C57BL/6 controls showed significant changes only in erythrocyte Mg and K content, and K-CI cotransport activities, similar to those observed in SAD 1 mice. Thus, in the SAD 1 mouse, changes in dietary Mg modulate K-CI cotransport, modify erythrocyte dehydration, and ultimately affect Hb levels.     

Activation of the unfolded protein response is associated with impaired granulopoiesis in transgenic mice expressing mutant Elane

Severe congenital neutropenia (SCN) is an inborn disorder of granulopoiesis that in many cases is caused by mutations of the ELANE gene, which encodes neutrophil elastase (NE). Recent data suggest a model in which ELANE mutations result in NE protein misfolding, induction of endoplasmic reticulum (ER) stress, activation of the unfolded protein response (UPR), and ultimately a block in granulocytic differentiation. To test this model, we generated transgenic mice carrying a targeted mutation of Elane (G193X) reproducing a mutation found in SCN. The G193X Elane allele produces a truncated NE protein that is rapidly degraded. Granulocytic precursors from G193X Elane mice, though without significant basal UPR activation, are sensitive to chemical induction of ER stress. Basal and stress granulopoiesis after myeloablative therapy are normal in these mice. Moreover, inaction of protein kinase RNA-like ER kinase (Perk), one of the major sensors of ER stress, either alone or in combination with G193X Elane, had no effect on basal granulopoiesis. However, inhibition of the ER-associated degradation (ERAD) pathway using a proteosome inhibitor resulted in marked neutropenia in G193X Elane. The selective sensitivity of G913X Elane granulocytic cells to ER stress provides new and strong support for the UPR model of disease patho-genesis in SCN.     

Age-related changes in polyamine biosynthesis after fasting and refeeding

The effect of aging on ornithine decarboxylase (ODC) activity and polyamine biosynthesis in the proximal small intestine was studied in two groups of male Fisher 344 rats (young [4-month old] and aged [26- to 27-month old]) using a fasting and refeeding model. In control (nonfasted) rats, levels of polyamines (putrescine, spermidine and spermine) and ODC activity were significantly higher in aged compared with young rats. In aged rats, fasting significantly reduced the levels of putrescine by 41%, spermidine by 23%, and spermine by 11%; however, fasting had no effect on polyamine levels in young rats. ODC activity was decreased 75% in young and 50% in aged rats after fasting compared with the respective age-matched controls. Conversely, 2 h after reinstituting a chow diet increased ODC activity by 17-fold in young rats but only 8-fold in aged rats. Putrescine levels were also increased in both age groups after refeeding; however, similar to ODC activity, these increases were much less in aged rats. In addition, spermidine and spermine levels remained significantly depressed in the aged groups even after 24 h of refeeding. These findings suggest that the normal rigid control of gut polyamine biosynthesis and proliferation noted in young rats is markedly altered with aging.     

Dendritic spinopathy in transgenic mice expressing ALS/dementia-linked mutant UBQLN2

Mutations in the gene encoding ubiquilin2 (UBQLN2) cause amyotrophic lateral sclerosis (ALS), frontotemporal type of dementia, or both. However, the molecular mechanisms are unknown. Here, we show that ALS/dementia-linked UBQLN2^P497H transgenic mice develop neuronal pathology with ubiquilin2/ubiquitin/p62-positive inclusions in the brain, especially in the hippocampus, recapitulating several key pathological features of dementia observed in human patients with UBQLN2 mutations. A major feature of the ubiquilin2-related pathology in these mice, and reminiscent of human disease, is a dendritic spinopathy with protein aggregation in the dendritic spines and an associated decrease in dendritic spine density and synaptic dysfunction. Finally, we show that the protein inclusions in the dendritic spines are composed of several components of the proteasome machinery, including Ub^G76V–GFP, a representative ubiquitinated protein substrate that is accumulated in the transgenic mice. Our data, therefore, directly link impaired protein degradation to inclusion formation that is associated with synaptic dysfunction and cognitive deficits. These data imply a convergent molecular pathway involving synaptic protein recycling that may also be involved in other neurodegenerative disorders, with implications for development of widely applicable rational therapeutics.Protein aggregates or inclusions with immunoreactivity to ubiquitin represent a common pathological hallmark in a broad range of late-onset neurodegenerative disorders, including Alzheimer’s disease (AD), Parkinson disease (PD), frontotemporal dementia (FTD), and amyotrophic lateral sclerosis (ALS) (1). However, the molecular mechanisms underlying the formation of these inclusions and their relationship to neuronal dysfunction and degeneration are poorly understood. Mutations in UBQLN2, which encodes the ubiquitin-like protein ubiquilin2 (UBQLN2), have been recently shown to cause a subset of ALS, FTD-type of dementia, or both (2, 3). Notably, mutations within and in close proximity to the PXX domain of ubiquilin2 appear to have high penetrance as shown in familial cases (2). The distribution of ubiquilin2-positive inclusions in the brain and spinal cord is well correlated with cognitive and motor symptoms of patients with diverse etiology, including chromosome 9 open reading frame 72 (C9ORF72)-linked cases (2, 4). The ubiquilin2-positive inclusions appear to cover a wide range of protein inclusions, including those without TAR DNA binding protein (TDP43) immunoreactivity (2, 4), suggesting a primary role for ubiquilin2 in inclusion formation and neurodegeneration. Therefore, understanding the pathophysiological basis of UBQLN2-linked dementia may provide mechanistic insight into the pathogenesis of neurodegenerative disorders and allow for the design of rational therapies. To this end, we developed and characterized mutant UBQLN2 transgenic mice.     

Chemomechanics of altered perfusion pressure in rat hearts

Summary In an apex-ejecting isolated perfused working rat heart, as well as isovolumic preparations of rat hearts, perfusion pressure was studied independent of afterload. A decrease in perfusion pressure caused an immediate decrease in developed pressure (10s). There was a significant increase in free Pi and the phosphorylation potential after 20–30 min of perfusion at a reduced coronary flow induced by a reduction in perfusion pressure. Developed pressure decreased prior to the phosphorylation potential and inorganic phosphate; however, the phosphorylation set a limit to maximum work performance. At a perfusion pressure of 140 cm H₂O and an afterload of 140 cm H₂O, work imposed on the heart was maximum; there was no further increase in work.     

TDP-43 mutant transgenic mice develop features of ALS and frontotemporal lobar degeneration

Frontotemporal lobar degeneration (FTLD) and amyotrophic lateral sclerosis (ALS) are neurodegenerative diseases that show considerable clinical and pathologic overlap, with no effective treatments available. Mutations in the RNA binding protein TDP-43 were recently identified in patients with familial amyotrophic lateral sclerosis (ALS), and TDP-43 aggregates are found in both ALS and FTLD-U (FTLD with ubiquitin aggregates), suggesting a common underlying mechanism. We report that mice expressing a mutant form of human TDP-43 develop a progressive and fatal neurodegenerative disease reminiscent of both ALS and FTLD-U. Despite universal transgene expression throughout the nervous system, pathologic aggregates of ubiquitinated proteins accumulate only in specific neuronal populations, including layer 5 pyramidal neurons in frontal cortex, as well as spinal motor neurons, recapitulating the phenomenon of selective vulnerability seen in patients with FTLD-U and ALS. Surprisingly, cytoplasmic TDP-43 aggregates are not present, and hence are not required for TDP-43-induced neurodegeneration. These results indicate that the cellular and molecular substrates for selective vulnerability in FTLD-U and ALS are shared between mice and humans, and suggest that altered DNA/RNA-binding protein function, rather than toxic aggregation, is central to TDP-43-related neurodegeneration.