Jr. James E. Darnell scite author profile

STATs (signal transducers and activators of transcription) are a family of latent cytoplasmic proteins that are activated to participate in gene control when cells encounter various extracellular polypeptides. Biochemical and molecular genetic explorations have defined a single tyrosine phosphorylation site and, in a dimeric partner molecule, an Src homology 2 (SH2) phosphotyrosine-binding domain, a DNA interaction domain, and a number of protein-protein interaction domains (with receptors, other transcription factors, the transcription machinery, and perhaps a tyrosine phosphatase). Mouse genetics experiments have defined crucial roles for each known mammalian STAT. The discovery of a STAT in Drosophila, and most recently in Dictyostelium discoideum, implies an ancient evolutionary origin for this dual-function set of proteins.

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Implications of RNA⋅RNA Splicing in Evolution of Eukaryotic Cells

Darnell

1978

Science

316

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The differences in the biochemistry of messenger RNA formation in eukaryotes compared to prokaryotes are so profound as to suggest that sequential prokaryotic to eukaryotic cell evolution seems unlikely. The recently discovered noncontiguous sequences in eukaryotic DNA that encode messenger RNA may reflect an ancient, rather than a new, distribution of information in DNA and that eukaryotes evolved independently of prokaryotes.

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Studies of IFN-Induced Transcriptional Activation Uncover the Jak-Stat Pathway

Darnell¹

1998

Journal of Interferon & Cytokine Research

157

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Sharing the Milstein Award with George R. Stark and Ian M. Kerr in the fall of 1997 brought this invitation to record personal reflections on our experiments concerning the mechanisms of action of interferon. Our work and that of the Kerr and Stark laboratories uncovered the Jak-Stat pathway through which signals from cell surface receptors reach genes in the cell nucleus. This review concentrates on that to which I can speak most reliably, that is, experiments done by my young colleagues at Rockefeller University.

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Reflections on the history of pre-mRNA processing and highlights of current knowledge: A unified picture

Darnell¹

2013

RNA

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Several strong conclusions emerge concerning pre-mRNA processing from both old and newer experiments. The RNAPII complex is involved with pre-mRNA processing through binding of processing proteins to the CTD (carboxyl terminal domain) of the largest RNAPII subunit. These interactions are necessary for efficient processing, but whether factor binding to the CTD and delivery to splicing sites is obligatory or facilitatory is unsettled. Capping, addition of an m 7 Gppp residue (cap) to the initial transcribed residue of a pre-mRNA, occurs within seconds. Splicing of pre-mRNA by spliceosomes at particular sites is most likely committed during transcription by the binding of initiating processing factors and ∼50% of the time is completed in mammalian cells before completion of the primary transcript. This fact has led to an outpouring in the literature about "cotranscriptional splicing." However splicing requires several minutes for completion and can take longer. The RNAPII complex moves through very long introns and also through regions dense with alternating exons and introns at an average rate of ∼3 kb per min and is, therefore, not likely detained at each splice site for more than a few seconds, if at all. Cleavage of the primary transcript at the 3 ′ end and polyadenylation occurs within 30 sec or less at recognized polyA sites, and the majority of newly polyadenylated pre-mRNA molecules are much larger than the average mRNA. Finally, it seems quite likely that the nascent RNA most often remains associated with the chromosomal locus being transcribed until processing is complete, possibly acquiring factors related to the transport of the new mRNA to the cytoplasm.

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Ribonucleic acids from animal cells

Darnell¹

1968

Bacteriol Rev

324

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