Superoxide Dismutase Knockout Mice Research Articles

Senolytic treatment does not mitigate oxidative stress-induced muscle atrophy but improves muscle force generation in CuZn superoxide dismutase knockout mice.

Oxidative stress is associated with tissue dysfunctions that can lead to reduced health. Prior work has shown that oxidative stress contributes to both muscle atrophy and cellular senescence, which is a hallmark of aging that may drive in muscle atrophy and muscle contractile dysfunction. The purpose of the study was to test the hypothesis that cellular senescence contributes to muscle atrophy or weakness. To increase potential senescence in skeletal muscle, we used a model of oxidative stress-induced muscle frailty, the CuZn superoxide dismutase knockout (Sod1KO) mouse. We treated 6-month-old wildtype (WT) and Sod1KO mice with either vehicle or a senolytic treatment of combined dasatinib (5 mg/kg) + quercetin (50 mg/kg) (D + Q) for 3 consecutive days every 15 days. We continued treatment for 7 months and sacrificed the mice at 13 months of age. Treatment with D + Q did not preserve muscle mass, reduce NMJ fragmentation, or alter muscle protein synthesis in Sod1KO mice when compared to the vehicle-treated group. However, we observed an improvement in muscle-specific force generation in Sod1KO mice treated with D + Q when compared to Sod1KO-vehicle mice. Overall, these data suggest that reducing cellular senescence via D + Q is not sufficient to mitigate loss of muscle mass in a mouse model of oxidative stress-induced muscle frailty but may mitigate some aspects of oxidative stress-induced muscle dysfunction.

Neonatal Extracellular Superoxide Dismutase Knockout Mice Increase Total Superoxide Dismutase Activity and VEGF Expression after Chronic Hyperoxia.

Bronchopulmonary dysplasia (BPD) is a common lung disease affecting premature infants that develops after exposure to supplemental oxygen and reactive oxygen intermediates. Extracellular superoxide dismutase (SOD3) is an enzyme that processes superoxide radicals and has been shown to facilitate vascular endothelial growth factor (VEGF) and nitric oxide (NO) signaling in vascular endothelium. We utilized a mouse model of neonatal hyperoxic lung injury and SOD3 knockout (KO) mice to evaluate its function during chronic hyperoxia exposure. Wild-type age-matched neonatal C57Bl/6 (WT) and SOD3−/− (KO) mice were placed in normoxia (21% FiO2, RA) or chronic hyperoxia (75% FiO2, O2) within 24 h of birth for 14 days continuously and then euthanized. Lungs were harvested for histologic evaluation, as well as comparison of antioxidant enzyme expression, SOD activity, VEGF expression, and portions of the NO signaling pathway. Surprisingly, KO-O2 mice survived without additional alveolar simplification, microvascular remodeling, or nuclear oxidation when compared to WT-O2 mice. KO-O2 mice had increased total SOD activity and increased VEGF expression when compared to WT-O2 mice. No genotype differences were noted in intracellular antioxidant enzyme expression or the NO signaling pathway. These results demonstrate that SOD3 KO mice can survive prolonged hyperoxia without exacerbation of alveolar or vascular phenotype.

The Dual Effects of Reactive Oxygen Species on the Mandibular Alveolar Bone Formation in SOD1 Knockout Mice: Promotion or Inhibition.

The status of reactive oxygen species (ROS) correlates closely with the normal development of the oral and maxillofacial tissues. Oxidative stress caused by ROS accumulation not only affects the development of enamel and dentin but also causes pathological changes in periodontal tissues (periodontal ligament and alveolar bone) that surround the root of the tooth. Although previous studies have shown that ROS accumulation plays a pathologic role in some oral and maxillofacial tissues, the effects of ROS on alveolar bone development remain unclear. In this study, we focused on mandibular alveolar bone development of mice deficient in superoxide dismutase1 (SOD1). Analyses were performed using microcomputerized tomography (micro-CT), TRAP staining, immunohistochemical (IHC) staining, and enzyme-linked immunosorbent assay (ELISA). We found for the first time that slightly higher ROS in mandibular alveolar bone of SOD1(-/-) mice at early ages (2-4 months) caused a distinct enlargement in bone size and increased bone volume fraction (BV/TV), trabecular thickness (Tb.Th), and expression of alkaline phosphatase (ALP), Runt-related transcription factor 2 (Runx2), and osteopontin (OPN). With ROS accumulation to oxidative stress level, increased trabecular bone separation (Tb.Sp) and decreased expression of ALP, Runx2, and OPN were found in SOD1(-/-) mice at 6 months. Additionally, dosing with N-acetylcysteine (NAC) effectively mitigated bone loss and normalized expression of ALP, Runx2, and OPN. These results indicate that redox imbalance caused by SOD1 deficiency has dual effects (promotion or inhibition) on mandibular alveolar bone development, which is closely related to the concentration of ROS and the stage of growth. We present a valuable model here for investigating the effects of ROS on mandibular alveolar bone formation and highlight important roles of ROS in regulating tissue development and pathological states, illustrating the complexity of the redox signal.

