MiR-155

Last updated
pre-mir-155
MiR-155 secondary structure.png
pre-mir-155 secondary structure and sequence conservation.ard
Identifiers
SymbolmiR-155
Rfam RF00731
miRBase family MIPF0000157
Other data
RNA type microRNA
Domain(s) Eukaryota;
PDB structures PDBe
MIR155
Identifiers
Aliases MIR155 , MIRN155, miRNA155, mir-155, miR-155, microRNA 155
External IDs OMIM: 609337; GeneCards: MIR155; OMA:MIR155 - orthologs
Orthologs
SpeciesHumanMouse
Entrez
Ensembl
UniProt
RefSeq (mRNA)

n/a

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RefSeq (protein)

n/a

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Location (UCSC) Chr 21: 25.57 – 25.57 Mb n/a
PubMed search [2] n/a
Wikidata
View/Edit Human

MiR-155 is a microRNA that in humans is encoded by the MIR155 host gene or MIR155HG. [3] MiR-155 plays a role in various physiological and pathological processes. [4] [5] [6] [7] [8] [9] Exogenous molecular control in vivo of miR-155 expression may inhibit malignant growth, [10] [11] viral infections, [12] and enhance the progression of cardiovascular diseases. [13]

Contents

Discovery

The MIR155HG was initially identified as a gene that was transcriptionally activated by promoter insertion at a common retroviral integration site in B-cell lymphomas and was formerly called BIC (B-cell Integration Cluster). The MIR155HG is transcribed by RNA polymerase II and the resulting ~1,500 nucleotide RNA is capped and polyadenylated. The 23 nucleotide single-stranded miR-155, which is harbored in exon 3, is subsequently processed from the parent RNA molecule. [14]

Figure 1. Schematic representation of the MIR155HG (accession # NC_000021). This gene spans 13024 bp, is composed of three exons, and encodes a 1500 bp non-coding primary-miRNA (pri-miRNA) (accession # NR_001458). The location of the pre-mir-155 is denoted by the orange box. Mir155 gene.png
Figure 1. Schematic representation of the MIR155HG (accession # NC_000021). This gene spans 13024 bp, is composed of three exons, and encodes a 1500 bp non-coding primary-miRNA (pri-miRNA) (accession # NR_001458). The location of the pre-mir-155 is denoted by the orange box.

Biogenesis

The MIR155HG RNA transcript does not contain a long open reading frame (ORF), however, it does include an imperfectly base-paired stem loop that is conserved across species. [15] This non-coding RNA (ncRNA) is now defined as a primary-miRNA (pri-miRNA). [15] Once miR-155 pri-miRNA is transcribed, this transcript is cleaved by the nuclear microprocessor complex, of which the core components are the RNase III type endonuclease Drosha and the DiGeorge critical region 8 (DGCR8) protein, [16] [17] to produce a 65 nucleotide stem-loop precursor miRNA (pre-mir-155) (see Figure 2).

Figure 2. The sequence of the pre-mir-155 stem loop that is matured from the pri-miRNA transcript. The mature miR-155 (miR-155-5p) sequence is shown in green and mature miR-155* (miR-155-3p) sequence is shown in red. Pre-mir-155.png
Figure 2. The sequence of the pre-mir-155 stem loop that is matured from the pri-miRNA transcript. The mature miR-155 (miR-155-5p) sequence is shown in green and mature miR-155* (miR-155-3p) sequence is shown in red.

Following export from the nucleus by exportin-5, pre-mir-155 molecules are cleaved near the terminal loop by Dicer resulting in RNA duplexes of ~22nucleotides. [16] [17] Following Dicer cleavage, an Argonaute (Ago) protein binds to the short RNA duplexes, forming the core of a multi-subunit complex called the RNA-induced silencing complex (RISC). [18] In a manner similar to siRNA duplexes, one of the two strands, the "passenger miRNA" (miR-155*), is released and degraded while the other strand, designated the "guide strand" or "mature miRNA" (miR-155), is retained within the RISC. [18]

Recent data suggest that both arms of the pre-miRNA hairpin can give rise to mature miRNAs. [19] [20] Due to the increasing number of examples where two functional mature miRNAs are processed from opposite arms of the same pre-miRNA, pre-mir-155 products are now denoted with the suffix -5p (from the 5′ arm) (e.g. miR-155-5p) and -3p (from the 3′ arm) (e.g. miR-155-3p) following their name (see Figure 3). [21]

Figure 3. The mature miR-155 (miR-155-5p) sequence is shown in green and mature miR-155* (miR-155-3p) sequence is shown in red. Mature mir-155-5p and -3p.png
Figure 3. The mature miR-155 (miR-155-5p) sequence is shown in green and mature miR-155* (miR-155-3p) sequence is shown in red.

