Spatial and temporal expression of acetylcholine receptor RNAs in innervated and denervated rat soleus muscle

In adult vertebrate skeletal muscle acetylcholine receptors are localized to the neuromuscular junction. Upon denervation, this distribution changes, with new receptors appearing in extrajunctional regions of the muscle fiber. The location of acetylcholine receptors in innervated or denervated muscle may result, in part, from the distribution of their RNAs. This was tested by assaying for receptor RNAs in junctional and extrajunctional regions of innervated and denervated rat soleus muscle using in situ hybridization and RNAase protection assays. These experiments showed alpha, beta, and delta subunit RNAs concentrated beneath the endplates of innervated muscle fibers. Following denervation, there was an unequal distribution of receptor RNAs along the muscle fiber, with highest levels occurring in extrajunctional regions near the endplate. These data are consistent with a nonuniform pattern of gene expression in adult skeletal muscle fibers.     

Dynamic and Coordinated Expression Changes of Rice Small RNAs in Response to Xanthomonas oryzae pv.oryzae

Endogenous small RNAs are newly identified players in plant immune responses, yet their roles in rice(Oryza sativa) responding to pathogens are still less understood, especially for pathogens that can cause severe yield losses. We examined the small RNA expression profiles of rice leaves at 2, 6, 12, and 24 hours post infection of Xanthomonas oryzae pv. oryzae(Xoo) virulent strain PXO99, the causal agent of rice bacterial blight disease. Dynamic expression changes of some mi RNAs and trans-acting si RNAs were identified, together with a few novel mi RNA targets, including an RLK gene targeted by osa-mi R159 a.1. Coordinated expression changes were observed among some small RNAs in response to Xoo infection, with small RNAs exhibiting the same expression pattern tended to regulate genes in the same or related signaling pathways, including auxin and GA signaling pathways, nutrition and defense-related pathways. These findings reveal the dynamic and complex roles of small RNAs in rice-Xoo interactions, and identify new targets for regulating plant responses to Xoo.     

Micro RNAs as mediators of cardiovascular disease: Targets to be manipulated

Cardiovascular disease has been the leading cause of death worldwide for the last few decades. Even with therapid progression of the biomedical field, conquering/managing cardiovascular disease is not an easy task because it is multifactorial disease. One of the key players of the development and progression of numerous diseases is micro RNA(mi RNA). These small, non-coding RNAs bind to target m RNAs to inhibit translations of and/or degrade the target m RNAs, thus acting as negative regulators of gene expressions. Accumulating evidence indicates that non-physiological expressions of mi RNAs contribute to both development and progression of cardiovascular diseases. Since even a single mi RNA can have multiple targets, dysregulation of mi RNAs can lead to catastrophic changes of proteins that may be important for maintaining physiologic conditions of cells, tissues, and organs. Current knowledge on the role of mi RNAs in cardiovascular disease is mostly based on the observational data such as microarray of mi RNAs in animal disease models, thus relatively lacking insight of how such dysregulation of mi RNAs is initiated and regulated. Consequently, future research should aim to elucidate the more comprehensive mechanisms of mi RNA dysregulation during pathogenesis of the cardiovascular system so that appropriate countermeasures to prevent/manage cardiovascular disease can be developed.     

The functional analysis of transiently upregulated miR-101 suggests a “braking” regulatory mechanism during myogenesis

Skeletal muscle differentiation is a highly coordinated process that involves many cellular signaling pathways and micro RNAs(mi RNAs). A group of muscle-specific mi RNAs has been reported to promote myogenesis by suppressing key signaling pathways for cell growth. However, the functional role and regulatory mechanism of most non-muscle-specific mi RNAs with stage-specific changes during differentiation are largely unclear. Here, we describe the functional characterization of mi R-101 a/b, a pair of non-muscle-specific mi RNAs that show the largest change among a group of transiently upregulated mi RNAs during myogenesis in C2 C12 cells. The overexpression of mi R-101 a/b inhibits myoblast differentiation by suppressing the p38/MAPK,Interferon Gamma, and Wnt pathways and enhancing the C/EBP pathway. Mef2 a, a key protein in the p38/MAPK pathway, was identified as a direct target of mi R-101 a/b. Interestingly, we found that the long non-coding RNA(lnc RNA) Malat1, which promotes muscle differentiation, interacts with mi R-101 a/b, and this interaction competes with Mef2 a m RNA to relieve the inhibition of the p38/MAPK pathway during myogenesis. These results uncovered a "braking" role in differentiation of transiently upregulated mi RNAs and provided new insights into the competing endogenous RNA(ce RNA) regulatory mechanism in myoblast differentiation and myogenesis.     

