Antisense RNA mediates transcriptional processing in an archaebacterium, indicating a novel kind of RNase activity

Halovirus HF2 Intergenic Repeat Sequences Carry Promoters

Halovirus HF2 was the first member of the Haloferacalesvirus genus to have its genome fully sequenced, which revealed two classes of intergenic repeat (IR) sequences: class I repeats of 58 bp in length, and class II repeats of 29 bp in length. Both classes of repeat contain AT-rich motifs that were conjectured to represent promoters. In the present study, nine IRs were cloned upstream of the bgaH reporter gene, and all displayed promoter activity, providing experimental evidence for the previous conjecture. Comparative genomics showed that IR sequences and their relative genomic positions were strongly conserved among other members of the same virus genus. The transcription of HF2 was also examined by the reverse-transcriptase-PCR (RT-PCR) method, which demonstrated very long transcripts were produced that together covered most of the genome, and from both strands. The presence of long counter transcripts suggests a regulatory role or possibly unrecognized coding potential.

Complete Genome Sequence of the Model Halovirus PhiH1 (ΦH1)

The halophilic myohalovirus Halobacterium virus phiH (ΦH) was first described in 1982 and was isolated from a spontaneously lysed culture of Halobacterium salinarum strain R1. Until 1994, it was used extensively as a model to study the molecular genetics of haloarchaea, but only parts of the viral genome were sequenced during this period. Using Sanger sequencing combined with high-coverage Illumina sequencing, the full genome sequence of the major variant (phiH1) of this halovirus has been determined. The dsDNA genome is 58,072 bp in length and carries 97 protein-coding genes. We have integrated this information with the previously described transcription mapping data. PhiH could be classified into Myoviridae Type1, Cluster 4 based on capsid assembly and structural proteins (VIRFAM). The closest relative was Natrialba virus phiCh1 (φCh1), which shared 63% nucleotide identity and displayed a high level of gene synteny. This close relationship was supported by phylogenetic tree reconstructions. The complete sequence of this historically important virus will allow its inclusion in studies of comparative genomics and virus diversity.

Visualizing translocation dynamics and nascent transcript errors in paused RNA polymerases in vivo

BACKGROUND

Transcription elongation is frequently interrupted by pausing signals in DNA, with downstream effects on gene expression. Transcription errors also induce prolonged pausing, which can lead to a destabilized genome by interfering with DNA replication. Mechanisms of pausing associated with translocation blocks and misincorporation have been characterized in vitro, but not in vivo.

RESULTS

We investigate the pausing pattern of RNA polymerase (RNAP) in Escherichia coli by a novel approach, combining native elongating transcript sequencing (NET-seq) with RNase footprinting of the transcripts (RNET-seq). We reveal that the G-dC base pair at the 5' end of the RNA-DNA hybrid interferes with RNAP translocation. The distance between the 5' G-dC base pair and the 3' end of RNA fluctuates over a three-nucleotide width. Thus, the G-dC base pair can induce pausing in post-translocated, pre-translocated, and backtracked states of RNAP. Additionally, a CpG sequence of the template DNA strand spanning the active site of RNAP inhibits elongation and induces G-to-A errors, which leads to backtracking of RNAP. Gre factors efficiently proofread the errors and rescue the backtracked complexes. We also find that pausing events are enriched in the 5' untranslated region and antisense transcription of mRNA genes and are reduced in rRNA genes.

CONCLUSIONS

In E. coli, robust transcriptional pausing involves RNAP interaction with G-dC at the upstream end of the RNA-DNA hybrid, which interferes with translocation. CpG DNA sequences induce transcriptional pausing and G-to-A errors.

Viruses of haloarchaea

In hypersaline environments, haloarchaea (halophilic members of the Archaea) are the dominant organisms, and the viruses that infect them, haloarchaeoviruses are at least ten times more abundant. Since their discovery in 1974, described haloarchaeoviruses include head-tailed, pleomorphic, spherical and spindle-shaped morphologies, representing Myoviridae, Siphoviridae, Podoviridae, Pleolipoviridae, Sphaerolipoviridae and Fuselloviridae families. This review overviews current knowledge of haloarchaeoviruses, providing information about classification, morphotypes, macromolecules, life cycles, genetic manipulation and gene regulation, and host-virus responses. In so doing, the review incorporates knowledge from laboratory studies of isolated viruses, field-based studies of environmental samples, and both genomic and metagenomic analyses of haloarchaeoviruses. What emerges is that some haloarchaeoviruses possess unique morphological and life cycle properties, while others share features with other viruses (e.g., bacteriophages). Their interactions with hosts influence community structure and evolution of populations that exist in hypersaline environments as diverse as seawater evaporation ponds, to hot desert or Antarctic lakes. The discoveries of their wide-ranging and important roles in the ecology and evolution of hypersaline communities serves as a strong motivator for future investigations of both laboratory-model and environmental systems.