Once miR-155-5p/-3p is assembled into the RISC, these molecules subsequently recognize their target messenger RNA (mRNA) by base pairing interactions between nucleotides 2 and 8 of miR-155-5p/-3p (the seed region) and complementary nucleotides predominantly in the 3′-untranslated region (3′-UTR) of mRNAs (see Figure 4 and 5 below). [22] Finally, with the miR-155-5p/-3p acting as an adaptor for the RISC, complex-bound mRNAs are subjected to translational repression (i.e. inhibition of translation initiation) and/or degradation following deadenylation. [18]

Evolutionary conservation

Early phylogenetic analyses demonstrated that the sequence of pre-mir-155 and miR-155-5p was conserved between human, mouse, and chicken. [15] Recent annotated sequencing data found that 22 different organisms including, mammals, amphibians, birds, reptiles, sea squirts, and sea lampreys, express a conserved miR-155-5p. Currently much less sequence data is available regarding miR-155-3p, therefore, it is not clear how conserved this miRNA is across species.

Tissue distribution

Northern blot analysis found that miR-155 pri-miRNA was abundantly expressed in the human spleen and thymus and detectable in the liver, lung, and kidney. [15] Sequence analysis of small RNA clone libraries comparing miRNA expression to all other organ systems examined established that miR-155-5p was one of five miRNAs (i.e. miR-142, miR-144, miR-150, miR-155, and miR-223) that was specific for hematopoietic cells including B-cells, T-cells, monocytes and granulocytes. [23] Together these results suggest that miR-155-5p is expressed in a number of tissues and cell types and, therefore, may play a critical role in a wide variety of biological processes, including hematopoiesis [4] [5] [6]

Although very few studies have investigated the expression levels of miR-155-3p, Landgraf et al. [23] established that expression levels of this miRNA was very low in hematopoietic cells. Additionally, PCR analyses found that while miR-155-3p was detectable in a number of human tissues the expression levels of this miRNA were 20–200 fold less when compared to miR-155-5p levels. [24] Even though the function of miR-155-3p has been largely ignored, several studies now suggest that, in some cases (astrocytes and plasmacytoid dendritic cells), both miR-155-5p and -3p can be functionally matured from pre-mir-155. [25] [26]

Targets

Bioinformatic analysis using TargetScan 6.2 (release date June, 2012) revealed at least 4,174 putative human miR-155-5p mRNA targets exist, with a total of 918 conserved sites (i.e. between mouse and human) and 4,249 poorly conserved sites (i.e. human only). [22] [27] Although the TargetScan 6.2 algorithm cannot be utilized to determine the miR-155-3p putative targets, one would speculate that this miRNA may also potentially regulate the expression of thousands of mRNA targets.

A comprehensive list of miR-155-5p/mRNA targets that were experimentally authenticated by both the demonstration of endogenous transcript regulation by miR-155-5p and validation of the miR-155-5p seed sequence through a reporter assay was recently assembled. [28] This list included 140 genes and included regulatory proteins for myelopoiesis and leukemogenesis (e.g. SHIP-1, AICDA, ETS1, JARID2, SPI1, etc.), inflammation (e.g. BACH1, FADD, IKBKE, INPP5D, MYD88, RIPK1, SPI1, SOCS, etc.) and known tumor suppressors (e.g. CEBPβ, IL17RB, PCCD4, TCF12, ZNF652, etc.). [28] The validated miR-155-5p binding site harbored in the SPI1 mRNA [29] and the validated miR-155-3p binding site harbored in the IRAK3 mRNA [26] are shown in Figures 4 and 5 respectively.

