MicroRNA Mirn140 modulates Pdgf signaling during palatogenesis

Eberhart, Johann K.; He, Xinjun; Swartz, Mary E.; Yan, Yi‐Lin; Song, Hao; Boling, Taylor C.; Kunerth, Allison K.; Walker, Macie B.; Kimmel, Charles B.; Postlethwait, John H.

doi:10.1038/ng.82

Cited by 306 publications

(383 citation statements)

References 43 publications

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“…MiR-140, a positive regulator of chondrogenesis through the inhibition of HDAC4 and Dnpep, contributes to craniofacial development and endochondral bone formation. [14][15][16] Consistent with this, mice lacking miR-140 display accelerated bone formation at embryonic and neonatal stages of development. 15 Conversely, miR-199a* and miR-145 have been shown to negatively regulate chondrocyte differentiation; miR-199a* downregulates the expression of Smad1, 17 whereas miR-145 targets Sox9, a key transcription factor involved in chondrogenesis.…”

Section: A Central Role For Mirnas In Bone Homeostasissupporting

confidence: 65%

MicroRNAs as regulators of bone homeostasis and bone metastasis

Ell

Kang

2014

Bonekey Reports

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MicroRNAs (miRNAs) are short, endogenous RNAs that have essential roles in regulating gene expression through the disruption of target genes. The miRNA-induced suppression can occur through Argonaute-mediated cleavage of target mRNAs or by translational inhibition. System-wide studies have underscored the integral role that miRNAs play in regulating the expression of essential genes within bone marrow stromal cells. The miRNA expression has been shown to enhance or inhibit cell differentiation and activity, and elucidating miRNA targets within bone marrow cells has revealed novel regulations during normal bone development. Importantly, multiple studies have shown that miRNA misexpression mediates the progression of bone-related pathologies, including osteopetrosis and osteoporosis, as well as the development and progression of osteosarcoma. Furthermore, recent studies have detailed the capacity for miRNAs to influence bone metastasis from a number of primary carcinomas. Taken together, these findings reveal the significant clinical potential for miRNAs to regulate bone homeostasis, as well as to mediate bone-related pathologies.BoneKEy Reports 3, Article number: 549 (2014) | doi:10.1038/bonekey.2014.44 MiRNA Biogenesis and FunctionThe past decade has seen a torrent of novel research into the post-translational regulation of genes via microRNA-mediated suppression. The microRNAs (miRNAs) are a class of B22-nucleotide-long RNAs that repress gene expression through complementary binding to sites in the 3 0 -untranslated region (UTR) of target mRNAs. 1 Mature miRNAs are generated by the sequential cleavage of longer precursor transcripts, or pri-miRNAs, that are typically transcribed from intragenic or intergenic regions by RNA polymerase II. 2 The initial cleavage step, mediated by Drosha and the DGCR8 complex, occurs in the nucleus and produces a shortened (70-100 nucleotides) pre-miRNA hairpin. Pre-miRNAs are exported from the nucleus by Exportin 5, followed by a second cleavage by the ribonuclease Dicer that produces a double-stranded, B18-25-nucleotide-long mature miRNA. One miRNA strand will then combine with Argonaute (AGO2) proteins to produce an RNAinduced silencing complex, allowing for directed pairing with target mRNAs. 1

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Section: A Central Role For Mirnas In Bone Homeostasissupporting

confidence: 65%

MicroRNAs as regulators of bone homeostasis and bone metastasis

Ell

Kang

2014

Bonekey Reports

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“…Disruption of platelet-derived growth factor receptor alpha (Pdgfra) in zebrafish by Mirn140 was found to cause craniofacial abnormalities including cleft palate. 6 Consistent evidence supporting a significant role in palatal development came from previous studies in Pdgfra knockout mice. [7][8][9][10] PDGFRa (MIM 173490) maps to chromosome 4q12, spans 65 kb, contains 23 exons, and encodes a protein with 743 amino-acid residues.…”

Section: Introductionsupporting

confidence: 53%

“…Pdgfra mutations and Mirn 140-injected embryos shared a range of facial defects, including cleft palate. 6 A recent report suggests that the single-nucleotide polymorphisms (SNP) region in pre-miR-140 contributes to cleft palate susceptibility by influencing the processing of miR-140 in human PDGFRa. 17 In addition, a subsequent publication has revealed possible synergistic interaction between infants with CA/AA at rs7205289 located in the microRNA (miR)-140 and maternal passive smoking in contributing to cleft palate risk.…”