An Algorithm for Generating Small RNAs Capable of Epigenetically Modulating Transcriptional Gene Silencing and Activation in Human Cells

Small noncoding antisense RNAs (sasRNAs) guide epigenetic silencing complexes to target loci in human cells and modulate gene transcription. When these targeted loci are situated within a promoter, long-term, stable epigenetic silencing of transcription can occur. Recent studies suggest that there exists an endogenous form of such epigenetic regulation in human cells involving long noncoding RNAs. In this article, we present and validate an algorithm for the generation of highly effective sasRNAs that can mimic the endogenous noncoding RNAs involved in the epigenetic regulation of gene expression. We validate this algorithm by targeting several oncogenes including AKT-1, c-MYC, K-RAS, and H-RAS. We also target a long antisense RNA that mediates the epigenetic repression of the tumor suppressor gene DUSP6, silenced in pancreatic cancer. An algorithm that can efficiently design small noncoding RNAs for the epigenetic transcriptional silencing or activation of specific genes has potential therapeutic and experimental applications.

Antisense regulation by transposon-derived RNAs in the hyperthermophilic archaeon Sulfolobus solfataricus

This study provides evidence that transposon-derived antisense RNAs in the hyperthermophilic archaeon Sulfolobus solfataricus can regulate gene expression in trans.

We report the first example of antisense RNA regulation in a hyperthermophilic archaeon. In Sulfolobus solfataricus, the transposon-derived paralogous RNAs, RNA-257_1–4, show extended complementarity to the 3′ UTR of the 1183 mRNA, encoding a putative phosphate transporter. Phosphate limitation results in decreased RNA-257₁ and increased 1183 mRNA levels. Correspondingly, the 1183 mRNA is faster degraded in vitro upon duplex formation with RNA-257₁. Insertion of the 1183 3′ UTR downstream of the lacS gene results in strongly reduced lacS mRNA levels in transformed cells, indicating that antisense regulation can function in trans.

Transcriptional interference networks coordinate the expression of functionally related genes clustered in the same genomic loci

The regulation of gene expression is essential for normal functioning of biological systems in every form of life. Gene expression is primarily controlled at the level of transcription, especially at the phase of initiation. Non-coding RNAs are one of the major players at every level of genetic regulation, including the control of chromatin organization, transcription, various post-transcriptional processes, and translation. In this study, the Transcriptional Interference Network (TIN) hypothesis was put forward in an attempt to explain the global expression of antisense RNAs and the overall occurrence of tandem gene clusters in the genomes of various biological systems ranging from viruses to mammalian cells. The TIN hypothesis suggests the existence of a novel layer of genetic regulation, based on the interactions between the transcriptional machineries of neighboring genes at their overlapping regions, which are assumed to play a fundamental role in coordinating gene expression within a cluster of functionally linked genes. It is claimed that the transcriptional overlaps between adjacent genes are much more widespread in genomes than is thought today. The Waterfall model of the TIN hypothesis postulates a unidirectional effect of upstream genes on the transcription of downstream genes within a cluster of tandemly arrayed genes, while the Seesaw model proposes a mutual interdependence of gene expression between the oppositely oriented genes. The TIN represents an auto-regulatory system with an exquisitely timed and highly synchronized cascade of gene expression in functionally linked genes located in close physical proximity to each other. In this study, we focused on herpesviruses. The reason for this lies in the compressed nature of viral genes, which allows a tight regulation and an easier investigation of the transcriptional interactions between genes. However, I believe that the same or similar principles can be applied to cellular organisms too.

Regulation of an antisense RNA with the transition of neonatal to IIb myosin heavy chain during postnatal development and hypothyroidism in rat skeletal muscle

Postnatal development of fast skeletal muscle is characterized by a transition in expression of myosin heavy chain (MHC) isoforms, from primarily neonatal MHC at birth to primarily IIb MHC in adults, in a tightly coordinated manner. These isoforms are encoded by distinct genes, which are separated by ∼17 kb on rat chromosome 10. The neonatal-to-IIb MHC transition is inhibited by a hypothyroid state. We examined RNA products [mRNA, pre-mRNA, and natural antisense transcript (NAT)] of developmental and adult-expressed MHC genes (embryonic, neonatal, I, IIa, IIx, and IIb) at 2, 10, 20, and 40 days after birth in normal and thyroid-deficient rat neonates treated with propylthiouracil. We found that a long noncoding antisense-oriented RNA transcript, termed bII NAT, is transcribed from a site within the IIb-Neo intergenic region and across most of the IIb MHC gene. NATs have previously been shown to mediate transcriptional repression of sense-oriented counterparts. The bII NAT is transcriptionally regulated during postnatal development and in response to hypothyroidism. Evidence for a regulatory mechanism is suggested by an inverse relationship between IIb MHC and bII NAT in normal and hypothyroid-treated muscle. Neonatal MHC transcription is coordinately expressed with bII NAT. A comparative phylogenetic analysis also suggests that bII NAT-mediated regulation has been a conserved trait of placental mammals for most of the eutherian evolutionary history. The evidence in support of the regulatory model implicates long noncoding antisense RNA as a mechanism to coordinate the transition between neonatal and IIb MHC during postnatal development.

