Charles N. Cole

Altered MicroRNA Expression Confined to Specific Epithelial Cell Subpopulations in Breast Cancer

MicroRNAs (miRNAs) are a new class of short noncoding regulatory RNAs (18-25 nucleotides) that are involved in diverse developmental and pathologic processes. Altered miRNA expression has been associated with several types of human cancer. However, most studies did not establish whether miRNA expression changes occurred within cells undergoing malignant transformation. To obtain insight into miRNA deregulation in breast cancer, we implemented an in situ hybridization (ISH) method to reveal the spatial distribution of miRNA expression in archived formalin-fixed, paraffin-embedded specimens representing normal and tumor tissue from >100 patient cases. Here, we report that expression of miR-145 and miR-205 was restricted to the myoepithelial/basal cell compartment of normal mammary ducts and lobules, whereas their accumulation was reduced or completely eliminated in matching tumor specimens. Conversely, expression of other miRNAs was detected at varying levels predominantly within luminal epithelial cells in normal tissue; expression of miR-21 was frequently increased, whereas that of let-7a was decreased in malignant cells. We also analyzed the association of miRNA expression with that of epithelial markers; prognostic indicators such as estrogen receptor, progesterone receptor, and HER2; as well as clinical outcome data. This ISH approach provides a more direct and informative assessment of how altered miRNA expression contributes to breast carcinogenesis compared with miRNA expression profiling in gross tissue biopsies. Most significantly, early manifestation of altered miR-145 expression in atypical hyperplasia and carcinoma in situ lesions suggests that this miRNA may have a potential clinical application as a novel biomarker for early detection.

Dbp5p/Rat8p is a yeast nuclear pore-associated DEAD-box protein essential for RNA export.

To identify Saccharomyces cerevisiae genes important for nucleocytoplasmic export of messenger RNA, we screened mutant strains to identify those in which poly(A)+ RNA accumulated in nuclei under nonpermissive conditions. We describe the identification of DBP5 as the gene defective in the strain carrying the rat8‐1 allele (RAT = ribonucleic acid trafficking). Dbp5p/Rat8p, a previously uncharacterized member of the DEAD‐box family of proteins, is closely related to eukaryotic initiation factor 4A(eIF4A) an RNA helicase essential for protein synthesis initiation. Analysis of protein databases suggests most eukaryotic genomes encode a DEAD‐box protein that is probably a homolog of yeast Dbp5p/Rat8p. Temperature‐sensitive alleles of DBP5/RAT8 were prepared. In rat8 mutant strains, cells displayed rapid, synchronous accumulation of poly(A)+ RNA in nuclei when shifted to the non‐permissive temperature. Dbp5p/Rat8p is located within the cytoplasm and concentrated in the perinuclear region. Analysis of the distribution of Dbp5p/Rat8p in yeast strains where nuclear pore complexes are tightly clustered indicated that a fraction of this protein associates with nuclear pore complexes (NPCs). The strong mutant phenotype, association of the protein with NPCs and genetic interaction with factors involved in RNA export provide strong evidence that Dbp5p/Rat8p plays a direct role in RNA export.

Rat8p/Dbp5p is a shuttling transport factor that interacts with Rat7p/Nup159p and Gle1p and suppresses the mRNA export defect of xpo1-1 cells.

In a screen for temperature‐sensitive mutants of Saccharomyces cerevisiae defective for mRNA export, we previously identified the essential DEAD‐box protein Dbp5p/Rat8p and the nucleoporin Rat7p/Nup159p. Both are essential for mRNA export. Here we report that Dbp5p and Rat7p interact through their Nterminal domains. Deletion of this portion of Rat7p (Rat7pΔN) results in strong defects in mRNA export and eliminates association of Dbp5p with nuclear pores. Overexpression of Dbp5p completely suppressed the growth and mRNA export defects of rat7ΔN cells and resulted in weaker suppression in cells carrying rat7‐1 or the rss1‐37 allele of GLE1. Dbp5p interacts with Gle1p independently of the N‐terminus of Dbp5p. Dbp5p shuttles between nucleus and cytoplasm in an Xpo1p‐dependent manner. It accumulates in nuclei of xpo1‐1 cells and in cells with mutations affecting Mex67p (mex67‐5), Gsp1p (Ran) or Ran effectors. Overexpression of Dbp5p prevents nuclear accumulation of mRNA in xpo1‐1 cells, but does not restore growth, suggesting that the RNA export defect of xpo1‐1 cells may be indirect. In a screen for high‐copy suppressors of the rat8‐2 allele of DBP5, we identified YMR255w, now called GFD1. Gfd1p is not essential, interacts with Gle1p and Rip1p/Nup42p, and is found in the cytoplasm and at the nuclear rim.

