Mohammad K. Hajihosseini scite author profile

MicroRNAs (miRNA) are short RNA molecules regulating the expression of specific mRNAs. We investigated the expression pattern and potential targets of mouse miR-140 and found that miR-140 is specifically expressed in cartilage tissues of mouse embryos during both long and flat bone development. MiR-140 expression was detected in the limbs of E11.5 embryos in the primorida of future bones both in the fore and hindlimb and across autopod, zeugopod and stylopod. All digits of E14.5 fore-and hindlimbs showed accumulation of miR-140, except the first digit of the hindlimb. MiR-140 expression was also detected in the cartilagenous base of E17.5 skulls and in the sternum, the proximal rib heads and the developing vertebral column of E15.5 embryos. A potential target of miR-140, histone deacetylase 4, was validated experimentally and the possible role of miR-140 in long bone development is discussed.

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Fgf10-Expressing Tanycytes Add New Neurons to the Appetite/Energy-Balance Regulating Centers of the Postnatal and Adult Hypothalamus

Haan

et al. 2013

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The expression and function of microRNAs in chondrogenesis and osteoarthritis

Swingler¹,

Wheeler²,

Carmont³

et al. 2012

Arthritis & Rheumatism

264

262

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Objective. To use an in vitro model of chondrogenesis to identify microRNAs (miRNAs) with a functional role in cartilage homeostasis.Methods. The expression of miRNAs was measured in the ATDC5 cell model of chondrogenesis using microarray and was verified using quantitative reverse transcription-polymerase chain reaction. MicroRNA expression was localized by in situ hybridization. Predicted miRNA target genes were validated using 3-untranslated region-Luc reporter plasmids containing either wild-type sequences or mutants of the miRNA target sequence. Signaling through the Smad pathway was measured using a (CAGA) 12 -Luc reporter.Results. The expression of several miRNAs was regulated during chondrogenesis. These included 39 miRNAs that are coexpressed with miRNA-140 (miR-140), which is known to be involved in cartilage homeostasis and osteoarthritis (OA). Of these miRNAs, miR-455 resides within an intron of COL27A1 that encodes a cartilage collagen. When human OA cartilage was compared with cartilage obtained from patients with femoral neck fractures, the expression of both miR-140-5p and miR-455-3p was increased in OA cartilage. In situ hybridization showed miR-455-3p expression in the developing limbs of chicks and mice and in human OA cartilage. The expression of miR-455-3p was regulated by transforming growth factor ␤ (TGF␤) ligands, and miRNA regulated TGF␤ signaling. ACVR2B, SMAD2, and CHRDL1 were direct targets of miR-455-3p and may mediate its functional impact on TGF␤ signaling.Conclusion. MicroRNA-455 is expressed during chondrogenesis and in adult articular cartilage, where it can regulate TGF␤ signaling, suppressing the Smad2/3 pathway. Diminished signaling through this pathway during the aging process and in OA chondrocytes is known to contribute to cartilage destruction. We propose that the increased expression of miR-455 in OA exacerbates this process and contributes to disease pathology.Osteoarthritis (OA) is a degenerative joint disease characterized by degradation of articular cartilage, thickening of subchondral bone, and formation of osteophytes (1). The etiology of OA is complex, with the contribution of genetic, developmental, biochemical, and biomechanical factors. Chondrocytes are the only cells in cartilage and are responsible for the synthesis and turnover of extracellular matrix (ECM), which is crucial to tissue function.During development, mesenchymal cells aggregate and differentiate into chondrocytes, which undergo a series of differentiation events: proliferation, hypertrophy, terminal differentiation, mineralization, and programmed cell death. Blood vessels penetrate the calcified matrix, bringing in osteoblasts that build new bone. The cartilage model grows by rounds of chondrocyte cell

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Formation and Differentiation of Multiple Mesenchymal Lineages during Lung Development Is Regulated by β-catenin Signaling

et al. 2008

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BackgroundThe role of ß-catenin signaling in mesodermal lineage formation and differentiation has been elusive.MethodologyTo define the role of ß-catenin signaling in these processes, we used a Dermo1(Twist2)Cre/+ line to target a floxed β-catenin allele, throughout the embryonic mesenchyme. Strikingly, the Dermo1Cre/+; β-cateninf/− conditional Knock Out embryos largely phenocopy Pitx1−/−/Pitx2−/− double knockout embryos, suggesting that ß-catenin signaling in the mesenchyme depends mostly on the PITX family of transcription factors. We have dissected this relationship further in the developing lungs and find that mesenchymal deletion of β-catenin differentially affects two major mesenchymal lineages. The amplification but not differentiation of Fgf10-expressing parabronchial smooth muscle progenitor cells is drastically reduced. In the angioblast-endothelial lineage, however, only differentiation into mature endothelial cells is impaired.ConclusionTaken together these findings reveal a hierarchy of gene activity involving ß-catenin and PITX, as important regulators of mesenchymal cell proliferation and differentiation.

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Hypothalamic tanycytes—masters and servants of metabolic, neuroendocrine, and neurogenic functions

2015

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There is a resurgent interest in tanycytes, a radial glial-like cell population occupying the floor and ventro-lateral walls of the third ventricle (3V). Tanycytes reside in close proximity to hypothalamic neuronal nuclei that regulate appetite and energy expenditure, with a subset sending projections into these nuclei. Moreover, tanycytes are exposed to 3V cerebrospinal fluid and have privileged access to plasma metabolites and hormones, through fenestrated capillaries. Indeed, some tanycytes act as conduits for trafficking of these molecules into the brain parenchyma. Tanycytes can also act as neural stem/progenitor cells, supplying the postnatal and adult hypothalamus with new neurons. Collectively, these findings suggest that tanycytes regulate and integrate important trophic and metabolic processes and possibly endow functional malleability to neuronal circuits of the hypothalamus. Hence, manipulation of tanycyte biology could provide a valuable tool for modulating hypothalamic functions such as energy uptake and expenditure in order to tackle prevalent eating disorders such as obesity and anorexia.

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