Optical Coherence Tomography Findings in the Retinas of SOD1 Knockout Mice.

PurposeThe retinal phenotype of popular mouse models mimicking ophthalmic diseases, such as the superoxide dismutase 1 (SOD1) knockout (KO) mouse model, has mainly been assessed by ex vivo histology and in vivo fundus photography. We used multifunctional optical coherence tomography (OCT) to characterize the retinas of SOD1 KO mice in vivo.MethodsThe custom-made ophthalmoscope featured a combination of conventional OCT, polarization-sensitive OCT, and OCT angiography. Seven SOD1 KO mice and nine age-matched controls were imaged between 6 and 17 months of age. A postprocessing framework was used to analyze total and outer retinal thickness changes. Drusenlike lesions were segmented, and their sizes and the number of lesions were assessed quantitatively. Their appearance in the conventional reflectivity images, as well as in the corresponding polarization-sensitive images, was characterized qualitatively.ResultsDrusenlike lesions increased in size and number with age for SOD1 KO mice. Exploiting the multiple contrast channels, the appearance of the lesions was found to resemble pseudodrusen observed in eyes of patients suffering from dry age-related macular degeneration. The total and outer retinal thicknesses were lower on average after 11 months and 7 months in SOD1 KO mice compared with age-matched controls. Neovascularizations were found in one out of seven KO animals.ConclusionsOCT imaging proved beneficial for a detailed in vivo characterization of the pathological changes in SOD1 KO mice.Translational RelevancePhenotyping of animal models using modern imaging concepts can be conducted with more precision and might also ease the translation of conclusions between clinical and preclinical research.

Ascorbic acid and CoQ10 ameliorate the reproductive ability of superoxide dismutase 1-deficient female mice†.

Superoxide dismutase 1 suppresses oxidative stress within cells by decreasing the levels of superoxide anions. A dysfunction of the ovary and/or an aberrant production of sex hormones are suspected causes for infertility in superoxide dismutase 1-knockout mice. We report on attempts to rescue the infertility in female knockout mice by providing two antioxidants, ascorbic acid and/or coenzyme Q10, as supplements in the drinking water of the knockout mice after weaning and on an investigation of their reproductive ability. On the first parturition, 80% of the untreated knockout mice produced smaller litter sizes compared with wild-type mice (average 2.8 vs 7.3 pups/mouse), and supplementing with these antioxidants failed to improve these litter sizes. However, in the second parturition of the knockout mice, the parturition rate was increased from 18% to 44-75% as the result of the administration of antioxidants. While plasma levels of progesterone at 7.5days of pregnancy were essentially the same between the wild-type and knockout mice and were not changed by the supplementation of these antioxidants, sizes of corpus luteum cells, which were smaller in the knockout mouse ovaries after the first parturition, were significantly ameliorated in the knockout mouse with the administration of the antioxidants. Moreover, the impaired vasculogenesis in uterus/placenta was also improved by ascorbic acid supplementation. We thus conclude that ascorbic acid and/or coenzyme Q10 are involved in maintaining ovarian and uterus/placenta homeostasis against insults that are augmented during pregnancy and that their use might have positive effects in terms of improving female fertility.