cis-antisense RNA, another level of gene regulation in bacteria

A substantial amount of antisense transcription is a hallmark of gene expression in eukaryotes. However, antisense transcription was first demonstrated in bacteria almost 50 years ago. The transcriptomes of bacteria as different as Helicobacter pylori, Bacillus subtilis, Escherichia coli, Synechocystis sp. strain PCC6803, Mycoplasma pneumoniae, Sinorhizobium meliloti, Geobacter sulfurreducens, Vibrio cholerae, Chlamydia trachomatis, Pseudomonas syringae, and Staphylococcus aureus have now been reported to contain antisense RNA (asRNA) transcripts for a high percentage of genes. Bacterial asRNAs share functional similarities with trans-acting regulatory RNAs, but in addition, they use their own distinct mechanisms. Among their confirmed functional roles are transcription termination, codegradation, control of translation, transcriptional interference, and enhanced stability of their respective target transcripts. Here, we review recent publications indicating that asRNAs occur as frequently in simple unicellular bacteria as they do in higher organisms, and we provide a comprehensive overview of the experimentally confirmed characteristics of asRNA actions and intimately linked quantitative aspects. Emerging functional data suggest that asRNAs in bacteria mediate a plethora of effects and are involved in far more processes than were previously anticipated. Thus, the functional impact of asRNAs should be considered when developing new strategies against pathogenic bacteria and when optimizing bacterial strains for biotechnology.

Long antisense non-coding RNAs and their role in transcription and oncogenesis

Long non-coding RNAs are estimated to qualitatively represent ~98% of expressed transcripts in human cells, a large proportion of which is antisense to protein-coding and non-coding transcripts. Here we review evidence from several experimental systems that suggests long antisense non-coding RNAs are involved in the transcriptional regulation of gene expression by altering epigenetic states at both adjacent and distal loci. We also review the initial evidence for a role of endogenous long antisense non-coding RNAs in oncogenic cellular transformation.

The transcription programme of the protein-primed halovirus SH1

SH1 is the only reported isolate of a spherical halovirus, a dominant morphotype in hypersaline lakes. The virus lytically infects the haloarchaeon Haloarcula hispanica, and carries a 30.9 kb linear dsDNA genome that, in a previous study, was proposed to contain 56 protein-coding genes, probably organized into between four and eight operons. In the present study, these predictions were directly tested by determining the orientations and lengths of virus transcripts using systematic RT-PCR and primer extension. Seven major transcripts were observed that together covered most of the genome. Six transcripts were synthesized from early in infection (1 h post-infection; p.i.) onwards, while transcript T6 was only detected late in infection (5-6 h p.i.). No transcripts were detected in the inverted terminal repeat sequences or at the extreme right end of the genome (ORFs 55-56). Start points for the major transcripts were mapped by primer extension and corresponded closely to the 5' termini determined by RT-PCR. Between 1 and 4 h p.i., transcripts usually terminated not far beyond the end of their last coding ORF, but late in infection, transcripts from the same promoters often terminated at more distal points, resulting in much of the genome being transcribed from both strands. Since many of these transcripts are complementary, RNA-RNA interactions are likely, and may play a role in regulating viral gene expression. Puromycin blockage of post-infection protein synthesis significantly altered the levels of certain virus transcripts, indicating that de novo protein synthesis is essential for the correct regulation of SH1 gene expression.

Induction and preliminary characterization of a novel halophage SNJ1 from lysogenic Natrinema sp. F5

Halophage SNJ1 was induced with mitomycin C from Natrinema sp. strain F5. The phage produces plaques on Natrinema sp. strain J7 only. The phage has a head of about 67 nm in diameter and a tail of 570 nm in length and belongs morphologically to the family Siphoviridae. The phage is strongly salt dependent; NaCl concentration affects the integrity of SNJ1, phage adsorption, and plaque formation. The optimal NaCl concentration for phage adsorption and plaque formation is 30% and 25%, respectively.

Virus-host interactions in salt lakes

Natural hypersaline waters are widely distributed around the globe, as both continental surface waters and sea floor lakes, the latter being maintained by the large density difference between the hypersaline and overlying marine water. Owing to the extreme salt concentrations, close to or at saturation (approximately 35%, w/v), such waters might be expected to be devoid of life but, in fact, maintain dense populations of microbes. The majority of these microorganisms are halophilic prokaryotes belonging to the Domain Archaea, 'haloarchaea'. Viruses infecting haloarchaea are a vital part of hypersaline ecosystems, in many circumstances outnumbering cells by 10-100-fold. However, few of these 'haloviruses' have been isolated and even fewer have been characterised in molecular detail. In this review, we explore the methods used by haloviruses to replicate within their hosts and consider the implications of haloviral-haloarchaeal interactions for salt lake ecology.

