His scientific interests lie mostly in Matrix metalloproteinase, Molecular biology, Genomic imprinting, Genetics and Cell biology. Paul D. Soloway combines subjects such as Morphogenesis, Cell, Cell culture and Mutant with his study of Matrix metalloproteinase. His Molecular biology research integrates issues from Concanavalin A, Fibroblast, In vitro and Matrix Metalloproteinase 3.
His research in Genomic imprinting intersects with topics in Imprinting and Epigenetics. His work on Extracellular matrix as part of general Cell biology research is frequently linked to Embryonic Induction, thereby connecting diverse disciplines of science. He usually deals with DNA methylation and limits it to topics linked to Methylation and Non-coding RNA and RNA.
Genetics, Matrix metalloproteinase, DNA methylation, Molecular biology and Genomic imprinting are his primary areas of study. His Matrix metalloproteinase study incorporates themes from Cell, Extracellular matrix, Cell biology and Cell growth. His study focuses on the intersection of Extracellular matrix and fields such as Pathology with connections in the field of Internal medicine and Endocrinology.
His studies in DNA methylation integrate themes in fields like Regulation of gene expression and Methylation, DNA. The concepts of his Molecular biology study are interwoven with issues in Mutation, Fibroblast, In vitro and Mutant. His work carried out in the field of Genomic imprinting brings together such families of science as Imprinting, Locus and Gene expression profiling.
Paul D. Soloway mainly focuses on DNA methylation, Genetics, Epigenetics, Chromatin and Histone. His DNA methylation research incorporates themes from Molecular biology and DNA. His work on Lysis is typically connected to Fluorescence microscope as part of general Molecular biology study, connecting several disciplines of science.
His study in RNA-Directed DNA Methylation, Methylation and Regulation of gene expression are all subfields of Genetics. His research investigates the connection between Regulation of gene expression and topics such as Cell biology that intersect with problems in Epigenesis. His Epigenetics research is multidisciplinary, relying on both Epigenomics, Internal medicine, Disease, Metabolic pathway and Genomic imprinting.
The scientist’s investigation covers issues in Regulation of gene expression, Genetics, Epigenetics, DNA methylation and Molecular biology. He has included themes like Small nucleolar RNA, Histone, Chromatin, Cell biology and Gene silencing in his Regulation of gene expression study. Paul D. Soloway connects Genetics with Argonaute in his research.
As part of his studies on Epigenetics, Paul D. Soloway frequently links adjacent subjects like Epigenomics. His Epigenomics research incorporates elements of Computational biology and Methylated DNA immunoprecipitation. In general Molecular biology, his work in Lysis is often linked to Microfluidics linking many areas of study.
This overview was generated by a machine learning system which analysed the scientist’s body of work. If you have any feedback, you can contact us here.
Tumor Cell Traffic through the Extracellular Matrix Is Controlled by the Membrane-anchored Collagenase MT1-MMP
Farideh Sabeh;Ichiro Ota;Kenn Holmbeck;Henning Birkedal-Hansen.
Journal of Cell Biology (2004)
Regional loss of imprinting and growth deficiency in mice with a targeted deletion of KvDMR1.
Galina V. Fitzpatrick;Paul D. Soloway;Michael J. Higgins.
Nature Genetics (2002)
Elevated matrix metalloprotease and angiostatin levels in integrin α1 knockout mice cause reduced tumor vascularization
Ambra Pozzi;Philip E. Moberg;Lindsey A. Miles;Simone Wagner.
Proceedings of the National Academy of Sciences of the United States of America (2000)
TIMP-2 Is Required for Efficient Activation of proMMP-2 in Vivo
Zhiping Wang;Ruth Juttermann;Paul D. Soloway.
Journal of Biological Chemistry (2000)
Role for piRNAs and noncoding RNA in de novo DNA methylation of the imprinted mouse Rasgrf1 locus.
Toshiaki Watanabe;Toshiaki Watanabe;Shin Ichi Tomizawa;Shin Ichi Tomizawa;Kohzoh Mitsuya;Yasushi Totoki.
Site-specific inductive and inhibitory activities of MMP-2 and MMP-3 orchestrate mammary gland branching morphogenesis
Bryony S. Wiseman;Mark D. Sternlicht;Leif R. Lund;Caroline M. Alexander.
Journal of Cell Biology (2003)
Cellular Activation of MMP-2 (Gelatinase A) by MT2-MMP Occurs via a TIMP-2-independent Pathway
Charlotte J. Morrison;Georgina S. Butler;Heather F. Bigg;Clive R. Roberts.
Journal of Biological Chemistry (2001)
Transcriptome-wide identification of novel imprinted genes in neonatal mouse brain.
Xu Wang;Qi-Wei Sun;Sean D McGrath;Elaine R. Mardis.
PLOS ONE (2008)
DNA methylation, imprinting and cancer.
Christoph Plass;Paul D Soloway.
European Journal of Human Genetics (2002)
Differential inhibition of membrane type 3 (MT3)-matrix metalloproteinase (MMP) and MT1-MMP by tissue inhibitor of metalloproteinase (TIMP)-2 and TIMP-3 regulates pro-MMP-2 activation
Huiren Zhao;M. Margarida Bernardo;Pamela Osenkowski;Anjum Sohail.
Journal of Biological Chemistry (2004)
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