Section: Discussionmentioning

confidence: 99%

PDGFRa mutations in humans with isolated cleft palate

et al. 2012

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Isolated cleft palate (CP) is common in humans and has complex genetic etiologies. Many genes have been found to contribute to CP, but the full spectrum of genes remains unknown. PCR-sequencing of the entire coding regions and the 3 0 untranslated region (UTR) of the platelet-derived growth factor receptor alpha (PDGFRa) and the microRNA (miR), miR-140 identified seven novel single base-pair substitutions in the PDGFRa in 9/102 patients with CP (8.8%), compared with 5/500 ethnic-matched unaffected controls (1%) (the two-tailed P-valueo0.0001). Of these seven, four were missense mutations in the coding regions and three in the 3 0 UTR. Frequencies of four changes (three in coding, one in 3 0 UTR) were statistically different from those of controls (P-valueo0.05). The c.*34G4A was identified in 1/102 cases and 0/500 controls. This position is conserved in primates and located 10 bp away from a predicted binding site for the miR-140. Luciferase assay revealed that, in the presence of miR-140, the c.*34G4A significantly repressed luciferase activity compared with that of the wild type, suggesting functional significance of this variant. This is the first study providing evidence supporting a role of PDGFRa in human CP.

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“…MiR-140 positively regulates chondrocyte differentiation by inhibiting HDAC4 and Dnpep, and contributes to craniofacial development and endochondral bone formation. 17,18 Consistent with this, mice lacking miR-140 display accelerated bone formation at the embryonic and neonatal stages of development. 18 Conversely, miR-199a* and miR-145 negatively regulate chondrogenesis; miR-199a* downregulates the expression of Smad1, 19 whereas miR-145 targets Sox9, which encodes an essential transcription factor for chondrocyte differentiation.…”

Section: Mirna Regulation In Bone Homeostasissupporting

confidence: 61%

Bone marrow stroma-derived miRNAs as regulators, biomarkers and therapeutic targets of bone metastasis

Alečković

Kang

2015

BoneKEy Reports

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MicroRNAs (miRNAs) are short, endogenous RNA molecules that have essential roles in regulating gene expression. They control numerous physiological and cellular processes, including normal bone organogenesis and homeostasis, by enhancing or inhibiting bone marrow cell growth, differentiation, functional activity and crosstalk of the multiple cell types within the bone. Hence, elucidating miRNA targets in bone marrow stromal cells has revealed novel regulations during bone development and maintenance. Moreover, recent studies have detailed the capacity for bone stromal miRNAs to influence bone metastasis from a number of primary carcinomas by interfering with bone homeostasis or by directly influencing metastatic tumor cells. Owing to the current lack of good diagnostic biomarkers of bone metastases, such changes in bone stromal miRNA expression in the presence of metastatic lesions may become useful biomarkers, and may even serve as therapeutic targets. In particular, cell-free and exosomal miRNAs shed from bone stromal cells into circulation may be developed into novel biomarkers that can be routinely measured in easily accessible samples. Taken together, these findings reveal the significant role of bone marrow stroma-derived miRNAs in the regulation of bone homeostasis and bone metastasis. Biogenesis and Function of miRNAsMicroRNAs (miRNAs) are a large family of noncoding B22-nucleotide-long RNA molecules that negatively regulate gene expression. 1 It is estimated that miRNAs regulate about 50% of all protein-coding genes. 2 They repress gene expression through complementary binding to sites in the 3 0 -untranslated region (UTR) of target mRNAs. 3,4 miRNA-mediated inhibition occurs either by mRNA degradation or translational silencing. Cleavage of target mRNAs occurs when the miRNA and the target mRNA exhibit perfect complementarity. 3 Conversely, miRNA-mRNA pairings with imperfect complementarity result in translational inhibition in the absence of target cleavage. 3,5 Thus, even in the absence of perfect binding, the association between an miRNA and a target 3 0 -UTR still results in the suppression of a target protein. Owing to the relatively short length of the seed sequence that binds to the 3 0 -UTR (5-7 nucleotides), each miRNA can potentially recognize hundreds of mRNAs and is thus a powerful molecular manager that can control several gene regulatory networks simultaneously.miRNA genes are typically transcribed into stem-loop structures from intra-or intergenic regions by RNA polymerase II and undergo sequential cleavage steps to produce mature miRNAs. 2 In the nucleus, newly transcribed pri-miRNAs (primary miRNAs) are cleaved by a complex formed by the RNase III enzyme Drosha and the double-stranded RNA-binding protein Pasha (or DGCR8) to produce precursor miRNAs. These precursor miRNAs are about 70-100 nucleotides long. 6 They are exported from the nucleus by Exportin 5 and the Ran-GTP cofactor, 7 where they undergo a second cleavage by the endoribonuclease Dicer to produce a double-stranded, B18-2...

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MicroRNA Mirn140 modulates Pdgf signaling during palatogenesis

Cited by 306 publications

References 43 publications

MicroRNAs as regulators of bone homeostasis and bone metastasis

MicroRNAs as regulators of bone homeostasis and bone metastasis

PDGFRa mutations in humans with isolated cleft palate

Bone marrow stroma-derived miRNAs as regulators, biomarkers and therapeutic targets of bone metastasis

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