Cancer: the chromatin connection

The American Association for Cancer Research's 93rd Annual Meeting was held in San Francisco, California, USA, from 6 to 10 April 2002.     

The two faces of Alba: the evolutionary connection between proteins participating in chromatin structure and RNA metabolism

Background  

There is considerable heterogeneity in the phyletic patterns of major chromosomal DNA-binding proteins in archaea. Alba is a well-characterized chromosomal protein from the crenarchaeal genus Sulfolobus. While Alba has been detected in most archaea and some eukaryotic taxa, its exact functions in these taxa are not clear. Here we use comparative genomics and sequence profile analysis to predict potential alternative functions of the Alba proteins.     

A short phosphodiester window is sufficient to direct RNase H-dependent RNA cleavage by antisense peptide nucleic acid

The potential pharmacologic benefits of using peptide nucleic acid (PNA) as an antisense agent are tempered by its incapacity to activate RNase H. The mixed backbone oligonucleotide (ON) (or gapmer) approach, in which a short internal window of RNAse H-competent residues is embedded within an RNase H-incompetent ON has not been applied previously to PNA because PNA and DNA hybridize to RNA with very different helical structures, creating structural perturbations at the two PNA-DNA junctions. It is demonstrated here for the first time that a short internal phosphodiester window within a PNA is sufficient to evoke the RNase H-dependent cleavage of a targeted RNA and to abrogate translation elongation in a well-characterized in vitro assay.     

The effect of loop size in antisense and target RNAs on the efficiency of antisense RNA control.

Most natural antisense RNAs display a high degree of secondary structure with stem-loops as their most prominent feature. Mutations affecting the inhibitory activity of these RNAs most often map in or close to loop regions in both the antisense and target RNAs. The primary recognition loops often contain 5-7 unpaired nucleotides. Nucleotide changes in the loops affect the binding rate and, hence, the inhibitory effect on the activity of the target RNA. Here we address the question whether loop sizes affect binding rates between antisense and target RNAs, using the replication control system of plasmid R1 as a model system. By creating a series of loop size mutants we show that loop size alterations have strong effects on the binding rates between the two reactant RNAs in vitro, and that most of the mutations analyzed display corresponding effects on antisense RNA control in vivo. Our data suggest that the three-dimensional structures of antisense and target RNA stem-loops are crucial for determining binding rates. The implications of these results for the design of efficient artificial antisense RNA control systems are discussed.     

Retrovirus RNA trafficking: from chromatin to invasive genomes

Full-length retroviral RNA has three well-established functions: it constitutes the genomic RNA that is packaged into virions and is transmitted to target cells by infection, it is the messenger RNA (mRNA) template for viral Gag and Pol protein synthesis and it serves as the pre-mRNA for the production of subgenomic spliced mRNAs that encode additional viral proteins such as Env. More recent work indicates that these full-length RNAs also play important roles in the assembly of virus particles, not only as a structural scaffold that facilitates viral core formation but also as a potential regulator of the assembly process itself. Here, we discuss how these assorted activities may be coupled with each other, paying particular attention to the importance of RNA trafficking and subcellular localization in the cytoplasm, possible points of regulation, and the role(s) played by cellular RNA-binding proteins.     

The connection between ribophagy, autophagy and ribosomal RNA decay

Ribosomes are essential components of all cells. A large body of knowledge has been accumulated regarding ribosome synthesis and assembly; however, the pathways of normal ribosome turnover, especially rRNA decay, are not known. Some information on ribosome recycling derives from studies on starved yeast cells that use a specialized type of autophagy, called ribophagy, to differentially target ribosomes for degradation. We found that Arabidopsis RNS2, a conserved ribonuclease of the RNase T2 family, is necessary for normal decay of rRNA. Mutants lacking RNS2 activity have longer-lived rRNA, accumulate RNA in the vacuole and show constitutive macroautophagy. Thus, it is clear that normal rRNA decay is necessary to maintain cellular homeostasis. These phenotypes and the subcellular localization of RNS2 in the endoplasmic reticulum and the vacuole suggest that RNS2 participates in a ribophagy-like mechanism that targets ribosomes for recycling under normal growth conditions.     