Antisense transcription in the human cytomegalovirus transcriptome

Human cytomegalovirus (HCMV) infections are prevalent in human populations and can cause serious diseases, especially in those with compromised or immature immune systems. The HCMV genome of 230 kb is among the largest of the herpesvirus genomes. Although the entire sequence of the laboratory-adapted AD169 strain of HCMV has been available for 18 years, the precise number of viral genes is still in question. We undertook an analysis of the HCMV transcriptome as an approach to enumerate and analyze the gene products of HCMV. Transcripts of HCMV-infected fibroblasts were isolated at different times after infection and used to generate cDNA libraries representing different temporal classes of viral genes. cDNA clones harboring viral sequences were selected and subjected to sequence analysis. Of the 604 clones analyzed, 45% were derived from genomic regions predicted to be noncoding. Additionally, at least 55% of the cDNA clones in this study were completely or partially antisense to known or predicted HCMV genes. The remarkable accumulation of antisense transcripts during infection suggests that currently available genomic maps based on open-reading-frame and other in silico analyses may drastically underestimate the true complexity of viral gene products. These findings also raise the possibility that aspects of both the HCMV life cycle and genome organization are influenced by antisense transcription. Correspondingly, virus-derived noncoding and antisense transcripts may shed light on HCMV pathogenesis and may represent a new class of targets for antiviral therapies.

The lysogenic region of virus φCh1: identification of a repressor-operator system and determination of its activity in halophilic Archaea

phiCh1 is a temperate virus infecting the haloalkaliphilic archaeon Natrialba magadii. As for all temperate viruses, a control of the lysogenic state versus the lytic life cycle is essential. Two open reading frames (ORFs) have been identified as putative repressor encoding genes: ORF48 and ORF49. The protein of ORF48 showed sequence similarities to putative repressor molecules. ORF49 was identified by the analysis of a mutant of phiCh1: the lysogenic strain carrying mutant phiCh1-1 showed a different lysis behavior than wild type virus phiCh1, indicating a dysfunction in the regulation of gene expression. Here, we show that the intergenic region between ORF48 and ORF49 comprises a promoter/operator sequence that is a transcriptionally active region in the model system Haloferax volcanii. Transcription from this region can be repressed by the activity of the ORF48 gene product. Gp43/gp44 has an enhancing effect on this regulatory sequence. Evidence is given for a possible binding site of Rep and gp43/gp44 within the coding region of the rep gene.

Evolutionary genomics of archaeal viruses: unique viral genomes in the third domain of life

In terms of virion morphology, the known viruses of archaea fall into two distinct classes: viruses of mesophilic and moderately thermophilic Eueryarchaeota closely resemble head-and-tail bacteriophages whereas viruses of hyperthermophilic Crenarchaeota show a variety of unique morphotypes. In accord with this distinction, the sequenced genomes of euryarchaeal viruses encode many proteins homologous to bacteriophage capsid proteins. In contrast, initial analysis of the crenarchaeal viral genomes revealed no relationships with bacteriophages and, generally, very few proteins with detectable homologs. Here we describe a re-analysis of the proteins encoded by archaeal viruses, with an emphasis on comparative genomics of the unique viruses of Crenarchaeota. Detailed examination of conserved domains and motifs uncovered a significant number of previously unnoticed homologous relationships among the proteins of crenarchaeal viruses and between viral proteins and those from cellular life forms and allowed functional predictions for some of these conserved genes. A small pool of genes is shared by overlapping subsets of crenarchaeal viruses, in a general analogy with the metagenome structure of bacteriophages. The proteins encoded by the genes belonging to this pool include predicted transcription regulators, ATPases implicated in viral DNA replication and packaging, enzymes of DNA precursor metabolism, RNA modification enzymes, and glycosylases. In addition, each of the crenarchaeal viruses encodes several proteins with prokaryotic but not viral homologs, some of which, predictably, seem to have been scavenged from the crenarchaeal hosts, but others might have been acquired from bacteria. We conclude that crenarchaeal viruses are, in general, evolutionarily unrelated to other known viruses and, probably, evolved via independent accretion of genes derived from the hosts and, through more complex routes of horizontal gene transfer, from other prokaryotes.

Over 20% of human transcripts might form sense-antisense pairs

The major challenge to identifying natural sense- antisense (SA) transcripts from public databases is how to determine the correct orientation for an expressed sequence, especially an expressed sequence tag sequence. In this study, we established a set of very stringent criteria to identify the correct orientation of each human transcript. We used these orientation-reliable transcripts to create 26 741 transcription clusters in the human genome. Our analysis shows that 22% (5880) of the human transcription clusters form SA pairs, higher than any previous estimates. Our orientation-specific RT-PCR results along with the comparison of experimental data from previous studies confirm that our SA data set is reliable. This study not only demonstrates that our criteria for the prediction of SA transcripts are efficient, but also provides additional convincing data to support the view that antisense transcription is quite pervasive in the human genome. In-depth analyses show that SA transcripts have some significant differences compared with other types of transcripts, with regard to chromosomal distribution and Gene Ontology-annotated categories of physiological roles, functions and spatial localizations of gene products.