Nuclear receptors and inflammatory diseases

It is well known that the steroid hormone glucocorticoid and its nuclear receptor regulate the inflammatory process, a crucial component in the pathophysiological process related to human diseases that include atherosclerosis, obesity and type II diabetes, inflammatory bowel disease, Alzheimer's disease, multiple sclerosis, and liver tumors. Growing evidence demonstrates that orphan and adopted orphan nuclear receptors, such as peroxisome proliferator-activated receptors, liver x receptors, the farnesoid x receptor, NR4As, retinoid x receptors, and the pregnane x receptor, regulate the inflammatory and metabolic profiles in a ligand-dependent or -independent manner in human and animal models. This review summarizes the regulatory roles of these nuclear receptors in the inflammatory process and the underlying mechanisms.     

MicroRNAs transcriptionally regulate promoter activity in Arabidopsis thaliana

Micro RNAs(mi RNAs) are vital regulators that repress gene expression in the cytoplasm in two main ways: m RNA degradation and translational inhibition. Several animal studies have shown that mi RNAs also target promoters, thereby activating expression.Whether this mi RNA action also occurs in plants is unknown. In this study, we demonstrated that several mi RNAs regulate target promoters in Arabidopsis thaliana. For example, mi R5658 was predominantly present in the nucleus and activated the expression of AT3 G25290 directly by binding to its promoter. Our observations suggest that this mode of action may be a general feature of plant mi RNAs, and thus provide insight into the vital roles of plant mi RNAs in the nucleus.     

MicroRNAs Regulating Signaling Pathways:Potential Biomarkers in Systemic Sclerosis

Systemic sclerosis(SSc) is a multisystem fibrotic and autoimmune disease. Both genetic and epigenetic elements mediate SSc pathophysiology. This review summarizes the role of one epigenetic element, known as micro RNAs(mi RNAs), involved in different signaling pathways of SSc pathogenesis. The expression of key components in transforming growth factor-b(TGF-b)signaling pathway has been found to be regulated by mi RNAs both upstream and downstream of TGF-b. We are specifically interested in the pathway components upstream of TGF-b, while mi RNAs in other signaling pathways have not been extensively studied. The emerging role of mi RNAs in vasculopathy of SSc suggests a promising new direction for future investigation. Elucidation of the regulatory role of mi RNAs in the expression of signaling factors may facilitate the discovery of novel biomarkers in SSc and improve the understanding and treatment of this disease.     

The occurrence of "mixed" nuclear bag intrafusal fibers in the cat muscle spindle

A total of 147 muscle spindles was studied histochemically in serial transverse sections of 42 cat tenuissimus muscle specimens. Nuclear bag1, nuclear bag2 and nuclear chain intrafusal muscle fibers were distinguished by the differential staining resulting from the reactions for myosin adenosine 5'-triphosphatase and nicotinamide adenine dinucleotide tetrazolium reductase. The majority of intrafusal fibers were of the same histochemical type at both fiber poles. However, seven muscle spindles contained one nuclear bag fiber each that presented as a bag1 in one pole and as a bag2 in the other pole. These "mixed" nuclear bag fibers were found in spindles that also contained at least one bag1 and one bag2 fiber of equivalent histochemical presentation in both fiber poles. The "mixed" bag fibers displayed differences of apparent fiber diameter and relative polar length between the two fiber poles. The motor innervation pattern, as revealed by staining for cholinesterase, was also dissimilar between the two poles of "mixed" bag fibers. The study indicates that the spindle equatorial region may in some instances serve as a boundary between two morphologically and histochemically different poles of the same intrafusal fiber.     

AMPK-dependent and -independent coordination of mitochondrial function and muscle fiber type by FNIP1

Mitochondria are essential for maintaining skeletal muscle metabolic homeostasis during adaptive response to a myriad of physiologic or pathophysiological stresses. The mechanisms by which mitochondrial function and contractile fiber type are concordantly regulated to ensure muscle function remain poorly understood. Evidence is emerging that the Folliculin interacting protein 1 (Fnip1) is involved in skeletal muscle fiber type specification, function, and disease. In this study, Fnip1 was specifically expressed in skeletal muscle in Fnip1-transgenic (Fnip1^Tg) mice. Fnip1^Tg mice were crossed with Fnip1-knockout (Fnip1^KO) mice to generate Fnip1^TgKO mice expressing Fnip1 only in skeletal muscle but not in other tissues. Our results indicate that, in addition to the known role in type I fiber program, FNIP1 exerts control upon muscle mitochondrial oxidative program through AMPK signaling. Indeed, basal levels of FNIP1 are sufficient to inhibit AMPK but not mTORC1 activity in skeletal muscle cells. Gain-of-function and loss-of-function strategies in mice, together with assessment of primary muscle cells, demonstrated that skeletal muscle mitochondrial program is suppressed via the inhibitory actions of FNIP1 on AMPK. Surprisingly, the FNIP1 actions on type I fiber program is independent of AMPK and its downstream PGC-1α. These studies provide a vital framework for understanding the intrinsic role of FNIP1 as a crucial factor in the concerted regulation of mitochondrial function and muscle fiber type that determine muscle fitness.     