The connection between ribophagy,autophagy and ribosomal RNA decay

Ribosomes are essential components of all cells. A large body of knowledge has been accumulated regarding ribosome synthesis and assembly; however, the pathways of normal ribosome turnover, especially rRNA decay, are not known. Some information on ribosome recycling derives from studies on starved yeast cells that use a specialized type of autophagy, called ribophagy, to differentially target ribosomes for degradation. We found that Arabidopsis RNS2, a conserved ribonuclease of the RNase T2 family, is necessary for normal decay of rRNA. Mutants lacking RNS2 activity have longer-lived rRNA, accumulate RNA in the vacuole and show constitutive macroautophagy. Thus, it is clear that normal rRNA decay is necessary to maintain cellular homeostasis. These phenotypes and the subcellular localization of RNS2 in the endoplasmic reticulum and the vacuole suggest that RNS2 participates in a ribophagy-like mechanism that targets ribosomes for recycling under normal growth conditions.     

Programmable control of bacterial gene expression with the combined CRISPR and antisense RNA system

A central goal of synthetic biology is to implement diverse cellular functions by predictably controlling gene expression. Though research has focused more on protein regulators than RNA regulators, recent advances in our understanding of RNA folding and functions have motivated the use of RNA regulators. RNA regulators provide an advantage because they are easier to design and engineer than protein regulators, potentially have a lower burden on the cell and are highly orthogonal. Here, we combine the CRISPR system from Streptococcus pyogenes and synthetic antisense RNAs (asRNAs) in Escherichia coli strains to repress or derepress a target gene in a programmable manner. Specifically, we demonstrate for the first time that the gene target repressed by the CRISPR system can be derepressed by expressing an asRNA that sequesters a small guide RNA (sgRNA). Furthermore, we demonstrate that tunable levels of derepression can be achieved (up to 95%) by designing asRNAs that target different regions of a sgRNA and by altering the hybridization free energy of the sgRNA–asRNA complex. This new system, which we call the combined CRISPR and asRNA system, can be used to reversibly repress or derepress multiple target genes simultaneously, allowing for rational reprogramming of cellular functions.     

Copy number control of IncIalpha plasmid ColIb-P9 by competition between pseudoknot formation and antisense RNA binding at a specific RNA site.

Replication of a low-copy-number IncIalpha plasmid ColIb-P9 depends on expression of the repZ gene encoding the replication initiator protein. repZ expression is negatively controlled by the small antisense Inc RNA, and requires formation of a pseudoknot in the RepZ mRNA consisting of stem-loop I, the Inc RNA target, and a downstream sequence complementary to the loop I. The loop I sequence comprises 5'-rUUGGCG-3', conserved in many prokaryotic antisense systems, and was proposed to be the important site of copy number control. Here we show that the level of repZ expression is rate-limiting for replication and thus copy number, by comparing the levels of repZ expression and copy number from different mutant ColIb-P9 derivatives defective in Inc RNA and pseudoknot formation. Kinetic analyses using in vitro transcribed RNAs indicate that Inc RNA binding and the pseudoknot formation are competitive at the level of initial base paring to loop I. This initial interaction is stimulated by the presence of the loop U residue in the 5'-rUUGGCG-3' motif. These results indicate that the competition between the two RNA-RNA interactions at the specific site is a novel regulatory mechanism for establishing the constant level of repZ expression and thus copy number.     

Translational control: the cancer connection

There is now a growing body of evidence which suggests links between the regulation of protein synthesis and the disruption of cell behaviour that typifies cancer. This directed issue of the International Journal of Biochemistry and Cell Biology presents several review articles of relevance to this field. The topics covered include the significance of the regulation and overexpression of polypeptide chain initiation factors for cell transformation and malignancy, the role of mRNA structure in the control of synthesis of key growth regulatory proteins, the actions of the eIF2 alpha-specific protein kinase PKR in the control cell growth and apoptosis, and the involvement of the elongation factor eEF1 in oncogenesis. The purpose of this article is to give an overview of the field and to indicate where we may expect developments to occur in the next few years.