Figure 4. Complementary base-pairing between miR-155-5p and the human SPI1 (spleen focus forming virus proviral integration oncogene)(also known as PU.1) mRNA. The miR-155-5p binding site is located 46-53 base pairs downstream from the SPI1 mRNA stop codon. The requisite "seed sequence" base-pairing is denoted by the bold dashes. MiR-155-5p complementry binding with SPI1.png
Figure 4. Complementary base-pairing between miR-155-5p and the human SPI1 (spleen focus forming virus proviral integration oncogene)(also known as PU.1) mRNA. The miR-155-5p binding site is located 46–53 base pairs downstream from the SPI1 mRNA stop codon. The requisite "seed sequence" base-pairing is denoted by the bold dashes.
Figure 5. Complementary base-pairing between miR-155-3p and the human IRAK3 (interleukin-1 receptor-associated kinase 3) mRNA. The miR-155-3p binding site is located 424-430 base pairs downstream from the IRAK3 mRNA stop codon. The requisite "seed sequence" base-pairing is denoted by the bold dashes. IRAK3 and miR1553p.png
Figure 5. Complementary base-pairing between miR-155-3p and the human IRAK3 (interleukin-1 receptor-associated kinase 3) mRNA. The miR-155-3p binding site is located 424–430 base pairs downstream from the IRAK3 mRNA stop codon. The requisite "seed sequence" base-pairing is denoted by the bold dashes.

Physiological roles

Hematopoiesis

Hematopoiesis is defined as the formation and development of blood cells, all of which are derived from hematopoietic stem-progenitor cells (HSPCs). [30] HSPCs are primitive cells capable of self-renewal and initially differentiate into common myeloid progenitor (CMP) or common lymphoid progenitor (CLP) cells. [30] CMPs represent the cellular population that has become myeloid lineage and it is the point that myelopoiesis begins. [30] During myelopoiesis further cellular differentiation takes place including thrombopoiesis, erythropoiesis, granulopoiesis, and monocytopoiesis. [30] CLPs subsequently differentiate into B-cells and T-cells in a process designated lymphopoiesis. [30] Given that miR-155-5p is expressed in hematopoietic cells [23] it was hypothesized that this miRNA plays a critical role in these cellular differentiation processes. In support of this premise, miR-155-5p was found to be expressed in CD34(+) human HSPCs, and it was speculated that this miRNA may hold these cells at an early stem-progenitor stage, inhibiting their differentiation into a more mature cell (i.e. megakaryocytic/erythroid/granulocytic/monocytic/B-lymphoid/T-lymphoid). [31] This hypothesis was substantiated when pre-mir-155 transduced HSPCs generated 5-fold fewer myeloid and 3-fold fewer erythroid colonies. [31] Additionally, Hu et al. [32] demonstrated that the homeobox protein, HOXA9, regulated MIR155HG expression in myeloid cells and that this miRNA played a functional role in hematopoiesis. These investigators found that forced expression of miR-155-5p in bone marrow cells resulted in a ~50% decrease in SPI1 (i.e. PU.1), [32] a transcription factor and a regulator of myelopoiesis, [33] and a validated target of this miRNA. [29] It was also established that in vitro differentiation of purified human erythroid progenitor cells resulted in a progressive decrease of miR-155-5p expression in mature red cells. [34] Additionally, mice deficient in pre-mir-155 showed clear defects in lymphocyte development and generation of B- and T-cell responses in vivo. [29] [35] [36] Finally, it was established that regulatory T-cell (Tregs) development required miR-155-5p and this miRNA was shown to play a role in Treg homeostasis and overall survival by directly targeting SOCS1, a negative regulator for IL-2 signaling. [37] [38] Taken together, these results strongly suggest that miR-155-5p is an essential molecule in the control of several aspects of hematopoiesis including myelopoiesis, erythropoiesis, and lymphopoiesis.