Haloarchaeal viruses: how diverse are they?

Hypersaline lakes are highly productive microbial environments that provide many advantages for microbial ecologists, including stable communities of relatively low diversity (mainly haloarchaea). An important component of these communities is comprised of their non-cellular parasites, i.e., their viruses. Few viruses of halobacteria (haloviruses) have been isolated and studied even though a wide selection of host species have been formally described (and easily cultured) for ten years. Hypersaline waters have been shown to contain very high concentrations of virus-like particles (at least 10(7) particles/ml), particularly fusiform particles, but laboratory isolations of new haloviruses have been very slow and the detailed study of selected examples even slower. Here we provide an outline of the reported haloviruses, including fusiform and unpublished isolates from this laboratory, and we discuss their diversity and the future directions for this research.

Natrialba magadii virus phiCh1: first complete nucleotide sequence and functional organization of a virus infecting a haloalkaliphilic archaeon

The double-stranded (ds)DNA virus phiCh1 infects the haloalkaliphilic archaeon Natrialba magadii. The complete DNA sequence of 58 498 bp of the temperate virus was established, and the probable functions of 21 of 98 phiCh1-encoded open reading frames (ORFs) have been assigned. This knowledge has been used to propose functional modules each required for specific functions during virus development. The phiCh1 DNA is terminally redundant and circularly permuted and therefore appears to be packaged by the so-called headful mechanism. The presence of ORFs encoding homologues of proteins involved in plasmid replication as well as experimental evidence indicate a plasmid-mediated replication strategy of the virus. Results from nanosequencing of virion components suggest covalent cross-linking of monomers of at least one of the structural proteins during virus maturation. A comparison of the phiCh1 genome with the partly sequenced genome of Halobacterium salinarum virus phiH revealed a close relationship between the two viruses, although their host organisms live in distinct environments with respect to the different pH values required for growth.

The structural protein E of the archaeal virus phiCh1: evidence for processing in Natrialba magadii during virus maturation

phiCh1 is a lysogenic virus for the haloalkalophilic archaeon Natrialba magadii. The virus morphology resembles other members of Myoviridae infecting Halobacterium species. The gene of the major capsid protein E of virus phiCh1 was cloned and the DNA sequence was determined. Gene E was mapped to a 3.2-kbp ClaI fragment, localized to the 5'-end of the phiCh1 genome. The complete nucleotide sequence of this region was determined and the identity of gene E was confirmed by comparing the experimentally determined N-terminal amino acid sequence of the purified protein to the translated DNA sequence of its open reading frame. We present evidence that the gene E product is proteolytically cleaved between Lys(16) and Asn(17) to yield the 305 residue polypeptides found in the mature viral capsid. Processing of the protein itself during virus development was determined by 2D gel electrophoresis using protein E-specific antibodies. Sequence similarity studies revealed an 80% identity to capsid protein Hp32 of phiH, infecting Halobacterium salinarum. RT-PCR analysis as well as Western blot studies revealed gene E as a late gene. Transcripts and proteins could be detected shortly before onset of lysis of the lysogenic strain N. magadii L11.

The primary immunity determinant in modulating the lysogenic immunity of the filamentous bacteriophage cf

Bacteriophage cf is the first single-stranded DNA phage that has been shown to set up a stable lysogenic state with its genome integrated into the host chromosome. From the isolation and characterization of a virulent mutant, cf-tv2, we report the first investigation into the mechanisms of the immunity established by the filamentous bacteriophage. The mutation in cf-tv2 enables the phage to produce plaques on lawns of cf lysogenic cells. The mutation was defined as a 49-nucleotide deletion located in a 0.59 kb NcoI/KpnI fragment of cf replicative form DNA. Two messages, cM1 and cM2, transcribed from the immunity region of wild-type cf but in opposite directions, were detected. In cf-tv2, the 49-nucleotide deletion abolishes cM2 transcription. The primer extension assay suggests a possible RNA-RNA interaction directed by base-pairing of the cM1 and cM2 RNAs. A frameshift mutation of the open reading frame ORF 165, encoded by cM2, resulted in a 10(5) plating efficiency on the cf lysogen. These observations suggest that both RNA-RNA interaction and repressor protein inhibition are involved in the mechanism of cf immunity. A model is proposed for the regulation of cf immunity.

