{"id":718,"date":"2023-03-04T13:11:00","date_gmt":"2023-03-04T13:11:00","guid":{"rendered":"https:\/\/ladomerylab.org\/?page_id=718"},"modified":"2023-03-09T11:46:46","modified_gmt":"2023-03-09T11:46:46","slug":"invited-reviews","status":"publish","type":"page","link":"https:\/\/ladomerylab.org\/invited-reviews\/","title":{"rendered":"Invited Reviews"},"content":{"rendered":"

Epigenetic Regulation of Alternative Splicing: how lncRNAs Tailor the Message<\/strong><\/a>
Noncoding RNA 7:21<\/i><\/strong> (2021)<\/p><\/div><\/div>

Investigating ROS, RNS, and H2S-Sensitive Signaling Proteins<\/strong><\/a>
Methods Mol Biol 1990:27-42<\/i><\/strong> (2019)<\/p><\/div><\/div>

Working with Hypoxia<\/strong><\/a>
Methods Mol Biol 1990:109-133<\/i><\/strong> (2019)<\/p><\/div><\/div>

The d16HER2 splice variant: a friend or foe of HER2-positive cancers?<\/strong><\/a>
Cancers (Basel) 11: E902.<\/i><\/strong> (2019)<\/p><\/div><\/div>

Alternative splicing in the Hippo pathway – implications for disease and potential therapeutic targets<\/strong><\/a>
Genes 13: pii: E161<\/i><\/strong> (2018)<\/p><\/div><\/div>

Oligonucleotide-based systems: DNA, microRNAs, DNA\/RNA aptamers<\/strong><\/a>
Essays in Biochemistry 60, 27-35<\/i><\/strong> (2016)<\/p><\/div><\/div>

The oncogene ERG: a key factor in prostate cancer<\/strong><\/a>
Oncogene 35, 403-414<\/i><\/strong> (2016)<\/p><\/div><\/div>

Detection of thiol modifications by hydrogen sulphide<\/strong><\/a>
Methods in Enzymology 555, 233-251<\/i><\/strong> (2015)<\/p><\/div><\/div>

The evolutionarily conserved multifunctional glycine-rich RNA binding proteins play key roles in development and stress adaptation<\/strong><\/a>
Physiologia Plantarum 153, 1-11<\/i><\/strong> (2014)<\/p><\/div><\/div>

Alternative splicing: role in cancer development and progression<\/strong><\/a>
Int J Cell Biol 2013:421606<\/i><\/strong> (2013)<\/p><\/div><\/div>

Aberrant alternative splicing is another hallmark of cancer<\/strong><\/a>
Int J Cell Biol, 2013:463786<\/i><\/strong> (2013)<\/p><\/div><\/div>

The relationship between the structure and biological actions of green tea catechins<\/strong><\/a>
Food Chemistry 141, 3282-3289<\/i><\/strong> (2013)<\/p><\/div><\/div>

SRPK1 inhibition in vivo: modulation of VEGF splicing and potential treatment for multiple diseases<\/strong><\/a>
Biochem. Soc. Trans. 40, 831-835<\/i><\/strong> (2012)<\/p><\/div><\/div>

Role of splice variants in the metastatic progression of prostate cancer<\/strong><\/a>
Biochem. Soc. Trans. 40, 870-874<\/i><\/strong> (2012)<\/p><\/div><\/div>

MicroRNAs: their discovery, biogenesis, function and potential use as biomarkers in non-invasive prenatal diagnostics<\/strong><\/a>
Int. J. Mol. Epidemiol. Gen. 2, 253-260<\/i><\/strong> (2011)<\/p><\/div><\/div>

A Report of the First International WT1 Meeting, University of Manchester UK, 2008<\/strong><\/a>
Int. J. Mol. Epidemiol. Gen. 1: 76-82<\/i><\/strong> (2010)<\/p><\/div><\/div>

RAP55: insights into an evolutionarily conserved protein family<\/strong><\/a>
Int. J. Biochem. Cell. Biol. 41: 977-981<\/i><\/strong> (2009)<\/p><\/div><\/div>

New insights into the function of the Wilms tumor suppressor gene WT1 in podocytes<\/strong><\/a>
Am. J. Physiol. Renal Physiol. 295: F12-7<\/i><\/strong> (2008)<\/p><\/div><\/div>

Targeting splicing in prostate cancer<\/strong><\/a>
International Journal of Molecular Sciences, accepted<\/i><\/strong> (2018)<\/p><\/div><\/div>

The post-transcriptional roles of WT1, a multifunctional zinc-finger protein<\/strong><\/a>
BBA - Reviews on Cancer 1785: 55-62<\/i><\/strong> (2008)<\/p><\/div><\/div>

Alternative splicing in angiogenesis: the vascular endothelial growth factor paradigm<\/strong><\/a>
Cancer Lett. 249: 133-142<\/i><\/strong> (2007)<\/p><\/div><\/div>

Murine Denys-Drash syndrome: evidence of podocyte de-differentiation and systemic mediation of glomerulosclerosis<\/strong><\/a>
Hum. Mol. Genet. 12: 2379-2394<\/i><\/strong> (2003)<\/p><\/div><\/div>

Multiple roles for the Wilms’ tumor suppressor, WT1<\/strong><\/a>
Cancer Res. 59:1747s-1751s<\/i><\/strong> (1999)<\/p><\/div><\/div>

Multifunctional proteins suggest connections between transcriptional and post-transcriptional processes<\/strong><\/a>
Bioessays 19: 903-909<\/i><\/strong> (1997)<\/p><\/div><\/div>

Transcription and masking of mRNA in germ cells: involvement of Y-box proteins<\/strong><\/a>
Chromosoma 104: 469-478<\/i><\/strong> (1996)<\/p><\/div><\/div>

Masking of mRNA by Y-box proteins<\/strong><\/a>
FASEB J. 10: 435-443<\/i><\/strong> (1996)<\/p><\/div><\/div>

A role for Y-box proteins in cell proliferation<\/strong><\/a>
Bioessays 17: 9-11<\/i><\/strong> (1995)<\/p><\/div><\/div>

Plants and pathogens: in concert or in conflict?<\/strong><\/a>
Ormond Papers 7: 135-145<\/i><\/strong> (1990)<\/p><\/div><\/div><\/section>\n

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