Immune system

The innate immune system constitutes the first line of defense against invading pathogens and is regarded as the major initiator of inflammatory responses. [39] Its cellular component involves primarily monocyte/macrophages, granulocytes, and dendritic cells (DCs), which are activated upon sensing of conserved pathogen structures (PAMPs) by pattern recognition receptors such as Toll-like receptors ((TLRs)). [40] MIR155HG (i.e. miR-155-5p) expression is greatly enhanced by TLR agonist stimulation of macrophages and dendritic cells. [41] [42] [43] [44] [45] [46] Since microbial lipopolysaccharide (an agonist of TLR4) activates a chain of events that lead to the stimulation of the NF-κB and AP-1 transcription factors, [40] it was hypothesized that endotoxin activation of MIR155HG may be mediated by those transcription factors. [41] Indeed, MIR155HG expression was found to be activated in LPS treated murine macrophage cells (i.e. Raw264.7) by an NF-κB-mediated mechanism. [42] Furthermore, H. pylori infection of primary murine bone marrow-derived macrophages resulted in a NF-κB dependent up-regulation of MIR155HG. [47] In the context of viral infection vesicular stomatitis virus (VSV) challenge of murine peritoneal macrophages was reported to result in miR-155-5p over-expression via a retinoic acid-inducible gene I/JNK/NF-κB–dependent pathway. [48] Support for a role of AP-1 in MIR155HG activation comes from studies using stimuli relevant to viral infection such as TLR3 ligand poly(I:C) or interferon beta (IFN-β). [43] Downstream of those stimuli AP-1 seems to play a major role in MIR155HG activation. [43] [49] [50] [51]

Upon its initiation via activation of e.g. TLRs by pathogen stimuli miR-155-5p functions as a post-transcriptional regulator of innate immune signaling pathways. Importantly, miR-155-5p displays a similar responsiveness to pathogen stimuli (e.g. TLR4 agonist LPS) as major pro-inflammatory marker mRNAs. [52] Once activated, miR-155-5p suppresses negative regulators of inflammation. These include inositol polyphosphate-5-phosphatase (INPP5D also denoted SHIP1) and suppressor of cytokine signaling 1 (SOCS1), suppression of which promotes cell survival, growth, migration, and anti-pathogen responses. [48] [53] [54] [55] Besides supporting the activation of defense pathways miR-155-5p may also limit the strength of the resulting NF-κB dependent inflammatory response, [52] suggesting varying functions of miR-155 at different stages of inflammation.

Taken together, these observations imply that the activation of the MIR155HG may be context-dependent given that both AP-1- and NF-κB-mediated mechanisms regulate the expression of this gene. These studies also suggest that a broad range of viral and bacterial inflammatory mediators can stimulate the expression of miR-155-5p and indicate that there is an intimate relationship between inflammation, innate immunity and MIR155HG expression.

Activity and phenotypes

There is evidence that miR-155 participates in cascades associated with cardiovascular diseases and hypertension, and was also found to be implicated in immunity, genomic instability, cell differentiation, inflammation, virus associated infections, cancer, and diabetes mellitus. [56]

Protective roles of miR-155 may arise in response to its action on silencing genes thereby regulating their expression time, mutations in miR-155 target site deny it the optimal access necessary to bring about gene silencing, leading to over abundance of delinquent activities that may go malignant, for example, miR-155 role as a protective agent against predisposition to B Cell associated malignancies is emphasized by maintaining the balance of Activation-Induced Cytidine Deaminase (AID) enzyme. MiR-155 mediates regulation of AID abundance and expression time upon immunological cues however, mutations in the target on AID mRNA result in its unresponsiveness to miR-155 silencing and lead to unbridled expression of its protein causing wild immature B-lymphocyte surges and AID-mediated chromosomal translocations. [5] [6]

Clinical significance

Cardiovascular

Transfection of miR-155 into human primary lung fibroblasts reduces the endogenous expression of the angiotensin II receptor AT1R protein. Furthermore, AT1R mediates angiotensin II-related elevation in blood pressure and contributes to the pathogenesis of heart failure. Defective miR-155 function could be implicated in hypertension and cardiovascular diseases if the cis-regulatory site on 3` UTR of AT1R (miR-155 target site) was affected due to a SNP polymorphism in AT1R itself. This mutation is disruptive of miR-155 targeting and thus preventive of AT1R expression down-regulation. [5] In low blood pressure over-expression of miR-155 correlates with the impairment of AT1R activity. [4]

Immunity

miR-155 is involved in immunity by playing key roles in modulating humoral and innate cell-mediated immune responses, for example, In miR-155 deficient mice, immunological-memory is impaired; making it fall prey to repetitive bouts of invasions by the same pathogen (Rodriguez et al. 2007), maturation and specificity of miR-155-deficient B-lymphocytes are impaired since the process relies on AID enzyme which has a miR-155 target in its 3′ UTR end. [5] [6] The phenotypic consequences involving deficiency of miR-155 in mice show later in life where the animals develop lung and intestinal lesions. [4]