The DNA binding protein Tfx from Methanobacterium thermoautotrophicum: structure, DNA binding properties and transcriptional regulation

In Methanobacterium thermoautotrophicum, the fmdECB operon encoding the molybdenum formyl-methanofuran dehydrogenase is directly preceded by an open reading frame tfx predicted to encode a DNA binding protein. The 16.1 kDa protein has an N-terminal basic domain with a helix-turn-helix motif for DNA binding and a C-terminal acidic domain possibly for transcriptional activation. We report here on the DNA binding properties of the Tfx protein heterologously overproduced in Escherichia coli. Tfx was found to bind specifically to a DNA sequence downstream of the promoter of the fmdECB operon, as shown by electrophoretic mobility shift assays and DNase I footprint analysis. Northern blot hybridizations revealed that transcription of tfx is repressed during the growth of M. thermoautotrophicum in the presence of tung-state. Based on its structure and properties, the DNA binding protein Tfx is proposed to be a transcriptional regulator composed of a basic DNA binding domain and an acidic activation domain.

Do natural antisense transcripts make sense in eukaryotes?

The existence of naturally occurring antisense RNAs has been illustrated, in eukaryotes, by an increasing number of reports. The following review presents the major findings in this field, with a special focus on the regulation of gene expression exerted by endogenous complementary transcripts. A large variety of eukaryotic organisms, contains antisense transcripts. Moreover, the great diversity of genetic loci encoding overlapping sense and antisense RNAs suggests that such transcripts may be involved in numerous biological functions, such as control of development, adaptative response. viral infection. The regulation of gene expression by endogenous antisense RNAs seems of general importance in eukaryotes as already established in prokaryotes: it is likely to be involved in the control of various biological functions and to play a role in the development of pathological situations. Several experimental evidences for coupled, balanced or unbalanced expression of sense and antisense RNAs suggest that antisense transcripts may govern the expression of their sense counterparts. Furthermore, documented examples indicate that this control may be exerted at many levels of gene expression (transcription, maturation, transport, stability and translation). This review also addresses the underlying molecular mechanisms of antisense regulation and presents the current mechanistic hypotheses.

Identification and partial purification of human double strand RNase activity. A novel terminating mechanism for oligoribonucleotide antisense drugs

We have identified a double strand RNase (dsRNase) activity that can serve as a novel mechanism for chimeric antisense oligonucleotides comprised of 2'-methoxy 5' and 3' "wings" on either side of an oligoribonucleotide gap. Antisense molecules targeted to the point mutation in codon 12 of Harvey Ras (Ha-Ras) mRNA resulted in a dose-dependent reduction in Ha-Ras RNA. Reduction in Ha-Ras RNA was dependent on the oligoribonucleotide gap size with the minimum gap size being four nucleotides. An antisense oligonucleotide of the same composition, but containing four mismatches, was inactive. When chimeric antisense oligonucleotides were prehybridized with 17-mer oligoribonucleotides, extracts prepared from T24 cells, cytosol, and nuclei resulted in cleavage in the oligoribonucleotide gap. Both strands were cleaved. Neither mammalian nor Escherichia coli RNase HI cleaved the duplex, nor did single strand nucleases. The dsRNase activity resulted in cleavage products with 5'-phosphate and 3'-hydroxyl termini. Partial purification of dsRNase from rat liver cytosolic and nuclear fractions was effected. The cytosolic enzyme was purified approximately 165-fold. It has an approximate molecular weight of 50,000-65,000, a pH optimum of approximately 7.0, requires divalent cations, and is inactivated by approximately 300 mM NaCl. It is inactivated by heat, proteinase K, and also by a number of detergents and several organic solvents.

Regulation of gene expression by natural antisense RNA transcripts

The use of synthetic antisense oligonucleotides as specific inhibitors of gene expression exploits the susceptibility of mRNA to functional blockade at several levels, including mRNA processing, transport, translation and degradation. It is becoming increasingly apparent that the actions of these synthetic oligomers are analogous to those of endogenous RNA molecules involved in the regulation of gene expression in both prokaryotes and eukaryotes. A growing number of eukaryotic genes are now thought to be regulated at least in part by natural antisense RNA transcribed from the presumptive non-coding DNA strand. This possibility is supported by the presence of a complex system of double-stranded (ds) RNA-specific proteins and dsRNA-induced signal transduction pathways in eukaryotic cells. The presence of functional open reading frames in a number of recognized natural antisense RNA transcripts indicates that, in addition to regulating gene function at the RNA level, the antisense strand of many genes may code for as yet unidentified proteins. In the present study we review the current literature on the role(s) played by natural antisense RNA in eukaryotic cells, with an emphasis on genes for which clear evidence of regulation, or potential regulation by natural antisense RNA is available.

Protein-DNA interactions in the ori region of the Mycobacterium fortuitum plasmid pAL5000

Plasmid pAL5000 from Mycobacterium fortuitum encodes two proteins necessary for replication: RepA (307 amino acid residues) and RepB (119 residues). A single RNA species encoding these proteins was characterized, and its 5' end was defined. The proteins were expressed as maltose-binding protein fusions in Escherichia coli. The RepB protein was shown in vitro to bind specifically to a previously defined 435-bp region of pAL5000 containing the origin of replication (ori). The precise RepB binding sites were defined by DNase I footprinting experiments. RepB binds to two motifs in the ori region: a high-affinity site within its own promoter region, implying autoregulation of its expression, and a low-affinity site further upstream, presumably the origin of replication itself. The binding to the latter motif seems to occur on one DNA strand only. The high-affinity binding site contains several palindromic sequences. Gel retardation assays were performed with the different binding sites as templates, and the binding constant to each site was estimated from protein titrations. This is the first molecular dissection of mycobacterial DNA-binding proteins and their interactions with their targets.