Age-related NMDA signaling alterations in SOD2 deficient mice

Oxidative stress affects the survival and function of neurons. Hence, they have a complex and highly regulated machinery to handle oxidative changes. The dysregulation of this antioxidant machinery is associated with a wide range of neurodegenerative conditions. Therefore, we evaluated signaling alterations, synaptic properties and behavioral performance in 2 and 6-month-old heterozygous manganese superoxide dismutase knockout mice (SOD2+/− mice). We found that their low antioxidant capacity generated direct oxidative damage in proteins, lipids, and DNA. However, only 6-month-old heterozygous knockout mice presented behavioral impairments. On the other hand, synaptic plasticity, synaptic strength and NMDA receptor (NMDAR) dependent postsynaptic potentials were decreased in an age-dependent manner. We also analyzed the phosphorylation state of the NMDAR subunit GluN2B. We found that while the levels of GluN2B phosphorylated on tyrosine 1472 (synaptic form) remain unchanged, we detected increased levels of GluN2B phosphorylated on tyrosine 1336 (extrasynaptic form), establishing alterations in the synaptic/extrasynaptic ratio of GluN2B. Additionally, we found increased levels of two phosphatases associated with dephosphorylation of p-1472: striatal-enriched protein tyrosine phosphatase (STEP) and phosphatase and tensin homolog deleted on chromosome Ten (PTEN). Moreover, we found decreased levels of p-CREB, a master transcription factor activated by synaptic stimulation. In summary, we describe mechanisms by which glutamatergic synapses are altered under oxidative stress conditions. Our results uncovered new putative therapeutic targets for conditions where NMDAR downstream signaling is altered. This work also contributes to our understanding of processes such as synapse formation, learning, and memory in neuropathological conditions.

A new mouse model of frailty: the Cu/Zn superoxide dismutase knockout mouse

Frailty is a geriatric syndrome that is an important public health problem for the older adults living in the USA. Although several methods have been developed to measure frailty in humans, we have very little understanding of its etiology. Because the molecular basis of frailty is poorly understood, mouse models would be of great value in determining which pathways contribute to the development of frailty. More importantly, mouse models would be critical in testing potential therapies to treat and possibly prevent frailty. In this article, we present data showing that Sod1KO mice, which lack the antioxidant enzyme, Cu/Zn superoxide dismutase, are an excellent model of frailty, and we compare the Sod1KO mice to the only other mouse model of frailty, mice with the deletion of the IL-10 gene. Sod1KO mice exhibit four characteristics that have been used to define human frailty: weight loss, weakness, low physical activity, and exhaustion. In addition, Sod1KO mice show increased inflammation and sarcopenia, which are strongly associated with human frailty. The Sod1KO mice also show alterations in pathways that have been proposed to play a role in the etiology of frailty: oxidative stress, mitochondrial dysfunction, and cell senescence. Using Sod1KO mice, we show that dietary restriction can delay/prevent characteristics of frailty in mice.

Nitric oxide inhibits neointimal hyperplasia following vascular injury via differential, cell-specific modulation of SOD-1 in the arterial wall

Superoxide (O2•−) promotes neointimal hyperplasia following arterial injury. Conversely, nitric oxide (•NO) inhibits neointimal hyperplasia through various cell-specific mechanisms, including redox regulation. What remains unclear is whether •NO exerts cell-specific regulation of the vascular redox environment following arterial injury to inhibit neointimal hyperplasia. Therefore, the aim of the present study was to assess whether •NO exerts cell-specific, differential modulation of O2•− levels throughout the arterial wall, establish the mechanism of such modulation, and determine if it regulates •NO-dependent inhibition of neointimal hyperplasia. In vivo, •NO increased superoxide dismutase-1 (SOD-1) levels following carotid artery balloon injury in a rat model. In vitro, •NO increased SOD-1 levels in vascular smooth muscle cells (VSMC), but had no effect on SOD-1 in endothelial cells or adventitial fibroblasts. This SOD-1 increase was associated with an increase in sod1 gene expression, increase in SOD-1 activity, and decrease in O2•− levels. Lastly, to determine the role of SOD-1 in •NO-mediated inhibition of neointimal hyperplasia, we performed the femoral artery wire injury model in wild type and SOD-1 knockout (KO) mice, with and without •NO. Interestingly, •NO inhibited neointimal hyperplasia only in wild type mice, with no effect in SOD-1 KO mice. In conclusion, these data show the cell-specific modulation of O2•− by •NO through regulation of SOD-1 in the vasculature, highlighting its importance on the inhibition of neointimal hyperplasia. These results also shed light into the mechanism of •NO-dependent redox balance, and suggest a novel VSMC redox target to prevent neointimal hyperplasia.

