1,721,017 research outputs found
The Roles of miR-25 and its Targeted Genes in Development of Human Cancer
No full textmicroRNAs (miRNAs) are small noncoding RNAs able to suppress gene expression by targeting messenger RNAs for translational repression or, at lesser extent, degradation. miRNAs are widely expressed in tissues and organs and play fundamental roles in controlling cell proliferation, apoptosis, differentiation, cell migration, autophagy and metabolism. Uncontrolled expression of miRNAs has been associated with cancer progression, and miRNA up- or down-regulation has been linked to oncogenic and tumor-suppressive roles in cancers such as breast cancer, colorectal cancer, lung cancer, gastric cancer and glioblastoma. Altered expression of the miRNA mir-25 has been reported in many human malignant tumors, participating in various cellular processes accordingly with its broad range of potential mRNAs target. In the present review, we briefly discuss the mechanisms underlying miR-25-mediated tumorigenesis in six different human cancers and its possible future as a potential diagnostic and prognostic parameter as well as therapeutic target in clinical applications
Non-protein coding RNA biomarkers and differential expression in cancers: a review
Full text linkAbstract Background In these years a huge number of human transcripts has been found that do not code for proteins, named non-protein coding RNAs. In most cases, small (miRNAs, snoRNAs) and long RNAs (antisense RNA, dsRNA, and long RNA species) have many roles, functioning as regulators of other mRNAs, at transcriptional and post-transcriptional level, and controlling protein ubiquitination and degradation. Various species of npcRNAs have been found differentially expressed in different types of cancer. This review discusses the published data and new results on the expression of a subset of npcRNAs. Conclusion These results underscore the complexity of the RNA world and provide further evidence on the involvement of functional RNAs in cancer cell growth control.</p
Roles of microRNAs in HIV-1 Replication and Latency
No full textMicroRNAs (miRNAs) are non-coding RNA molecules, with sequence length of 19-24 nucleotides, which can induce mRNA degradation and regulate protein translation repression. Recently plenty of reports showed that miRNAs increase or decrease in the serum (circulating miRNAs) and in PBMC of Human immunodeficiency virus type 1 (HIV-1) infected individuals to affect the replication of HIV-1 through regulating HIV-1 proteins or HIV-1 replication related host factors. Many of miRNAs can suppress HIV-1 replication, but do not affect the integrated viral DNA. Low or no viral protein expression could result in a block of virus and its replication to induce HIV-1 latency, which is the great obstacle of the cure of HIV-1 infection. In the HIV-1 latency reservoir, the integrated provirus can reactivate under appropriate stimulus, which results in HIV-1 reproduction. Factors imply that cellular miRNAs may promote the establishment of HIV-1 latency. Further studies on the mechanisms of miRNAs affecting viral protein expression will provide new approaches to clear the viral reservoir
FKBP51 and the NF-kappaB regulatory pathway in cancer
No full textConstitutive activation of NF-κB occurs in a significant percentage of human cancers. Genetic abnormalities of tumors often enhance normal NF-κB signaling. Chronic inflammation is also associated with constitutive NF-κB activation and increases the risk of cancer. Aberrant NF-κB activation favors cellular transformation, sustains cancer survival, and contributes to tumor invasion. Strategies to inhibit NF-κB represent a promising therapeutic option against cancer. In the last decade, several studies point to the large immunophilin FKBP51 as an important element for the control of NF-κB activation in human neoplasia. This article is an overview of the causes of aberrant NF-κB regulation in cancer and highlights recent papers that implicate FKBP51 in such deregulation
Microtubule-dependent Organization of Vaccinia Virus Core-derivd Early mRNAs into Distinct Cytoplasmic Structures.
Full text linkVaccinia virus (vv) early transcription can be reconstituted in vitro from purified virions; in this assay mRNAs are made inside the viral core and subsequently extruded. Although the in vitro process has been extensively characterized, relatively little is known about vv early transcription in vivo. In the present study the fate of vv early mRNAs in infected HeLa cells was followed by BrUTP transfection and confocal and electron microscopy. The extruded vv early mRNAs were found to be organized into unique granular cytoplasmic structures that reached a size up to 1 μm. By EM these structures appeared as amorphous electron-dense cytoplasmic aggregates that were surrounded by ribosomes. Confocal images showed that the RNA structures were located some distance away from intracellular cores and that both structures appeared to be aligned on microtubules (MTs), implying that MT tracks connected mRNAs and cores. Accordingly, intact MTs were found to be required for the typical punctate organization of viral mRNAs. Biochemical evidence supported the notion that vv mRNAs were MT associated and that MT depletion severely affected viral (but not cellular) mRNA synthesis and stability. By confocal microscopy the viral mRNA structures appeared to be surrounded by molecules of the translation machinery, showing that they were active in protein synthesis. Finally, our data suggest a role for a MT and RNA-binding viral protein of 25 kDa (gene L4R), in mRNA targeting away from intracellular cores to their sites of cytoplasmic accumulation
Computational analysis and in vivo validation of a microRNA encoded by the IBTK gene, a regulator of B-lymphocytes differentiation and survival.