Transcript analysis of the c-vac region and differential synthesis of the two regulatory gas vesicle proteins GvpD and GvpE in Halobacterium salinarium PHH4

Halobacterium salinarium PHH4 synthesizes gas vesicles in the stationary growth phase by the expression of 14 gyp genes arranged in two clusters. The chromosomal gvpACNO (c-gvpACNO) gene cluster (encoding the major structural gas vesicle protein GvpA and the minor structural protein GvpC was transcribed as three mRNA species starting at one promoter during the stationary phase of growth. The second gene cluster, c-gvpDEFGHIKLM), was transcribed during all stages of growth as a relatively unstable, single mRNA with a maximal length of 6 kb. In addition, a 1.7-kb c-gvpD transcript was synthesized during stationary growth starting at the same promotor as that of the cgvpDEFGHIJKLM mRNA. The expression of the first two genes located in this unit (c-gvpD and c-gvpE) was also monitored by Western blot (immunoblot) analyses using antisera raised against these proteins synthesized in Escherichia coli. While the cGvpD protein was present only during early exponential growth and disappeared during gas vesicle formation, the cGvpE protein was present during cGvpA and gas vesicle synthesis in the early stationary phase of growth. Previous data indicated that cGvpD is involved in repression of gas vesicle formation, whereas cGvpE is a transcriptional activator for the c-gvpA promoter. The appearance of both proteins during the growth cycle is in line with the functions of these proteins in gas vesicle synthesis. The mechanism of the differential translation of cGvpD and cGvpE from the c-gvpDEFGHIJKLM rnRNA still has to be elucidated, but antisense RNAs complementary to the 5' terminus as well as the 3' portion of the c-gvpD mRNA might be involved in this regulation. Such RNAs occurred during early stationary growth when the cGvpD protein level decreased and may possibly inhibit the translation of the c-gvpD mRNA.

Post-transcriptional controls in bacteriophage T4: roles of the sequence-specific endoribonuclease RegB

Gene regB of bacteriophage T4 encodes a sequence-specific endoribonuclease which introduces cuts in early phage messenger RNAs. In most cases, cutting takes place in the middle of the tetranucleotide GGAG. Efficient cleavages occur in the motifs located in intergenic regions, some of them being Shine-Dalgarno sequences. When located in a coding sequence, this tetranucleotide is poorly recognized or not at all. In this article, we have reviewed the properties of the RegB endoribonuclease, with emphasis on its possible roles in T4 development. We show that the nuclease RegB plays at least two roles: (i) it inactivates a sub-class of early mRNA by cleaving Shine-Dalgarno sequences, and (ii) it is necessary for the degradation of early mRNAs, but not of middle and late mRNAs. Accordingly, we found that middle and late mRNAs avoid processing by RegB, probably for different reasons. Most of the middle mRNAs (mRNAs initiated at MotA-dependent promoters) do not contain the motif GGAG in their intergenic regions, whereas about one-third of the late genes have this motif as Shine-Dalgarno sequence. It is not yet known whether the RNase is inactivated early in the phage cycle, or whether it remains active but cannot recognize late mRNAs as substrates.

Halophage HF2: genome organization and replication strategy

Halophage HF2 is a lytic, broad-host-range bacteriophage of the extremely halophilic domain Archaea. It has a 79.7-kb double-stranded DNA genome which is linear, contains no modified nucleotides, and is not susceptible to cleavage by many type II restriction endonucleases. This insensitivity is attributed to selection against palindromic restriction sites, a commonly observed feature of broad-host-range phages. Interestingly, enzymes that did cut the genome recognized AT-rich sites, and five such enzymes, DraI, AseI, HpaI, HindIII, and SspI, were used to construct a physical map of the genome. Southern hybridization experiments used to order fragments on the map indicated homologies between the phage termini, and subsequent sequence analysis showed that HF2 possessed 306-bp direct terminal repeats. The presence of such repeats suggested replication through concatameric intermediates, and this was confirmed by analysis of the state of the phage genome in infected cells. This is a replication strategy adopted by many well-studied bacterial phages, for example T3 and T7. Other similarities between the terminal repeats of T3 or T7 and HF2 include a putative nick site at the repeat border and a series of short imperfect repeats. These observations suggest a long evolutionary history for concatamer-based strategies of phage replication, possibly predating the divergence of Archaea/Eucarya and Bacteria, or alternatively, indicate possible lateral transfer of phage genes or modules between the domains Archaea and Bacteria.