Superoxide dismutase deficiency impairs olfactory sexual signaling and alters bioenergetic function in mice.

Oxidative stress (an overproduction of reactive oxygen species in relation to defense mechanisms) may restrict investment in life history traits, such as growth, reproduction, lifespan, and the production of sexual signals to attract mates. The constraint on sexual signaling by oxidative stress is of particular interest because it has been proposed as a mechanism ensuring that only good-quality males produce the most attractive sexual signals. Despite these predictions, evidence supporting this theory is, at best, equivocal. We used a superoxide dismutase knockout mouse to demonstrate that oxidative stress directly impairs investment in morphological (preputial glands) and molecular (major urinary proteins) components of olfactory signaling essential for mate attraction. By maintaining males in a much more competitive environment than usual for mouse laboratory experiments, we also revealed a range of phenotypes of superoxide dismutase deficiency not observed in previous studies of this mouse model. This range included impaired bioenergetic function, which was undetectable in the control environment of this study. We urge further examination of model organisms in seminatural conditions and more competitive laboratory environments, as important phenotypes can be exposed under these more demanding conditions.

Effect of alcohol exposure on hepatic superoxide generation and hepcidin expression

To understand the role of mitochondrial-produced superoxide (O2 (•-)) in the regulation of iron-regulatory hormone, hepcidin by alcohol in the liver. For alcohol experiments, manganese superoxide dismutase knockout mice heterozygous for Sod2 gene expression (Sod2 (+/-)) and age-matched littermate control mice (LMC), expressing Sod2 gene on both alleles, were exposed to either 10% (w/v) ethanol in the drinking water or plain water (control) for 7 d. Total cellular O2 (•-) levels in hepatocytes isolated from the livers of mice were measured by electron paramagnetic resonance spectroscopy. The mitochondrial-targeted, O2 (•-)-sensitive fluorogenic probe, MitoSOX Red and flow cytometry were utilized to measure O2 (•-) in mitochondria. Gene and protein expression were determined by Taqman Real-time quantitative PCR and Western blotting, respectively. Sod2 (+/-) mice expressed 40% less MnSOD protein (SOD2) in hepatocytes compared to LMC mice. The deletion of Sod2 allele did not alter the basal expression level of hepcidin in the liver. 10% ethanol exposure for 1 wk inhibited hepatic hepcidin mRNA expression three-fold both in Sod2 (+/-) and LMC mice. O2 (•-) levels in hepatocytes of untreated Sod2 (+/-) mice were three-fold higher than in untreated LMC mice, as observed by electron paramagnetic resonance spectroscopy. O2 (•-) levels in mitochondria of Sod2 (+/) mice were four-fold higher than in mitochondria of untreated LMC mice, as measured by MitoSOX Red fluorescence and flow cytometry. Alcohol induced a two-fold higher increase in O2 (•-) levels in hepatocytes of LMC mice than in Sod2 (+/-) mice compared to respective untreated counterparts. In contrast, 1 wk alcohol exposure did not alter mitochondrial O2 (•-) levels in both Sod2 (+/-) and control mice. Mitochondrial O2 (•-) is not involved in the inhibition of liver hepcidin transcription and thereby regulation of iron metabolism by alcohol. These findings also suggest that short-term alcohol consumption significantly elevates O2 (•-) levels in hepatocytes, which appears not to originate from mitochondria.

Generation and characterization of a novel kidney-specific manganese superoxide dismutase knockout mouse

Inactivation of manganese superoxide dismutase (MnSOD), a mitochondrial antioxidant, has been associated with renal disorders and often results in detrimental downstream events that are mechanistically not clear. Development of an animal model that exhibits kidney-specific deficiency of MnSOD would be extremely beneficial in exploring the downstream events that occur following MnSOD inactivation. Using Cre-Lox recombination technology, kidney-specific MnSOD deficient mice (both 100% and 50%) were generated that exhibited low expression of MnSOD in discrete renal cell types and reduced enzymatic activity within the kidney. These kidney-specific 100% KO mice possessed a normal life-span, although it was interesting that the mice were smaller. Consistent with the important role in scavenging superoxide radicals, the kidney-specific KO mice showed a significant increase in oxidative stress (tyrosine nitration) in a gene-dose dependent manner. In addition, loss of MnSOD resulted in mild renal damage (tubular dilation and cell swelling). Hence, this novel mouse model will aid in determining the specific role (local and/or systemic) governed by MnSOD within certain kidney cells. Moreover, these mice will serve as a powerful tool to explore molecular mechanisms that occur downstream of MnSOD inactivation in renal disorders or possibly in other pathologies that rely on normal renal function.