No full textOvarian Aging: Role of Pituitary-Ovarian Axis Hormones and ncRNAs in Regulating Ovarian Mitochondrial Activity
No full text: The number of mitochondria in the oocyte along with their functions (e.g., energy production, scavenger activity) decline with age progression. Such multifaceted functions support several processes during oocyte maturation, ranging from energy supply to synthesis of the steroid hormones. Hence, it is hardly surprising that their impairment has been reported in both physiological and premature ovarian aging, wherein they are crucial players in the apoptotic processes that arise in aged ovaries. In any form, ovarian aging implies the progressive damage of the mitochondrial structure and activities as regards to ovarian germ and somatic cells. The imbalance in the circulating hormones and peptides (e.g., gonadotropins, estrogens, AMH, activins, and inhibins), active along the pituitary-ovarian axis, represents the biochemical sign of ovarian aging. Despite the progress accomplished in determining the key role of the mitochondria in preserving ovarian follicular number and health, their modulation by the hormonal signalling pathways involved in ovarian aging has been poorly and randomly explored. Yet characterizing this mechanism is pivotal to molecularly define the implication of mitochondrial dysfunction in physiological and premature ovarian aging, respectively. However, it is fairly difficult considering that the pathways associated with ovarian aging might affect mitochondria directly or by altering the activity, stability and localization of proteins controlling mitochondrial dynamics and functions, either unbalancing other cellular mediators, released by the mitochondria, such as non-coding RNAs (ncRNAs). We will focus on the mitochondrial ncRNAs (i.e., mitomiRs and mtlncRNAs), that retranslocate from the mitochondria to the nucleus, as active players in aging and describe their role in the nuclear-mitochondrial crosstalk and its modulation by the pituitary-ovarian hormone dependent pathways. In this review, we will illustrate mitochondria as targets of the signaling pathways dependent on hormones and peptides active along the pituitary/ovarian axis and as transducers, with a particular focus on the molecules retrieved in the mitochondria, mainly ncRNAs. Given their regulatory function in cellular activities we propose them as potential diagnostic markers and/or therapeutic targets
Potent and stable attenuation of live-HIV-1 by gain of a proteolysis-resistant inhibitor of NF-kappaB (IkappaB-alphaS32/36A) and the implications for vaccine development.
No full textLive-attenuated human immunodeficiency viruses (HIVs) are candidates for Acquired Immunodeficiency Syndrome (AIDS) vaccine. Based on the simian immunodeficiency virus (SIV) model for AIDS, loss-of-function (e.g. deletion of accessory genes such as nef) has been forwarded as a primary approach for creating enfeebled, but replication-competent, HIV-1/SIV. Regrettably, recent evidence suggests that loss-of-function alone is not always sufficient to prevent the emergence of virulent mutants. New strategies that attenuate via mechanisms distinct from loss-of-function are needed for enhancing the safety phenotype of viral genome. Here, we propose gain-of-function to be used simultaneously with loss-of-function as a novel approach for attenuating HIV- 1. We have constructed an HIV-1 genome carrying the cDNA of a proteolysis- resistant nuclear factor-κB inhibitor (IκB-αS32/36A) in the nef region. HIV-1 expressing IκB-αS32/36A down-regulates viral expression and is highly attenuated in both Jurkat and peripheral blood mononuclear cells. We provide formal proof that the phenotypic and attenuating characteristics of IκBαS32/36A permit its stable maintenance in a live, replicating HIV-1 despite 180 days of forced ex vivo passaging in tissue culture. As compared with other open-reading frames embedded into HIV/SIV genome, this degree of stability is unprecedented. Thus, IκB-αS32/36A offers proof-of-principle that artifactually gained functions, when used to attenuate the replication of live HIV-1, can be stable. These findings illustrate gain-of-function as a feasible strategy for developing safer live-attenuated HIVs to be tested as candidates for AIDS vaccine
Hiv-1 Tat induces the expression of the inteleukin-6 (IL6) gene by binding to the IL6 leader RNA and by interacting with CAAT enhancer-binding protein β (NF-IL6) trascription factors.
No full textOn the relationship between vaccinia virus intracellular cores, early mRNAs and DNA replication sites.
No full textVirus assembly, a late event in the life cycle of vaccinia virus (VV), is preceded by a number of steps that all occur in the cytoplasm of the infected host cell: virion entry, delivery of the viral core into the cytoplasm, and transcription from these cores of early mRNAs, followed by the process of DNA replication. In the present study the quantitative and structural relationships between these distinct steps of VV morphogenesis were investigated. We show that viral RNA and DNA synthesis increases linearly with increasing amounts of incoming cores. Moreover, at multiplicities of infection that result in 10 to 40 cores per cell, an approximately 1:1 ratio between cores and sites of DNA replication exists, suggesting that each core is infectious. We have shown previously that W early mRNAs collect in distinct granular structures that recruit components of the host cell translation machinery. Strikingly, these structures appeared to form some distance away from intracellular cores (M. Mallardo, S. Schleich, and J. Krijnse Locker, Mol. Biol. Cell 12:3875-3891, 2001). In the present study the intracellular locations of the sites of early mRNA accumulation and those of the subsequent process of DNA replication were compared. We show that these are distinct structures that have different intracellular locations. Finally, we study the fate of the parental DNA after core uncoating. By electron microscopy, cores were found close to membranes of the endoplasmic reticulum (ER) and the parental DNA, once it had left the core, appeared to associate preferentially with the cytosolic side of those membranes. Since we have previously shown that the process of DNA replication occurs in an ER-enclosed cytosolic "subcompartment" (N. Tolonen, L. Doglio, S. Schleich, and J. Krijnse Locker, Mol. Biol. Cell 12:2031-2046, 2001), the present data suggest that the parental DNA is released into the cytosol and associates with the same membranes where DNA replication is subsequently initiated. The combined data are discussed with respect to the cytosolic organization of VV morphogenesis
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