MicroRNAs 29b, 133b,and 211 Regulate Vascular Smooth Muscle Calcification Mediated by High Phosphorus

Vascular calcification is a frequent cause of morbidity and mortality in patients with CKD and the general population. The common association between vascular calcification and osteoporosis suggests a link between bone and vascular disorders. Because microRNAs (miRs) are involved in the transdifferentiation of vascular smooth muscle cells into osteoblast-like cells, we investigated whether miRs implicated in osteoblast differentiation and bone formation are involved in vascular calcification. Different levels of uremia, hyperphosphatemia, and aortic calcification were induced by feeding nephrectomized rats a normal or high-phosphorus diet for 12 or 20 weeks, at which times the levels of eight miRs (miR-29b, miR-125, miR-133b, miR-135, miR-141, miR-200a, miR-204, and miR-211) in the aorta were analyzed. Compared with controls and uremic rats fed a normal diet, uremic rats fed a high-phosphorous diet had lower levels of miR-133b and miR-211 and higher levels of miR-29b that correlated respectively with greater expression of osteogenic RUNX2 and with lower expression of several inhibitors of osteoblastic differentiation. Uremia per se mildly reduced miR-133b levels only. Similar results were obtained in two in vitro models of vascular calcification (uremic serum and high–calcium and –phosphorus medium), and experiments using antagomirs and mimics to modify miR-29b, miR-133b, and miR-211 expression levels in these models confirmed that these miRs regulate the calcification process. We conclude that miR-29b, miR-133b, and miR-211 have direct roles in the vascular smooth muscle calcification induced by high phosphorus and may be new therapeutic targets in the management of vascular calcification.     

A proposed nomenclature and diagnostic criteria for protein-energy wasting in acute and chronic kidney disease

The recent research findings concerning syndromes of muscle wasting, malnutrition, and inflammation in individuals with chronic kidney disease (CKD) or acute kidney injury (AKI) have led to a need for new terminology. To address this need, the International Society of Renal Nutrition and Metabolism (ISRNM) convened an expert panel to review and develop standard terminologies and definitions related to wasting, cachexia, malnutrition, and inflammation in CKD and AKI. The ISRNM expert panel recommends the term 'protein-energy wasting' for loss of body protein mass and fuel reserves. 'Kidney disease wasting' refers to the occurrence of protein-energy wasting in CKD or AKI regardless of the cause. Cachexia is a severe form of protein-energy wasting that occurs infrequently in kidney disease. Protein-energy wasting is diagnosed if three characteristics are present (low serum levels of albumin, transthyretin, or cholesterol), reduced body mass (low or reduced body or fat mass or weight loss with reduced intake of protein and energy), and reduced muscle mass (muscle wasting or sarcopenia, reduced mid-arm muscle circumference). The kidney disease wasting is divided into two main categories of CKD- and AKI-associated protein-energy wasting. Measures of chronic inflammation or other developing tests can be useful clues for the existence of protein-energy wasting but do not define protein-energy wasting. Clinical staging and potential treatment strategies for protein-energy wasting are to be developed in the future.     

Cachexia/Protein energy wasting syndrome in CKD: Causation and treatment

Cachexia is a multifactorial syndrome defined by significant body weight loss, fat and muscle mass reduction, and increased protein catabolism. Protein energy wasting (PEW) is characterized as a syndrome of adverse changes in nutrition and body composition being highly prevalent in patients with CKD, especially in those undergoing dialysis, and it is associated with high morbidity and mortality in this population. Multiple mechanisms are involved in the genesis of these adverse nutritional changes in CKD patients. There is no obvious distinction between PEW and cachexia from a pathophysiologic standpoint and should be considered as part of the spectrum of the same nutritional disorder in CKD with similar management approaches for prevention and treatment based on current understanding. A plethora of factors can affect the nutritional status of CKD patients requiring a combination of therapeutic approaches to prevent or reverse protein and energy depletion. At present, there is no effective pharmacologic intervention that prevents or attenuates muscle atrophy in catabolic conditions like CKD. Prevention and treatment of uremic muscle wasting involve optimal nutritional support, correction of acidosis, and physical exercise. There has been emerging consistent evidence that active treatment, perhaps by combining nutritional interventions and resistance exercise, may be able to improve but not totally reverse or prevent the supervening muscle wasting and weakness. Active research into more direct pharmacological treatment based on basic mechanistic research is much needed for this unmet medical need in patients with CKD.     