Sex of the Animal Impacts Responses to Angiotensin II, Oxidative Stress Levels, and Nitric Oxide Bioavailability

HomeHypertensionVol. 57, No. 5Sex of the Animal Impacts Responses to Angiotensin II, Oxidative Stress Levels, and Nitric Oxide Bioavailability Free AccessLetterPDF/EPUBAboutView PDFView EPUBSections ToolsAdd to favoritesDownload citationsTrack citationsPermissions ShareShare onFacebookTwitterLinked InMendeleyReddit Jump toFree AccessLetterPDF/EPUBSex of the Animal Impacts Responses to Angiotensin II, Oxidative Stress Levels, and Nitric Oxide Bioavailability Krystal N. Brinson and Jennifer C. Sullivan Krystal N. BrinsonKrystal N. Brinson Search for more papers by this author and Jennifer C. SullivanJennifer C. Sullivan Search for more papers by this author Originally published28 Feb 2011https://doi.org/10.1161/HYPERTENSIONAHA.111.171017Hypertension. 2011;57:e18Other version(s) of this articleYou are viewing the most recent version of this article. Previous versions: January 1, 2011: Previous Version 1 To the Editor:Oxidative stress has been implicated in the pathogenesis of renal and cardiovascular diseases; however, there is still much to be learned. It is against this background that we read with great interest the article titled, “Superoxide Dismutase 1 Limits Renal Microvascular Remodeling and Attenuates Arteriole and Blood Pressure Responses to Angiotensin II via Modulation of Nitric Oxide Bioavailability,” by Carlström et al.1 The goal of this article was to determine the functional role of superoxide dismutase 1 (SOD1) in regulating renal microvascular function and blood pressure responses to angiotensin (Ang) II. The authors found that SOD1 knockout mice had a greater initial increase in blood pressure to chronic Ang II compared with wild-type control mice. In addition, renal afferent arterioles from SOD1 knockout mice were significantly more sensitive to acute Ang II–induced vasoconstriction compared with wild type, whereas arterioles from SOD1 transgenic mice were less sensitive to Ang II versus controls. Altered vascular responsiveness was likely attributed to low levels of NO bioavailability in arterioles from SOD1-knockout mice and enhanced levels of superoxide.Although the authors are to be commended on their excellent work, we would like to call attention to the fact that experiments were conducted using both male and female SOD1-transgenic, SOD1 knockout, and wild-type littermate mice with an equal distribution of both sexes in all of the experiments. Based on known sex differences in blood pressure and vascular responses to Ang II,2 sex differences in NO bioavailability,3 and sex differences in oxidative stress and antioxidant potential,4 the inclusion of both sexes may be a confounding factor in the study. In fact, if only males had been included, the differences between the SOD1-knockout and transgenic mice and the appropriate wild-type control groups may have been more dramatic. For example, female experimental animals have been shown to be less sensitive to Ang II–induced hypertension, therefore, it would be interesting to know whether the blood pressure data in Figure 2 of their article included 2 males and 3 females or 3 males and 2 females. The inclusion of both sexes may also contribute to the greater variability in the blood pressure data with Ang II infusion. In addition, we recently published that female SOD3 knockout mice maintain total SOD activity because of a compensatory upregulation of SOD1 activity.5In closing, although we applaud the authors on the inclusion of females in their study, we encourage them to examine the data between the sexes separately. Based on existing data in the literature, they may find additional novel findings based on the sex of the animal.Krystal N. Brinson Vascular Biology Center Georgia Health Science University Augusta, GAJennifer C. Sullivan Vascular Biology Center and Department of Pharmacology and Toxicology Georgia Health Science University Augusta, GASources of FundingSupported by NIH1R01 HL-093271-01A1 to J.C.S.DisclosuresNone.FootnotesLetters to the Editor will be published, if suitable, as space permits. They should not exceed 1000 words (typed double-spaced) in length and may be subject to editing or abridgment.

