Craig R. Cook scite author profile

Mcm10 is a DNA replication factor that interacts with multiple subunits of the MCM2-7 hexameric complex. We report here that Mcm10 self-interacts and assembles into large homocomplexes (ϳ800 kDa). A conserved domain of 210 amino acid residues is sufficient for mediating self-interaction and complex assembly. A novel zinc finger within the conserved domain, CX 10 CX 11 CX 2 H, is essential for the homocomplex formation. Mutant alleles with amino acid substitutions at conserved cysteines and histidine in the zinc finger fail to assemble homocomplexes. A defect in homocomplex assembly correlates with defects in DNA replication and cell growth in the mutants. These observations suggest that homocomplex assembly is essential for Mcm10 function. Multisubunit Mcm10 homocomplexes may provide the structural basis for Mcm10 to interact with multiple subunits of the MCM2-7 hexamer.

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SR Protein and snRNP Requirements for Assembly of the Rous Sarcoma Virus Negative Regulator of Splicing Complexin Vitro

Cook

McNally

1998

Virology

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Retroviruses use unspliced RNA as mRNA for expression of virion structural proteins and as genomic RNA; the full-length RNA often constitutes the majority of the viral RNA in an infected cell. Maintenance of this large pool of unspliced RNA is crucial since even a modest increase in splicing efficiency can lead to impaired replication. In Rous sarcoma virus, the negative regulator of splicing (NRS) was identified as a cis element that negatively impacts splicing of viral RNA. Components of the splicing apparatus appear to be involved in splicing inhibition since binding of a number of splicing factors (snRNPs and SR proteins) and assembly of a large complex (NRS-C) in nuclear extracts correlate with NRS-mediated splicing inhibition. In determining the requirements for NRS complex assembly, we show that NRS-C assembly can be reconstituted by addition of total SR proteins to an S100 extract that lacks these factors. Of the purified SR proteins tested, SF2/ASF was functional in NRS-C assembly, whereas SC35 and SRp40 were not. The participation of snRNPs in NRS-C assembly was addressed by selectively depleting individual snRNPs with oligonucleotides and RNase H or by sequestering critical snRNA domains with 2'-O-methyl RNA oligonucleotides. The results indicate that in addition to U11 snRNP, U1 snRNP and SR proteins, but not U2 snRNP, are involved in NRS-C assembly.

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Role of JNK in network formation of human lung microvascular endothelial cells

Medhora

Dhanasekaran²,

Pratt³

et al. 2008

American Journal of Physiology-Lung Cellular and Molecular Phys

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The signaling mechanisms in vasculogenesis and/or angiogenesis remain poorly understood, limiting the ability to regulate growth of new blood vessels in vitro and in vivo. Cultured human lung microvascular endothelial cells align into tubular networks in the three-dimensional matrix, Matrigel. Overexpression of MAPK phosphatase-1 (MKP-1), an enzyme that inactivates the ERK, JNK, and p38 pathways, inhibited network formation of these cells. Adenoviral-mediated overexpression of recombinant MKP-3 (a dual specificity phosphatase that specifically inactivates the ERK pathway) and dominant negative or constitutively active MEK did not attenuate network formation in Matrigel compared with negative controls. This result suggested that the ERK pathway may not be essential for tube assembly, a conclusion which was supported by the action of specific MEK inhibitor PD 184352, which also did not alter network formation. Inhibition of the JNK pathway using SP-600125 or l-stereoisomer (l-JNKI-1) blocked network formation, whereas the p38 MAPK blocker SB-203580 slightly enhanced it. Inhibition of JNK also attenuated the number of small vessel branches in the developing chick chorioallantoic membrane. Our results demonstrate a specific role for the JNK pathway in network formation of human lung endothelial cells in vitro while confirming that it is essential for the formation of new vessels in vivo.

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Interaction between the Negative Regulator of Splicing Element and a 3′ Splice Site: Requirement for U1 Small Nuclear Ribonucleoprotein and the 3′ Splice Site Branch Point/Pyrimidine Tract

Cook

McNally

1999

J Virol

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The negative regulator of splicing (NRS) from Rous sarcoma virus suppresses viral RNA splicing and is one of several ciselements that account for the accumulation of large amounts of unspliced RNA for use as gag-pol mRNA and progeny virion genomic RNA. The NRS can also inhibit splicing of heterologous introns in vivo and in vitro. Previous data showed that the splicing factors SF2/ASF and U1, U2, and U11 small nuclear ribonucleoproteins (snRNPs) bind the NRS, and a correlation was established between SF2/ASF and U11 binding and activity, suggesting that these factors are important for function. These observations, and the finding that a large spliceosome-like complex (NRS-C) assembles on NRS RNA in nuclear extract, led to the proposal that the NRS is recognized as a minor-class 5′ splice site. One model to explain NRS splicing inhibition holds that the NRS interacts nonproductively with and sequesters U2-dependent 3′ splice sites. In this study, we provide evidence that the NRS interacts with an adenovirus 3′ splice site. The interaction was dependent on the integrity of the branch point and pyrimidine tract of the 3′ splice site, and it was sensitive to a mutation that was previously shown to abolish U11 snRNP binding and NRS function. However, further mutational analyses of NRS sequences have identified a U1 binding site that overlaps the U11 site, and the interaction with the 3′ splice site correlated with U1, not U11, binding. These results show that the NRS can interact with a 3′ splice site and suggest that U1 is of primary importance for NRS splicing inhibition.

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Characterization of an RNP Complex That Assembles on the Rous Sarcoma Virus Negative Regulator of Splicing Element

Cook

McNally

1996

Nucleic Acids Research

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We have characterized an RNP complex that assembles in nuclear extracts on the negative regulator of splicing (NRS) element from Rous sarcoma virus. While no complex was detected by native gel electrophoresis under conditions that supported spliceosome assembly, gel filtration revealed a specific ATP-independent complex that rapidly assembled on NRS RNA. No complexes were formed on non-specific RNA. Unlike the non-specific H complex, factors required for NRS complex assembly are limiting in nuclear extract. The NRS complex was not detected in reactions containing ATP and pre-formed complexes were dissociated in the presence of ATP. In addition, the assembly process was sensitive to high salt but NRS complexes were salt stable once formed. Assembly of the NRS complex appears functionally significant since mutated NRS RNAs that fail to inhibit splicing in vivo are defective for NRS complex assembly in nuclear extract. The probable relationship of the NRS complex to spliceosomal complexes is discussed.

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Craig R. Cook

A Novel Zinc Finger Is Required for Mcm10 Homocomplex Assembly

SR Protein and snRNP Requirements for Assembly of the Rous Sarcoma Virus Negative Regulator of Splicing Complexin Vitro

Role of JNK in network formation of human lung microvascular endothelial cells

Interaction between the Negative Regulator of Splicing Element and a 3′ Splice Site: Requirement for U1 Small Nuclear Ribonucleoprotein and the 3′ Splice Site Branch Point/Pyrimidine Tract

Characterization of an RNP Complex That Assembles on the Rous Sarcoma Virus Negative Regulator of Splicing Element

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