Energy homeostasis and cachexia in chronic kidney disease

Loss of protein stores, presenting as clinical wasting, is reported to have a prevalence of 30–60% and is an important risk factor for mortality in chronic kidney disease (CKD) patients. There is debate as to whether the clinical wasting in CKD patients represents malnutrition or cachexia. Malnutrition results from inadequate intake of nutrients, despite a good appetite, and manifests as weight loss associated with adaptive metabolic responses such as decreased basic metabolic rate and preservation of lean body mass at the expense of fat mass. Furthermore, the abnormalities in malnutrition can usually be overcome simply by supplying more food or altering the composition of the diet. In contrast, cachexia is characterized by maladaptive responses such as anorexia, elevated basic metabolic rate, wasting of lean body tissue, and underutilization of fat tissue for energy. Diet supplementation and intradialytic parenteral nutrition have not been successful in reversing cachexia in CKD. The etiology of cachexia in CKD is complex and multifactorial. Two major factors causing muscle wasting in uremia are acidosis and decreased insulin responses. Inflammation secondary to cytokines may also play a significant role. The hypoalbuminemia of CKD patients is principally associated with inflammation and not changes in food intake. There is also recent evidence that hypothalamic neuropeptides may be important in the downstream signaling of cytokines in the pathogenesis of cachexia in CKD. Elevated circulating levels of cytokines, such as leptin, may be an important cause of uremia-associated cachexia via signaling through the central melanocortin system. Further research into the molecular pathways leading to cachexia may lead to novel therapeutic therapy for this devastating and potentially fatal complication of CKD.Supported by grants from the National Institute of Health R01 DK 50780 and K24 DK59574 to RHM.     

Mechanisms stimulating muscle wasting in chronic kidney disease: the roles of the ubiquitin-proteasome system and myostatin

Catabolic conditions including chronic kidney disease (CKD), cancer, and diabetes cause muscle atrophy. The loss of muscle mass worsens the burden of disease because it is associated with increased morbidity and mortality. To avoid these problems or to develop treatment strategies, the mechanisms leading to muscle wasting must be identified. Specific mechanisms uncovered in CKD generally occur in other catabolic conditions. These include stimulation of protein degradation in muscle arising from activation of caspase-3 and the ubiquitin-proteasome system (UPS). These proteases act in a coordinated fashion with caspase-3 initially cleaving the complex structure of proteins in muscle, yielding fragments that are substrates that are degraded by the UPS. Fortunately, the UPS exhibits remarkable specificity for proteins to be degraded because it is the major intracellular proteolytic system. Without a high level of specificity cellular functions would be disrupted. The specificity is accomplished by complex reactions that depend on recognition of a protein substrate by specific E3 ubiquitin ligases. In muscle, the specific ligases are Atrogin-1 and MuRF-1, and their expression has characteristics of a biomarker of accelerated muscle proteolysis. Specific complications of CKD (metabolic acidosis, insulin resistance, inflammation, and angiotensin II) activate caspase-3 and the UPS through mechanisms that include glucocorticoids and impaired insulin or IGF-1 signaling. Mediators activate myostatin, which functions as a negative growth factor in muscle. In models of cancer or CKD, strategies that block myostatin prevent muscle wasting, suggesting that therapies that block myostatin could prevent muscle wasting in catabolic conditions.     