Characterization of novel kidney specific manganese superoxide dismutase knockout mice

Inactivation of manganese superoxide dismutase (MnSOD), the major mitochondrial antioxidant, is a key issue in renal failure following transplantation or ischemia/reperfusion (IR) injury. Homozygous MnSOD knock out (KO) mice die shortly after birth, and heterozygous MnSOD KO mice have decreased MnSOD activity in all tissues/organs. To address the role MnSOD inactivation has on renal injury, we generated bi‐transgenic kidney specific MnSOD KO (50% and 100%) mice by breeding KidneyCre mice1 and floxed MnSOD mice2. Characterization of these KOs revealed that phenotypically the mice are smaller in size compared to littermate controls, but show no survival differences. Immunohistochemistry data showed that the Cre‐recombinase mediated MnSOD deletion occurred specifically in the kidney and was located predominantly in the medullary region. The kidney specific KOs exhibited histologic evidence of mild renal damage, increased tyrosine nitration, and renal cell death. KO mice renal function was not altered; however, more renal damage was observed following IR injury compared to littermate controls. In summary, we have developed a novel kidney specific MnSOD KO mouse model that will help define the molecular pathways that occur downstream of MnSOD inactivation during renal injury.Supported by NIH grant 1RO1DK0789361.

Contractile Properties of Whole Skeletal Muscle and Single Muscle Fibers from Young and Old Superoxide Dismutase Knockout Mice

CuZn‐SOD knockout mice (Sod1−/−) have elevated oxidative stress, decreased body mass, and decreased lifespan compared to wild‐type mice (Sod1+/+). Sod1−/− exhibit age‐related decreases in whole muscle mass, absolute maximum isometric force (F0) and specific F0 (sF0), F0 normalized by cross‐sectional area (CSA). Reduced sF0 in whole muscle of Sod1−/− could be due to decreased sF0 of individual fibers or to non‐functional fibers that contribute to CSA but not force. We tested the hypothesis that sF0 of single fibers from Sod1−/− is lower than that of Sod1+/+ mice. Single fibers were obtained from the gastrocnemius muscle of Sod1+/+ and Sod1−/− mice at 8 and 20 mo of age. Single fiber F0 and CSA were measured and sF0 was calculated. The F0 of single fibers decreased with age (P=0.037) in both Sod1+/+ and Sod1−/− groups, but no difference was observed between the groups (P=0.825). The CSA of the fibers decreased with age (P=0.027) for both groups, but no differences were observed between groups (P=0.971). No differences in sF0 were observed among age or genotype groups (P=0.368, 0.906). Therefore, the decrease in sF0 of whole muscles in Sod1−/− mice may be explained by an increase in a population of non‐functional fibers that contribute to the CSA of the whole muscle, but not to force production. Supported by P30 AG13283.

Increased mitochondrial content in response to mitochondrial dysfunction in skeletal muscle of Cu, Zn superoxide dismutase knockout mice

Mitochondrial biogenesis is an important mechanism allowing cells to adapt to energetic stress. Here we test whether skeletal muscle compensates for mitochondrial dysfunction induced by oxidative stress by increasing mitochondrial content in vivo. We used 31P NMR and optical spectroscopies to measure ATP and O2 fluxes in vivo in wild‐type and Cu, Zn‐superoxide dismutase knockout mice (SOD1). Adult SOD1 mice demonstrated significant mitochondrial dysfunction as indicated by a 36% lower energy coupling ratio (P/O) (P=0.03) and a 13% lower resting ATP/PCr (P=0.01). Mitochondrial dysfunction in the SOD1 mice was associated with an increased capacity for mitochondrial ATP production (1.08 ± 0.04 vs. 0.72 ± 0.10 mM ATP s−1, P=0.01) and O2 uptake (O2max) (0.30 ± 0.04 vs. 0.13 ± 0.02 mM O2 s−1, P<0.01). Cytochrome oxidase protein and gene transcript and peroxisome proliferative activated receptor, gamma, coactivator 1 alpha (PGC1a) transcript levels were positively correlated with O2max and negatively correlated with P/O across treatment groups (P<0.05), supporting a relationship between reduced energy coupling and increased mitochondrial content. These results indicate that skeletal muscle compensates for mitochondrial dysfunction in vivo by activating mitochondrial biogenesis and increasing mitochondrial content. Supported by NIH grants AG028455, AG022385, and the Ellison Medical Foundation.