Muscle LIM protein plays both structural and functional roles in skeletal muscle

Muscle LIM protein (MLP) has been suggested to be an important mediator of mechanical stress in cardiac tissue, but the role that it plays in skeletal muscle remains unclear. Previous studies have shown that it is dramatically upregulated in fast-to-slow fiber-type transformation and also after eccentric contraction (EC)-induced muscle injury. The functional consequences of this upregulation, if any, are unclear. In the present study, we have examined the skeletal muscle phenotype of MLP-knockout (MLPKO) mice in terms of their response to EC-induced muscle injuries. The data suggest that while the MLPKO mice recover completely after EC-induced injury, their torque production lags behind that of heterozygous littermates in the early stages of the recovery process. This lag is accompanied by decreased expression of the muscle regulatory factor MyoD, suggesting that MLP may influence gene expression. In addition, there is evidence of type I fiber atrophy and a shorter resting sarcomere length in the MLPKO mice, but no significant differences in fiber type distribution. In summary, MLP appears to play a subtle role in the maintenance of normal muscle characteristics and in the early events of the recovery process of skeletal muscle to injury, serving both structural and gene-regulatory roles. eccentric contractions; passive tension     

The role of circulating miRNAs in multiple myeloma

Multiple myeloma(MM) is a common malignant hematological disease. Dysregulation of micro RNAs(mi RNAs) in MM cells and bone marrow microenviroment has important impacts on the initiation and progression of MM and drug resistance in MM cells. Recently, it was reported that MM patient serum and plasma contained sufficiently stable mi RNA signatures, and circulating mi RNAs could be identified and measured accurately from body fluid. Compared to conventional diagnostic parameters, the circulating mi RNA profile is appropriate for the diagnosis of MM and estimates patient progression and therapeutic outcome with higher specificity and sensitivity. In this review, we mainly focus on the potential of circulating mi RNAs as diagnostic, prognostic, and predictive biomarkers for MM and summarize the general strategies and methodologies for identification and measurement of circulating mi RNAs in various cancers. Furthermore, we discuss the correlation between circulating mi RNAs and the cytogenetic abnormalities and biochemical parameters assessed in multiple myeloma.     

Receptors and ionic transporters in nuclear membranes: new targets for therapeutical pharmacological interventions

Work from our group and other laboratories showed that the nucleus could be considered as a cell within a cell. This is based on growing evidence of the presence and role of nuclear membrane G-protein coupled receptors and ionic transporters in the nuclear membranes of many cell types, including vascular endothelial cells, endocardial endothelial cells, vascular smooth muscle cells, cardiomyocytes, and hepatocytes. The nuclear membrane receptors were found to modulate the functioning of ionic transporters at the nuclear level, and thus contribute to regulation of nuclear ionic homeostasis. Nuclear membranes of the mentioned types of cells possess the same ionic transporters; however, the type of receptors is cell-type dependent. Regulation of cytosolic and nuclear ionic homeostasis was found to be dependent upon a tight crosstalk between receptors and ionic transporters of the plasma membranes and those of the nuclear membrane. This crosstalk seems to be the basis for excitation-contraction coupling, excitation-secretion coupling, and excitation - gene expression coupling. Further advancement in this field will certainly shed light on the role of nuclear membrane receptors and transporters in health and disease. This will in turn enable the successful design of a new class of drugs that specifically target such highly vital nuclear receptors and ionic transporters.     

PGC-1α及其在肌纤维类型转化中的作用

PGC-1α属于与能量代谢关系最密切的PGC-1转录辅助活化因子家族成员,最早在酵母双杂交体系中作为调控脂肪细胞分化的核受体PPARγ的辅激活因子被发现。PGC-1α在肌纤维类型转化中发挥重要作用,肌纤维类型及其组成是肌肉生长和肉品质形成的生物学基础,直接影响肌肉色泽、嫩度内脂肪含量。因此,研究PGC-1α在肌纤维类型转化中的调控作用,将为改善肉品质提供重要的理论依据。主要从PGC-1α的结构特点、作用特征及其在陆上动物和鱼类肌纤维类型转化中的最新进展等方面进行综述。