Association of chronic kidney disease with muscle deficits in children

The effect of chronic kidney disease (CKD) on muscle mass in children, independent of poor growth and delayed maturation, is not well understood. We sought to characterize whole body and regional lean mass (LM) and fat mass (FM) in children and adolescents with CKD and to identify correlates of LM deficits in CKD. We estimated LM and FM from dual energy x-ray absorptiometry scans in 143 children with CKD and 958 controls at two pediatric centers. We expressed whole body, trunk, and leg values of LM and FM as Z-scores relative to height, sitting height, and leg length, respectively, using the controls as the reference. We used multivariable regression models to compare Z-scores in CKD and controls, adjusted for age and maturation, and to identify correlates of LM Z-scores in CKD. Greater CKD severity associated with greater leg LM deficits. Compared with controls, leg LM Z-scores were similar in CKD stages 2 to 3 (difference: 0.02 [95% CI: -0.20, 0.24]; P = 0.8), but were lower in CKD stages 4 to 5 (-0.41 [-0.66, -0.15]; P = 0.002) and dialysis (-1.03 [-1.33, -0.74]; P < 0.0001). Among CKD participants, growth hormone therapy associated with greater leg LM Z-score (0.58 [0.03, 1.13]; P = 0.04), adjusted for CKD severity. Serum albumin, bicarbonate, and markers of inflammation did not associate with LM Z-scores. CKD associated with greater trunk LM and FM, variable whole body LM, and normal leg FM, compared with controls. In conclusion, advanced CKD associates with significant deficits in leg lean mass, indicating skeletal muscle wasting. These data call for prospective studies of interventions to improve muscle mass among children with CKD.     

Patients receiving maintenance dialysis have more severe functionally significant skeletal muscle wasting than patients with dialysis-independent chronic kidney disease.

BACKGROUND: Chronic renal replacement therapy patients exhibit reduction in skeletal muscle function as a result of a combination of metabolic effects and muscle fibre size reduction. The aim of this study was to compare muscle mass with function in patients with chronic kidney disease (CKD) at stages 4 and 5 on haemodialysis (HD) and peritoneal dialysis (PD), and investigate the associations of muscle wasting in a cross-sectional cohort. METHODS: We studied 134 patients (60 HD, 28 PD and 46 CKD 4). The three groups were well matched for age, sex, diabetes and dialysis vintage. Cross-sectional area (CSA) of muscle and fat was measured from a standardized multi-slice CT scan of a 6 cm long section of thigh. CSA of soft tissue was taken from appropriate fat and muscle densities. Functional assessment was by the sit-to-stand 60 test, assessing both the number of sit-to-stands possible under controlled conditions in 60 s (STS 60), and the time taken to perform five sit-to-stand movements (STS 5). Data were collected on a wide range of potential determinants of muscle CSA. RESULTS: There were no significant differences in haemoglobin between males or females or between any of the groups studied. Serum phosphate and calcium-phosphate product were higher in HD patients as compared to CKD4 patients, but there were no differences in these variables when comparing PD patients with either CKD4 or HD patients. Muscle CSA correlated well with objective functional assessments in males (STS 60 R = 0.52, P<0.0001) and females (R = 0.41, P = 0.004), and STS performance was reduced in dialysed patients as compared with CKD 4. Univariate analysis demonstrated that muscle CSA was associated with serum albumin concentration (R = 0.49, P<0.0001), age (R = -0.35, P = 0.005) and C-reactive protein (R = -0.34, P = 0.004). Creatinine clearance, dialysis adequacy, dialysis vintage and time-averaged serum bicarbonate, calcium and phosphate concentrations were not correlated with muscle CSA. CONCLUSION: In conclusion, patients with dialysis-treated CKD 5 exhibited more functionally significant muscle wasting than patients with CKD 4. This may be amenable to modification with targeted exercise or amelioration of factors associated with observed differences in muscle mass.     

Inflammation and cachexia in chronic kidney disease

Chronic inflammation is associated with cachexia and increased mortality risk in patients with chronic kidney disease (CKD) and end-stage renal disease (ESRD). Inflammation suppresses appetite and causes the loss of protein stores. In CKD patients, increased serum levels of pro-inflammatory cytokines may be caused by reduced renal function, volume overload, oxidative or carbonyl stress, decreased levels of antioxidants, increased susceptibility to infection in uremia, and the presence of comorbid conditions. Cachexia is brought about by the synergistic combination of a dramatic decrease in appetite and an increase in the catabolism of fat and lean body mass. Pro-inflammatory cytokines act on the central nervous system to alter appetite and energy metabolism and to provide a signal—through the nuclear factor-κB and ATP-ubiquitin-dependent proteolytic pathways—that causes muscle wasting. Further research into the molecular pathways leading to inflammation and cachexia may lead to novel therapeutic therapies for this devastating and potentially fatal complication of chronic disease.     

Strategies for suppressing muscle atrophy in chronic kidney disease: mechanisms activating distinct proteolytic systems.