Uncovering Growth-Suppressive MicroRNAs in Lung Cancer

Purpose: MicroRNA (miRNA) expression profiles improve classification, diagnosis, and prognostic information of malignancies, including lung cancer. This study uncovered unique growth-suppressive miRNAs in lung cancer. Experimental Design: miRNA arrays were done on normal lung tissues and adenocarcinomas from wild-type and proteasome degradation-resistant cyclin E transgenic mice to reveal repressed miRNAs in lung cancer. Real-time and semiquantitative reverse transcription-PCR as well as in situ hybridization assays validated these findings. Lung cancer cell lines were derived from each transgenic line (designated as ED-1 and ED-2 cells, respectively). Each highlighted miRNA was independently transfected into these cells. Growth-suppressive mechanisms were explored. Expression of a computationally predicted miRNA target was examined. These miRNAs were studied in a paired normal-malignant human lung tissue bank. Results: miR-34c, miR-145, and miR-142-5p were repressed in transgenic lung cancers. Findings were confirmed by real-time and semiquantitative reverse transcription-PCR as well as in situ hybridization assays. Similar miRNA profiles occurred in human normal versus malignant lung tissues. Individual overexpression of miR-34c, miR-145, and miR-142-5p in ED-1 and ED-2 cells markedly repressed cell growth. Anti-miR cotransfections antagonized this inhibition. The miR-34c target, cyclin E, was repressed by miR-34c transfection and provided a mechanism for observed growth suppression. Conclusions: miR-34c, miR-145, and miR-142-5p were repressed in murine and human lung cancers. Transfection of each miRNA significantly repressed lung cancer cell growth. Thus, these miRNAs were growth suppressive and are proposed to exert antineoplastic effects in the lung.

Coupling of Termination, 3 Processing, and mRNA Export

ABSTRACT In a screen to identify genes required for mRNA export in Saccharomyces cerevisiae, we isolated an allele of poly(A) polymerase (PAP1) and novel alleles encoding several other 3′ processing factors. Many newly isolated and some previously described mutants (rna14-48, rna14-49, rna14-64, rna15-58, and pcf11-1 strains) are defective in polymerase II (Pol II) termination but, interestingly, retain the ability to polyadenylate these improperly processed transcripts at the nonpermissive temperature. Deletion of the cis-acting sequences required to couple 3′ processing and termination also produces transcripts that fail to exit the nucleus, suggesting that all of these processes (cleavage, termination, and export) are coupled. We also find that several but not all mRNA export mutants produce improperly 3′ processed transcripts at the nonpermissive temperature. 3′ maturation defects in mRNA export mutants include improper Pol II termination and/or the previously characterized hyperpolyadenylation of transcripts. Importantly, not all mRNA export mutants have defects in 3′ processing. The similarity of the phenotypes of some mRNA export mutants and 3′ processing mutants indicates that some factors from each process may mechanistically interact to couple mRNA processing and export. Consistent with this assumption, we present evidence that Xpo1p interacts in vivo with several 3′ processing factors and that the addition of recombinant Xpo1p to in vitro processing reaction mixtures stimulates 3′ maturation. Of the core 3′ processing factors tested (Rna14p, Rna15p, Pcf11p, Hrp1p, Fip1p, and Cft1p), only Hrp1p shuttles. Overexpression of Rat8p/Dbp5p suppresses both 3′ processing and mRNA export defects found in xpo1-1 cells.

Nuclear PRP20 protein is required for mRNA export.

The yeast PRP20 protein is highly homologous in structure and function to the RCC1 protein of higher eukaryotes. The RCC1 protein is involved in the regulation of the onset of mitosis, whereas the PRP20 protein was shown to be required for accurate and efficient mRNA metabolism. The first observable phenotype in mutant prp20 cells when shifted from permissive to non‐permissive temperature is a loss of nuclear PRP20 protein. Concomitantly, an accumulation of poly(A)+ RNA in the nucleus is observed. The temperature‐sensitive RCC1 allele in the mutant hamster cell line tsBN2 leads to a similar accumulation of mRNA in the nucleus.