Activated B and T cells show increased miR-155 expression, the same goes for macrophages and dendritic cells of the immune system. MiR-155 is crucial for proper lymphocyte development and maturation. Details of various manifestations of miR-155 levels and involvement in activities that ascertain optimal immune responses have been the subject of many researches:

Reduction of IgG1

Defective T and B cells as well as markedly decreased IgG1 responses were observed in miR-155-deficient mice, IgG1 is reduced whereas the expression of the IgM immunoglobulin remains normal in these mice. The change in IgG1 levels maybe explained by the fact that it is a target for miR-155 in B cells, the protein-encoding mRNA for the transcriptional regulator Pu.1-protein, elevation of Pu.1 protein predisposes defective IgG1 production. In addition to Pu.1, there are nearly 60 other differentially elevated genes in miR-155 deficient B cells, further inspection revealed possible miR-155 target sites in the 3′ UTR regions in these genes. [6]

Lymphocyte malignancies

Mature receptors affinity and specificity of lymphocytes to pathogenic agents underlie proper immune responses, optimal miR-155 coordination is required for manufacturing of normal B lymphocytes, production of high-affinity antibodies and balancing of BCR signalling. It has been demonstrated that miR-155 can be transferred through gap junctions from leukemic cells to healthy B cells and promote their transformation to tumorigenic-like cells [57]

Selection of competent B cells takes place in the germinal center where they are trained to differentiate body cells vs. foreign antigens, they compete for antigen recognition and for T cell help, in this fashion of selective pressure those B Cells that demonstrated high-affinity receptors and cooperation with T cells (affinity maturation) are recruited and deployed to the bone marrow or become memory B cells, apoptotic termination takes place for those B Cells failing the competition. Immature B cells which are miR-155 deficient evade apoptosis as a result of elevated Bcl-2 protein levels; a protein that was found to be involved in B Cell malignancies and to be controlled by miR-155. [6]

Inflammation

Inflammatory responses to triggers such as TNF-α involve macrophages with components that include miR-155. miR-155 is overexpressed in atopic dermatitis and contributes to chronic skin inflammation by increasing the proliferative response of T(H) cells through the downregulation of CTLA-4. [58] In Autoimmune disorders such as rheumatoid arthritis, miR-155 showed higher expression in patients' tissues and synovial fibroblasts. [4] In multiple sclerosis, increased expression of mir-155 has also been measured in peripheral and CNS-resident myeloid cells, including circulating blood monocytes and activated microglia. [59] It was also found that mir-155 is implicated in inflammation. Overexpression of mir-155 will lead to chronic inflammatory state in human. [60]

DNA viruses

In DNA viruses, miRNAs were experimentally verified, miRNAs in viruses are encoded by dsDNAs, [5] examples of such viruses include herpesviruses such as Humans-Epstein-Barr Virus (EBV) and adenoviruses, [4] another virus expressing miR-155-like miRNA in chickens is the oncogenic MDV-1 whose non-oncogenic relative MDV-2 does not, this suggests implication of miR-155 in lymphomagenesis. [5] Viruses can exploit host miRNAs to the degree that they use host miRNAs to encode for viral clones for example: miR-K12-11 in Kaposi's-sarcoma-associated Herpesvirus has a target specificity region orthologous to that of miR-155's; mimicking the action of miR-155 [61] and, sharing targets with it, thus it can be thought to suppress miR-155 accessibility to its targets by competition and this in effect downregulates expression of genes playing roles in cellular growth and apoptosis in a manner that defies regulations by miR-155. [4] EBV modulates host miR-155 expression, which is essential for growth of EBV-infected B cells. [62] EBV-infected cells have increased expression of miR-155 thereby disturbing equilibrium of expression for genes regulating transcription in those cells. [4] [5]