Complementation studies with the gas vesicle-encoding p-vac region of Halobacterium salinarium PHH1 reveal a regulatory role for the p-gvpDE genes

Gas-vesicle (Vac) synthesis in Halobacterium salinarium PHH1 involves the expression of the p-vac region consisting of 14 different gvp genes that are arranged in two clusters: p-gvpACNO and, oppositely oriented, p-gvpDEFGHIJKLM. The latter cluster of genes is transcribed as two units: p-gvpDE and p-gvpF-M. The 5'-terminus of the p-gvpF-M mRNA was located 169 nucleotides upstream of p-gvpF within p-gvpE. The p-gvpG and p-gvpK gene was expressed in Escherichia coli and antibodies to proteins obtained were raised in rabbits. Both proteins could be detected in halobacterial cell lysates; in gas-vesicle preparations, however, neither GvpG nor GvpK could be found. The requirement for single p-gvp gene expression for gas-vesicle synthesis was determined by transformation experiments using the Vac- species Haloferax volcanii as recipient. Construct delta A containing all p-gvp genes except for p-gvpA, encoding the major gas-vesicle structural protein, produced Vac- transformants, but the addition of p-gvpA on a second vector restored gas-vesicle synthesis to wild-type level (Vac++). Similarly, double transformants containing p-gvpD-M plus p-gvpACNO, or p-gvpG-M (fused to the promoter of the halobacterial ferredoxin gene for expression) plus p-gvpFED-ACNO were Vac++. Transformants containing the p-vac region either lacking gvpA, gvpF, or gvpGHI were Vac-, indicating the absolute requirement of these gvp genes (or at least one in the case of gvpGHI) for gas-vesicle formation. Double transformants containing the constructs p-gvpF-M plus p-gvpACNO (delta DE) accumulated gas vesicles (Vac+) but synthesized fewer than the wild type, showing that the p-gvpDE genes are not necessary for gas-vesicle assembly. A repressor function affecting the synthesis of the p-gvpF-M mRNA could be suggested for p-gvpD and the 5'-region of its mRNA.

Genes for DNA cytosine methyltransferases and structural proteins, expressed during lytic growth by the phage phi H of the archaebacterium Halobacterium salinarium

Lytic genes and transcription from the Halobacterium salinarium phage phi H were studied. Genes for three structural proteins were located to the left arm of the linear phage genome. The right arm was shown to encode three DNA cytosine methyltransferases, the first such sequences reported from an archaebacterium. One cytosine methyltransferase is of the N(4)-methyltransferase type. The other two open reading frames (ORFs) seem to be parts of the same gene, which has been split by a recombination event. This gene product is of the C5-methyltransferase type. The methyltransferase genes are the first phi H genes detected showing high homology to eubacterial proteins. Five of the six described gene products have a higher proportion acidic over basic amino acid residues, a common characteristic of halobacterial proteins. Lytic phi H transcription was shown to produce three RNA species, two shorter species encoding the methyltransferase genes and one large species transcribed from both the right and the left phage arm and subsequently being processed upstream of the region encoding the structural proteins.

Transcription of the halophage phi H repressor gene is abolished by transcription from an inversely oriented lytic promoter

The temperate phage phi H of the extremely halophilic archaebacterium Halobacterium salinarium encodes a repressor, Rep, which in the immune state represses the production of an early lytic transcript, denoted T4. Rep acts at the transcriptional level by blocking the promoter for T4. The promoter for the rep gene itself is positioned back to back to the promoter for T4, in a manner analogous to that of the cI/cro genes in bacteriophage lambda. Transcription of the rep gene does not occur when the phase is growing lytically. We show that this repressor of rep transcription during lytic growth is due to the transcription per se from the stronger, oppositely oriented promoter for T4, without the need of a phage gene product.

Structure specific ds/ss-RNase activity in the extreme halophile Halobacterium salinarium

A ds/ss-RNA processing activity involved in antisense-RNA mediated gene regulation in the extremely halophilic archaebacterium Halobacterium salinarium was investigated in vivo. H.salinarium cells were transformed with DNA encoding an RNA species complementary to a part of the major lytic transcript, termed T4, of the H.salinarium phage phi H. The transformants transcribing this construct, when infected by phage were able to process T4 in a similar way to the processing of the lytic transcript denoted T1, in the natural sense-antisense system. Processing of T4 was not observed under normal phage growth on wild-type cells. Thus the antisense-RNA mediated processing activity earlier reported is dependent on the presence of an RNA duplex and is not sequence specific.

What makes an mRNA anti-sense-itive?

Antisense RNA has been used for some time as a versatile tool for silencing gene expression. There is ample evidence for gene regulation by endogenous antisense transcripts in prokaryotes and increasing insight into the molecular mechanisms underlying such regulation. The introduction of antisense gene constructs into eukaryotes has now become routine but the mechanisms by which gene expression is inhibited are barely understood. In recent years, several examples of endogenous eukaryotic antisense transcripts have been discovered, some of which probably serve regulatory functions. Here we will discuss a model to explain mechanisms of antisense-mediated gene silencing.