Defective interfering particles of poliovirus: II. Nature of the defect

Abstract Poliovirus defective, interfering particles in which about 15% of the standard viral RNA is deleted have been described (Cole et al. , 1971). Stocks of DI ‡ particles more than 99% free of standard poliovirus were prepared by centrifugation of mixed preparations in CsCl gradients. Using purified DI particles, it was found that DI particles can carry out most of the standard poliovirus functions including inhibition of cellular macromolecular synthesis, production of viral RNA and production of virus-specific protein. Neither the kinetics nor extent of viral RNA or protein synthesis differed between DI particle-infected cells and standard virus-infected cells. Newly made virions, capsid proteins, and the capsid protein precursor (NCVP 1) were totally absent in DI particle-infected cells. All of the other viral proteins were present. DI-infected cells briefly labeled with amino acids also contained a new polypeptide, DI-P, which was apparently the residual fragment of NCVP 1 encoded by the DI genome. It was very unstable, being rapidly degraded to acid-soluble fragments. When the cleavage of viral proteins was inhibited with amino acid analogs, precursors of the viral proteins were generated. Those precursors which should have contained NCVP 1 had molecular weights 30,000 to 40,000 daltons lower in DI-infected cells than in standard virus-infected cells. This is the amount of protein encoded by 15% of the standard poliovirus genome which is the per cent of the standard RNA sequence not represented in DI RNA. Poliovirus DI particles therefore appear to be deletion mutants lacking RNA encoding about one-third of the capsid protein precursor. Whether the deletion is internal or terminal remains to be determined.

Gas1-induced growth suppression requires a transactivation-independent p53 function.

In normal cells, induction of quiescence is accompanied by the increased expression of growth arrest-specific genes (gas). One of them, gas1, is regulated at the transcriptional level and codes for a membrane-associated protein (Gas1) which is down regulated during the G0-to-S phase transition in serum-stimulated cells. Gas1 is not expressed in growing or transformed cells, and when overexpressed in normal fibroblasts, it blocks the G0-to-S phase transition. Moreover, Gas1 blocks cell proliferation in several transformed cells with the exception of simian virus 40- or adenovirus-transformed cell lines. In this paper, we demonstrate that overexpression of Gas1 blocks cell proliferation in a p53-dependent manner and that the N-terminal domain-dependent transactivating function of p53 is dispensable for Gas1-induced growth arrest. These data therefore indicate that the other intrinsic transactivation-independent functions of p53, possibly related to regulation of apoptosis, should be involved in mediating Gas1-induced growth arrest.

Nucleocytoplasmic transport: Driving and directing transport

Nucleocytoplasmic transport involves assembly and movement across the nuclear envelope of cargo-receptor complexes that interact with the small GTPase Ran. The asymmetric distribution of Ran regulator proteins, RanGAP1 and RCC1, provides the driving force and directionality for nuclear transport.

Phylogenetic distribution of microRNAs supports the basal position of acoel flatworms and the polyphyly of Platyhelminthes

SUMMARY Phylogenetic analyses based on gene sequences suggest that acoel flatworms are not members of the phylum Platyhelminthes, but instead are the most basal branch of triploblastic bilaterians. Nonetheless, this result has been called into question. An alternative test is to use qualitative molecular markers that should, in principle, exclude the possibility of convergent (homoplastic) evolution in unrelated groups. microRNAs (miRNAs), noncoding regulatory RNA molecules that are under intense stabilizing selection, are a newly discovered set of phylogenetic markers that can resolve such taxonomic disputes. The acoel Childia sp. has recently been shown to possess a subset of the conserved core of miRNAs found across deuterostomes and protostomes, whereas a polyclad flatworm—in addition to this core subset—possesses miRNAs restricted to just protostomes. Here, we examine another acoel, Symsagittifera roscoffensis, and three other platyhelminths. Our results show that the distribution of miRNAs in S. roscoffensis parallels that of Childia. In addition, two of 13 new miRNAs cloned from a triclad flatworm are also found in other lophotrochozoan protostomes, but not in ecdysozoans, deuterostomes, or in basal metazoans including acoels. The limited set of miRNAs found in acoels, intermediate between the even more reduced set in cnidarians and the larger and expanding set in the rest of bilaterians, is compelling evidence for the basal position of acoel flatworms and the polyphyly of Platyhelminthes.