Acceleration of diabetic renal injury in the superoxide dismutase knockout mouse: effects of tempol

Indices of renal injury and oxidative stress were examined in mice with deficiency of cytosolic Cu 2+/Zn 2+ superoxide dismutase (SOD1−/−, KO) and their wild-type (WT) littermates with streptozotocin-induced diabetes. After 5 weeks of diabetes, KO diabetic (D) but not WT-D mice developed marked albuminuria, increases in glomerular content of transforming growth factor β, collagen α1(IV), and nitrotyrosine, and higher glomerular superoxide compared with corresponding values in nondiabetics. After 5 months of diabetes, increases in these parameters, mesangial matrix expansion, renal cortical malondialdehyde content, and severity of tubulointerstitial injury were all significantly greater, whereas cortical glutathione was lower, in KO-D than in WT-D. In contrast to WT-D, after 4 weeks of diabetes, KO-D mice did not develop the increase in inulin clearance ( C In) characteristic of early diabetes. The nitric oxide synthase inhibitor N ω-nitro- l-arginine methylester suppressed C In in WT-D, but had no effect on C In in KO-D. Treatment of KO-D with the SOD mimetic tempol for 4 weeks suppressed albuminuria, increases in glomerular transforming growth factor β, collagen α1(IV), nitrotyrosine, and glomerular superoxide, and concurrently increased C In. The latter action of tempol in KO-D was blocked by the N ω-nitro- l-arginine methylester. The findings provide support for a role for superoxide and its metabolism by SOD1 in the pathogenesis of renal injury in diabetes in vivo, and implicate increased interaction of superoxide with nitric oxide as a pathogenetic factor.

Heterozygous Deficiency of Manganese Superoxide Dismutase in Mice (Mn-SOD+/-): A Novel Approach to Assess the Role of Oxidative Stress for the Development of Nitrate Tolerance

Nitroglycerin (GTN)-induced tolerance was reported to be associated with increased levels of reactive oxygen species (ROS) in mitochondria. In the present study, we further investigated the role of ROS for the development of nitrate tolerance by using heterozygous manganese superoxide dismutase knock-out mice (Mn-SOD+/-). Mn-SOD is acknowledged as a major sink for mitochondrial superoxide. Vasodilator potency of mouse aorta in response to acetylcholine and GTN was assessed by isometric tension studies. Mitochondrial ROS formation was detected by 8-amino-5-chloro-7-phenylpyrido[3,4-d]pyridazine-1,4-(2H,3H)dione sodium salt (L-012)-enhanced chemiluminescence and mitochondrial aldehyde dehydrogenase (ALDH-2) activity was determined by a high-performance liquid chromatography-based assay. Aortic rings from Mn-SOD+/- mice showed normal endothelial function and vasodilator responses to GTN. In contrast, preincubation of aorta with GTN or long-term GTN infusion caused a marked higher degree of tolerance as well as endothelial dysfunction in Mn-SOD+/- compared with wild type. Basal as well as GTN-stimulated ROS formation was significantly increased in isolated heart mitochondria from Mn-SOD+/- mice, correlating well with a marked decrease in ALDH-2 activity in response to in vitro and in vivo GTN treatment. The data presented indicate that deficiency in Mn-SOD leads to a higher degree of tolerance and endothelial dysfunction associated with increased mitochondrial ROS production in response to in vitro and in vivo GTN challenges. These data further point to a crucial role of ALDH-2 in mediating GTN bioactivation as well as development of GTN tolerance and underline the important contribution of ROS to these processes.

