| miRNA | gene name | experiments | ||||||
|---|---|---|---|---|---|---|---|---|
| hsa-miR-642b-5p | BTG2 |
|
||||||
| hsa-miR-642b-5p | ZDHHC5 |
|
||||||
| hsa-miR-642b-5p | HOXC8 |
|
||||||
| hsa-miR-642b-5p | NPTX1 |
|
||||||
| hsa-miR-642b-5p | SH3BP5L |
|
||||||
| hsa-miR-642b-5p | CCDC115 |
|
||||||
| hsa-miR-642b-5p | SORCS2 |
|
||||||
| hsa-miR-642b-5p | IL1F10 |
|
||||||
| hsa-miR-642b-5p | ZDHHC20 |
|
||||||
| hsa-miR-642b-5p | ZNF865 |
|
||||||
| hsa-miR-642b-5p | ZNF385A |
|
||||||
| hsa-miR-642b-5p | ZFHX3 |
|
||||||
| hsa-miR-642b-5p | PSAT1 |
|
||||||
| hsa-miR-642b-5p | ADAT2 |
|
||||||
| hsa-miR-642b-5p | RAP1B |
|
||||||
| hsa-miR-642b-5p | ALG1 |
|
||||||
| hsa-miR-642b-5p | KRAS |
|
||||||
| hsa-miR-642b-5p | SLC35G1 |
|
||||||
| hsa-miR-642b-5p | XKR4 |
|
||||||
| hsa-miR-642b-5p | ARL6IP1 |
|
||||||
| hsa-miR-642b-5p | DPF2 |
|
||||||
| hsa-miR-642b-5p | CACNA1A |
|
||||||
| hsa-miR-642b-5p | SHOX2 |
|
||||||
| hsa-miR-642b-5p | C14orf180 |
|
||||||
| hsa-miR-642b-5p | ABCC12 |
|
||||||
| hsa-miR-642b-5p | DUSP10 |
|
||||||
| hsa-miR-642b-5p | VPS8 |
|
||||||
| hsa-miR-642b-5p | LZTR1 |
|
||||||
| hsa-miR-642b-5p | SECISBP2 |
|
||||||
| hsa-miR-642b-5p | PALM2 |
|
||||||
| hsa-miR-642b-5p | ARF1 |
|
||||||
| hsa-miR-642b-5p | IPO9 |
|
||||||
| hsa-miR-642b-5p | IGF2BP1 |
|
||||||
| hsa-miR-642b-5p | LY6G6D |
|
||||||
| hsa-miR-642b-5p | LY6G6F |
|
||||||
| hsa-miR-642b-5p | WDR37 |
|
||||||
| hsa-miR-642b-5p | NCS1 |
|
||||||
| hsa-miR-642b-5p | ZNF79 |
|
||||||
| hsa-miR-642b-5p | TRIM66 |
|
||||||
| hsa-miR-642b-5p | STX6 |
|
| authors | journal | year | Pubmed link | title | |
|---|---|---|---|---|---|
| 1 | Hafner et al. | Cell | 2010 | 20371350 | Transcriptome-wide identification of RNA-binding protein and microRNA target sites by PAR-CLIP. |
| 2 | Farazi et al. | Genome Biol. | 2014 | 24398324 | Identification of distinct miRNA target regulation between breast cancer molecular subtypes using AGO2-PAR-CLIP and patient datasets. |
| 3 | Karginov et al. | Genes Dev. | 2013 | 23824327 | Remodeling of Ago2-mRNA interactions upon cellular stress reflects miRNA complementarity and correlates with altered translation rates. |
| 4 | Kishore et al. | Nat. Methods | 2011 | 21572407 | A quantitative analysis of CLIP methods for identifying binding sites of RNA-binding proteins. |
| 5 | Gottwein et al. | Cell Host Microbe | 2011 | 22100165 | Viral microRNA targetome of KSHV-infected primary effusion lymphoma cell lines. |
| 6 | Kishore et al. | Genome Biol. | 2013 | 23706177 | Insights into snoRNA biogenesis and processing from PAR-CLIP of snoRNA core proteins and small RNA sequencing. |
| 7 | Haecker et al. | PLoS Pathog. | 2012 | 22927820 | Ago HITS-CLIP expands understanding of Kaposi's sarcoma-associated herpesvirus miRNA function in primary effusion lymphomas. |
| 8 | Whisnant et al. | MBio | 2013 | 23592263 | In-depth analysis of the interaction of HIV-1 with cellular microRNA biogenesis and effector mechanisms. |
| 9 | Memczak et al. | Nature | 2013 | 23446348 | Circular RNAs are a large class of animal RNAs with regulatory potency. |
| 10 | Lipchina et al. | Genes Dev. | 2011 | 22012620 | Genome-wide identification of microRNA targets in human ES cells reveals a role for miR-302 in modulating BMP response. |
| 11 | Majoros et al. | Nat. Methods | 2013 | 23708386 | MicroRNA target site identification by integrating sequence and binding information. |
| 12 | Xue et al. | Cell | 2013 | 23313552 | Direct conversion of fibroblasts to neurons by reprogramming PTB-regulated microRNA circuits. |
| 13 | Chi et al. | Nature | 2009 | 19536157 | Argonaute HITS-CLIP decodes microRNA-mRNA interaction maps. |