Loss of protein and lean body mass occurs commonly in patients with chronic kidney disease (CKD). CKD or conditions associated with CKD will stimulate muscle loss, but the cellular mechanisms by which these conditions cause muscle atrophy are largely undefined. In animal models of uremia and other catabolic conditions or in peritoneal dialysis patients, there is evidence that the ubiquitin-proteasome proteolytic system is activated to degrade actomyosin and myofibrillar proteins in muscle. Before the ubiquitin system can degrade muscle proteins, however, an initial cleavage of actomyosin and myofibrils must occur. Caspase-3 performs this initial cleavage of actomyosin and leaves a footprint of its activity, accumulation of a 14-kDa actin fragment in muscle. A critical step in stimulating the ubiquitin-proteasome system in muscle was recently discovered, the activation of a specific E3 ubiquitin-conjugating enzyme, atrogin-1. Both caspase-3 and the ubiquitin system, including atrogin-1, are activated when insulin signaling is impaired, and specifically when phosphatidylinositol 3 kinase activity is suppressed. Strategies that prevent a decrease in phosphatidylinositol 3 kinase activity or inhibit caspase-3 activity could lead to treatments that prevent muscle wasting in CKD patients.     

miR-486-5p的靶基因预测及其在胰腺腺癌中作用的生物信息学分析

背景与目的:胰腺癌是癌症相关性死亡的主要原因之一,是消化系统恶性程度最高的肿瘤,其主要的病理类型为胰腺腺癌(PAAD),预后较差。miR-486-5p在不同癌症中起重要的作用,但尚缺乏miR-486-5p在PAAD中的研究报告。本研究通过生物信息学方法探寻miR-486-5p的靶基因并分析靶基因在PAAD中的表达及意义。方法:使用PROGmiRV2数据库分析miR-486-5p与PAAD预后的相关性。综合运用多个数据平台来预测miR-486-5p的靶基因,并使用DAVID在线数据库对筛选出的靶基因进行基因本体论(GO)富集分析和京都基因与基因组百科(KEGG)信号通路分析,再以STRING数据库构建靶基因蛋白质-蛋白质相互作用(PPI)网络,并利用Cytoscape软件进行可视化编辑,筛选PPI网络中的核心基因,最后验证筛选出的核心基因,找出与PAAD预后相关的核心基因。结果:miR-486-5p低表达PAAD患者的总生存时间较miR-486-5p高表达患者明显缩短(P0.05)。得到至少被3个数据库预测到的靶基因数目共187个。GO分析显示,靶基因主要参与蛋白质稳定、蛋白质磷酸化、RNA聚合酶II启动子的转录正调节及凋亡过程的负调节等生物学过程;KEGG分析显示靶基因主要参与FOXO信号通路、p53信号通路、Ras信号通路及PI3K-Akt信号通路等。miR-486-5p潜在靶基因的蛋白网络分析发现,SIRT1、PTEN、SMAD2、CSNK2A1、SE RPINE1是PPI网络中关键靶基因;进一步通过GEPIA验证发现CSNK2A1、SERPINE1在PAAD组织中均明显上调(均P0.05),这些基因的高表达与PAAD患者的总体存活和无病生存相关(均P0.05),CSNK2A1和SERPINE1的高表达的PAAD患者有更差的预后。结论:miR-486-5p通过对靶向基因的调控,作用于PAAD患者体内多种信号通路的网络,参与PAAD的发生和发展,影响PAAD患者的预后。     

Review article: Biomarkers of clinical outcomes in advanced chronic kidney disease

Chronic kidney disease (CKD) is a complex condition, where the decrease in kidney function is accompanied by numerous metabolic changes affecting virtually all the organ systems of the human body. Many of the biomarkers characteristic of the individually affected organ systems have been associated with adverse outcomes including higher mortality in advanced CKD, whereas in persons without CKD these biomarkers may have no bearing on survival. It is believed that the high mortality seen in CKD is a result of several abnormalities conspiring to induce or aggravate a heightened degree of cardiovascular morbidity and predisposition to wasting syndrome. Not all the biomarkers may, however, be causally responsible for the adverse outcomes associated with them. We review various biomarkers of protein-energy wasting, inflammation, oxidative stress, potassium disarrays, acid-base disorders, bone and mineral disorders, glycemic status, and anemia. Although all of these biomarkers have shown associations with worsened outcomes in CKD, markers of protein-energy wasting, especially serum albumin, remain the strongest predictor of survival in CKD patients, especially those undergoing maintenance dialysis treatment. We also review the putative pathophysiologic mechanisms behind these associations, and present potential therapeutic interventions that could result in remedies to improve poor clinical outcomes in CKD, pending the results of current and future controlled trials.     