Cancer

Over-silencing by miR-155 may result in triggering oncogenic cascades that begin by apoptotic resistance, the pro-apoptotic Tumour Protein-53-induced-nuclear-protein1 (TP53INP1) is silenced by miR-155, over-expression of miR-155 leads to decreased levels of TP53INP1 in pancreatic ductal adenocarcinomas and possibly in other epithelial cancers where TP53INP1 activity is lost thereby resulting in apoptosis evasion and uncontrolled bouts of growth. [5]

Inactivation of DNA Mismatch Repair (MMR) as identified by elevation of mutation rates is the cause of Lynch Syndrome (LS), also known as hereditary nonpolyposis colorectal cancer (HNPCC), down-regulation of MMR controlling protein is carried out by over-expression of miR-155, MMR is controlled by a group of conserved proteins, reduced activity of these proteins results in elevated levels of mutations in the phenotype triggering a march towards developing this type of cancer. [63]

Other types of tumors in which miR-155 over-expression was reported include: thyroid carcinoma, breast cancer, colon cancer, cervical cancer, and lung cancer, where distinct miR-155 expression profiles quantification can potentially serve as signals for tumor detection and evaluation of prognosis outcome. [4] It is shown in an analysis that miR-155 expression is associated with survival in triple negative breast cancer. [64]

Notes

See also

Related Research Articles

microRNA Small non-coding ribonucleic acid molecule

MicroRNA (miRNA) are small, single-stranded, non-coding RNA molecules containing 21 to 23 nucleotides. Found in plants, animals and some viruses, miRNAs are involved in RNA silencing and post-transcriptional regulation of gene expression. miRNAs base-pair to complementary sequences in mRNA molecules, then silence said mRNA molecules by one or more of the following processes:

  1. Cleavage of the mRNA strand into two pieces,
  2. Destabilization of the mRNA by shortening its poly(A) tail, or
  3. Reducing translation of the mRNA into proteins.

RNA activation (RNAa) is a small RNA-guided and Argonaute (Ago)-dependent gene regulation phenomenon in which promoter-targeted short double-stranded RNAs (dsRNAs) induce target gene expression at the transcriptional/epigenetic level. RNAa was first reported in a 2006 PNAS paper by Li et al. who also coined the term "RNAa" as a contrast to RNA interference (RNAi) to describe such gene activation phenomenon. dsRNAs that trigger RNAa have been termed small activating RNA (saRNA). Since the initial discovery of RNAa in human cells, many other groups have made similar observations in different mammalian species including human, non-human primates, rat and mice, plant and C. elegans, suggesting that RNAa is an evolutionarily conserved mechanism of gene regulation.

mir-17 microRNA precursor family

The miR-17 microRNA precursor family are a group of related small non-coding RNA genes called microRNAs that regulate gene expression. The microRNA precursor miR-17 family, includes miR-20a/b, miR-93, and miR-106a/b. With the exception of miR-93, these microRNAs are produced from several microRNA gene clusters, which apparently arose from a series of ancient evolutionary genetic duplication events, and also include members of the miR-19, and miR-25 families. These clusters are transcribed as long non-coding RNA transcripts that are processed to form ~70 nucleotide microRNA precursors, that are subsequently processed by the Dicer enzyme to give a ~22 nucleotide products. The mature microRNA products are thought to regulate expression levels of other genes through complementarity to the 3' UTR of specific target messenger RNA.

mir-199 microRNA precursor

The miR-199 microRNA precursor is a short non-coding RNA gene involved in gene regulation. miR-199 genes have now been predicted or experimentally confirmed in mouse, human and a further 21 other species. microRNAs are transcribed as ~70 nucleotide precursors and subsequently processed by the Dicer enzyme to give a ~22 nucleotide product. The mature products are thought to have regulatory roles through complementarity to mRNA.

mir-29 microRNA precursor

The miR-29 microRNA precursor, or pre-miRNA, is a small RNA molecule in the shape of a stem-loop or hairpin. Each arm of the hairpin can be processed into one member of a closely related family of short non-coding RNAs that are involved in regulating gene expression. The processed, or "mature" products of the precursor molecule are known as microRNA (miRNA), and have been predicted or confirmed in a wide range of species.

<span class="mw-page-title-main">PD-L1</span> Mammalian protein found in humans

Programmed death-ligand 1 (PD-L1) also known as cluster of differentiation 274 (CD274) or B7 homolog 1 (B7-H1) is a protein that in humans is encoded by the CD274 gene.