Skeletal muscle reperfusion injury is enhanced in extracellular superoxide dismutase knockout mouse

This study investigates the role of extracellular SOD (EC-SOD), the major extracellular antioxidant enzyme, in skeletal muscle ischemia and reperfusion (I/R) injury. Pedicled cremaster muscle flaps from homozygous EC-SOD knockout (EC-SOD-/-) and wild-type (WT) mice were subjected to 4.5-h ischemia and 90-min reperfusion followed by functional and molecular analyses. Our results revealed that EC-SOD-/- mice showed significantly profound I/R injury compared with WT littermates. In particular, there was a delayed and incomplete recovery of arterial spasm and blood flow during reperfusion, and more severe acute inflammatory reaction and muscle damage were noted in EC-SOD-/- mice. After 90-min reperfusion, intracellular SOD [copper- and zinc-containing SOD (CuZn-SOD) and manganese-containing (Mn-SOD)] mRNA levels decreased similarly in both groups. EC-SOD mRNA levels increased in WT mice, whereas EC-SOD mRNA was undetectable, as expected, in EC-SOD-/- mice. In both groups of animals, CuZn-SOD protein levels decreased and Mn-SOD protein levels remained unchanged. EC-SOD protein levels decreased in WT mice. Histological analysis showed diffuse edema and inflammation around muscle fibers, which was more pronounced in EC-SOD-/- mice. In conclusion, our data suggest that EC-SOD plays an important role in the protection from skeletal muscle I/R injury caused by excessive generation of reactive oxygen species.

Inhibition of iNOS attenuates skeletal muscle reperfusion injury in extracellular superoxide dismutase knockout mice

Reactive oxygen species (ROS) and reactive nitrogen species (RNS) are closely involved in the mechanism of skeletal muscle ischemia/reperfusion (I/R) injury. This study was designed to determine the effects of inducible nitric oxide synthase (iNOS) inhibitor 1400 W on the reperfused cremaster muscle in extracellular super-oxide dismutase knockout (EC-SOD(-/-)) mice. The muscle was exposed to 4.5 h of ischemia, followed by 90 min of reperfusion. Mice received either 3 mg/kg of 1400 W or the same amount of phosphate-buffered saline (PBS, as a control) subcutaneously at 10 min before the start of reperfusion. 1400 W treatment markedly improved the recovery speed of vessel diameter and blood flow in the reperfused cremaster muscle of EC-SOD(-/-) mice compared to controls. Histological examination showed reduced edema in the interstitial space and muscle fiber, and reduced density of nitrotyrosine (a marker of total peroxi-nitrate (ONOO(-)) level) in 1400 W-treated muscles compared to controls. Our results suggest that iNOS and ONOO(-) products are involved in skeletal muscle I/R injury. Reduced I/R injury by using selective inhibition of iNOS perhaps works by limiting cytotoxic ONOO(-) generation, a reaction product of nitric oxide (NO) and super-oxide anion (O(2) (-)). Thus, inhibition of iNOS appears to be a treatment strategy for reducing clinical I/R injury.

Endothelial Progenitor Cells at Work

Tissue replacement in the adult organism by cell-specific differentiation of autologous stem/progenitor cells has evolved as a fascinating concept in stem cell biology. After organ damage, bone marrow–derived circulating or tissue-resident progenitor cells are thought to differentiate toward the type of cell needed for repair. According to this concept, maturation of these cells would be expected to result at best in a perfect morphological and functional replacement of the injured tissue. However, in this issue of Arteriosclerosis, Thrombosis, and Vascular Biology , He et al show that endothelial progenitor cells (EPCs) are more than just as capable of in vitro angiogenic tube formation as mature endothelial cells (ECs), but are truly advantageous when it comes to stress tolerance.1 See page 2021 EPCs were originally characterized as cells that are mobilized from the bone marrow and circulate in the peripheral blood and express certain surface membrane markers including the vascular endothelial growth factor receptor (VEGF-R2) KDR and the hematopoietic progenitor cell markers CD34 and CD133.2–4 During ex vivo expansion, these cells develop morphological and functional characteristics typical for ECs, including formation of vascular-like structures in matrigel and other in vitro angiogenesis assays. Most importantly, however, transplanted EPCs exhibit an extraordinary potent in vivo capacity to improve the neovascularization of ischemic tissue in the adult organism.5 In this regard, EPCs were shown to be more effective than mature ECs in animal models of hind limb ischemia,6–8 although mature ECs are well established to exert a potent in vitro angiogenic activity. Thus, the …