miR-150 Promotes Renal Fibrosis in Lupus Nephritis by Downregulating SOCS1

MicroRNAs (miRs) seem to mediate renal fibrosis in several renal diseases, with some miRs having profibrotic effects and others having opposing effects. Although differential expression of certain miRs has been described in lupus nephritis, it is unknown whether miRs contribute to fibrosis or could serve as biomarkers of specific histologic manifestations of lupus nephritis. Here, we compared miR expression in kidney biopsies from patients with lupus nephritis and identified miR-150 as the most differentially expressed miR in kidneys with high chronicity (chronicity index [CI] ≥4); miR-150 positively correlated with chronicity scores and the expression of profibrotic proteins. Overexpression of miR-150 significantly reduced expression of the antifibrotic protein suppressor of cytokine signaling 1 (SOCS1) and upregulated profibrotic proteins in both proximal tubular and mesangial cells. Directly targeting SOCS1 with a small interfering RNA produced similar results. Furthermore, TGF-β1 induced miR-150 expression, decreased SOCS1, and increased profibrotic proteins in proximal tubular cells and podocytes; a miR-150 inhibitor reversed these changes, suggesting that the profibrotic effects of TGF-β1 are, at least in part, mediated by miR-150. Consistent with these in vitro observations, biopsies with high miR-150 and high CI exhibited substantial expression of TGF-β1, reduced SOCS1, and an increase in profibrotic proteins. In summary, miR-150 is a promising quantitative renal biomarker of kidney injury in lupus nephritis. Our results suggest that miR-150 promotes renal fibrosis by increasing profibrotic molecules through downregulation of SOCS1.Despite improvements in renal outcomes in lupus nephritis (LN), a significant proportion of patients still progress to ESRD.^1,2 Fibrosis is the main pathologic feature in progressive LN and is captured by the chronicity index (CI), a semiquantitative score of chronic kidney injury, strongly associated with progression to ESRD.³MicroRNAs (miRs) are involved in the pathogenesis of CKD and renal fibrosis,^4–6 with some miRs showing profibrotic and others antifibrotic effects.⁷ miR-192, miR-141, miR-205, miR-377, and miR-21 are increased, whereas miR-29 and miR-200 are decreased in patients or animal models with renal fibrosis due to diabetic nephropathy (DN),^8–10 obstructive nephropathy,^11–13 IgA nephropathy,¹⁴ and hypertensive nephrosclerosis.¹⁵ Moreover, inhibition of miR-192 ameliorated renal fibrosis in diabetic mice.¹⁰ These findings suggest that miRs are important mediators in renal fibrosis and might be potential therapeutic targets to prevent ESRD.There are few studies of miRs in LN. One study identified 66 differentially expressed miRs in renal biopsies from LN patients compared with normal controls.¹⁶ Another study found that the intrarenal expression of miR-638, miR-198, and miR-146a was different between LN and normal controls.¹⁷ No study explored miRs as biomarkers of any specific histologic manifestation or their potential role in renal fibrosis in LN.In this study, we aimed to identify miR biomarkers reflective of CI in kidney biopsies from LN patients and to explore the potential pathogenic role of differentially expressed miRs in renal fibrosis. We show that miR-150 is significantly increased in renal biopsies with high CI and that increased miR-150 levels lead to increased production of profibrotic molecules through downregulation of suppressor of cytokine signaling 1 (SOCS1), a negative regulator of fibrosis.^18–20     

Protein-energy wasting and uremic failure to thrive in children with chronic kidney disease: They are not small adults