<span class="mw-page-title-main">C-C chemokine receptor type 6</span> Mammalian protein found in Homo sapiens

Chemokine receptor 6 also known as CCR6 is a CC chemokine receptor protein which in humans is encoded by the CCR6 gene. CCR6 has also recently been designated CD196. The gene is located on the long arm of Chromosome 6 (6q27) on the Watson (plus) strand. It is 139,737 bases long and encodes a protein of 374 amino acids.

<span class="mw-page-title-main">NT5E</span> Enzyme converting AMP to adenosine

5′-nucleotidase (5′-NT), also known as ecto-5′-nucleotidase or CD73, is an enzyme that in humans is encoded by the NT5E gene. CD73 commonly serves to convert AMP to adenosine.

mir-126

In molecular biology mir-126 is a short non-coding RNA molecule. MicroRNAs function to regulate the expression levels of other genes by several pre- and post-transcription mechanisms.

miR-132 Non-coding RNA molecule

In molecular biology miR-132 microRNA is a short non-coding RNA molecule. MicroRNAs function to regulate the expression levels of other genes by several mechanisms, generally reducing protein levels through the cleavage of mRNAs or the repression of their translation. Several targets for miR-132 have been described, including mediators of neurological development, synaptic transmission, inflammation and angiogenesis.

mir-31

miR-31 has been characterised as a tumour suppressor miRNA, with its levels varying in breast cancer cells according to the metastatic state of the tumour. From its typical abundance in healthy tissue is a moderate decrease in non-metastatic breast cancer cell lines, and levels are almost completely absent in mouse and human metastatic breast cancer cell lines. Mir-31-5p has also been observed upregulated in Zinc Deficient rats compared to normal in ESCC and in other types of cancers when using this animal model. There has also been observed a strong encapsulation of tumour cells expressing miR-31, as well as a reduced cell survival rate. miR-31's antimetastatic effects therefore make it a potential therapeutic target for breast cancer. However, these two papers were formally retracted by the authors in 2015.

mir-210 microRNA

In molecular biology mir-210 microRNA is a short RNA molecule. MicroRNAs function to regulate the expression levels of other genes by several mechanisms.

miR-146 Family of microRNA precursors

miR-146 is a family of microRNA precursors found in mammals, including humans. The ~22 nucleotide mature miRNA sequence is excised from the precursor hairpin by the enzyme Dicer. This sequence then associates with RISC which effects RNA interference.

In molecular biology mir-339 microRNA is a short RNA molecule. MicroRNAs function to regulate the expression levels of other genes by several mechanisms. miR-339-5p expression was associated with overall survival in breast cancer.

In molecular biology mir-153 microRNA is a short RNA molecule. MicroRNAs function to regulate the expression levels of other genes by several mechanisms.

In molecular biology mir-663 microRNA is a short RNA molecule. MicroRNAs function to regulate the expression levels of other genes by several mechanisms.

In molecular biology mir-885 microRNA is a short RNA molecule. MicroRNAs function to regulate the expression levels of other genes by several mechanisms.

miR-324-5p is a microRNA that functions in cell growth, apoptosis, cancer, epilepsy, neuronal differentiation, psychiatric conditions, cardiac disease pathology, and more. As a microRNA, it regulates gene expression through targeting mRNAs. Additionally, miR-324-5p is both an intracellular miRNA, meaning it is commonly found within the microenvironment of the cell, and one of several circulating miRNAs found throughout the body. Its presence throughout the body both within and external to cells may contribute to miR-324-5p's wide array of functions and role in numerous disease pathologies – especially cancer – in various organ systems.

MicroRNA-125 (miR-125) is a highly conserved microRNA family consisting of miR-125a and miR-125b. MiR-125 can be found throughout diverse species from nematode to humans. MiR-125 family members are involved in cell differentiation, proliferation and apoptosis as a result of targeting messenger RNAs related to these cellular processes. By affecting these cellular processes, miR-125 can cause promotion or suppression of pathological processes including carcinogenesis, muscle abnormalities, neurological disorders and pathologies of the immune system. Moreover, miR-125 also plays an important role in normal immune functions and was described to affect development and function of immune cells as well as playing role in immunological host defense in response to bacterial and viral infections.

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