Protein-energy wasting (PEW), a condition of decreased body protein and fat mass, is highly prevalent in patients with chronic kidney disease (CKD) and a potent predictor of mortality in this population. In adults with CKD, PEW has typically been defined on the basis of (1) deranged biochemical parameters, (2) reduced body mass, (3) reduced muscle mass, and (4) decreased dietary protein intake. Emerging data suggest that PEW may also commonly afflict children with CKD and have a negative impact on growth and development (“uremic failure to thrive”), yet it remains comparatively understudied and less well characterized in these patients. Given the challenges of applying adult-defined PEW criteria to the pediatric population, the authors of a recent study entitled “Protein energy wasting in children with chronic kidney disease” [Abraham et al. (2014) Pediatr Nephrol 29:1231–1238] have sought to develop a scoring system and three alterative definitions for this condition using a combination of biochemical markers, clinical measurements, and subjective reporting in children in the CKiD cohort: (1) minimal PEW definition (≥2 adult-defined PEW criteria); (2) standard PEW definition (≥3 adult-defined PEW criteria); (3) modified PEW definition (≥3 adult-defined PEW criteria, plus short stature or poor growth). These authors observed that meeting the modified PEW definition was associated with a significantly increased risk of hospitalization in unadjusted analyses, i.e., a 2.2-fold higher risk, and trended towards increased risk in multivariable adjusted analyses, i.e., 2.0-fold higher risk. At the present time, future studies validating these findings and developing further refined definitions and/or scoring systems for the detection and management of PEW in children and uremic failure to thrive are urgently needed.     

CKD时高糖皮质激素通过激活Atrogin-1、MuRF-1引起骨骼肌萎缩

目的：瘦体质量丢失和肌肉消耗状态是慢性肾脏病（CKD）严重并发症,并与患者不良预后有关。本研究观察CKD模型小鼠骨骼肌合成和分解代谢,分析肌肉特异性E3连接酶肌萎缩蛋白Fbox-1（Atrogin-1）在肌萎缩中的作用,探讨CKD肌肉消耗的病理机制。方法：采用5/6肾切除制作小鼠CKD模型,以假手术组为对照组。同位素14＋C-苯丙氨酸掺入法检测肌肉蛋白合成,酪氨酸释放率分析检测肌肉分解代谢,组织病理学检测胫骨前肌横截面积并计算肌纤维面积分布图,Northern blot检测Atrogin-1和肌环指蛋白-1（MurF-1）mRNA水平,Western blot检测其蛋白表达及Akt/FOXO1信号通路,Elisa方法检测血清糖皮质激素水平。结果：造模1月后,CKD小鼠体重和骨骼肌重量明显下降,形态学表现为胫骨前肌横截面积减少,肌纤维面积分布图明显左移;蛋白质代谢方面显示肌肉蛋白分解增加明显,蛋白质合成代谢亦轻度下降,肌肉组织的Atrogin-1和MuRF-1mRNA表达明显上调,血清糖皮质激素水平较对照组升高13倍,CKD的代谢状态可导致骨骼肌组织Akt/FOXO1信号途径异常。结论：CKD时骨骼肌分解代谢旺盛,肌萎缩关键基因表达升高,致Akt/FOXO1信号途径异常,结果引起的肌肉萎缩,而糖皮质激素水平升高可能是原因之一。     

Apoptosis and myostatin mRNA are upregulated in the skeletal muscle of patients with chronic kidney disease

Apoptosis and myostatin are major mediators of muscle atrophy and might therefore be involved in the wasting of uremia. To examine whether they are expressed in the skeletal muscle of patients with chronic kidney disease (CKD), we measured muscle apoptosis and myostatin mRNA and their related intracellular signal pathways in rectus abdominis biopsies obtained from 22 consecutive patients with stage 5 CKD scheduled for peritoneal dialysis. Apoptotic loss of myonuclei, determined by anti-single-stranded DNA antibody and terminal deoxynucleotidyl transferase-mediated dUTP nick-end labeling assays, was significantly increased three to fivefold, respectively. Additionally, myostatin and interleukin (IL)-6 gene expressions were significantly upregulated, whereas insulin-like growth factor-I mRNA was significantly lower than in controls. Phosphorylated JNK (c-Jun amino-terminal kinase) and its downstream effector, phospho-c-Jun, were significantly upregulated, whereas phospho-Akt was markedly downregulated. Multivariate analysis models showed that phospho-Akt and IL-6 contributed individually and significantly to the prediction of apoptosis and myostatin gene expression, respectively. Thus, our study found activation of multiple pathways that promote muscle atrophy in the skeletal muscle of patients with CKD. These pathways appear to be associated with different intracellular signals, and are likely differently regulated in patients with CKD.