Germ-line transformation via transposable elements is a powerful tool to study gene function in Drosophila melanogaster. However, some inherent characteristics of transposon-mediated transgenesis limit its use for transgene analysis. Here, we circumvent these limitations by optimizing a phiC31-based integration system. We generated a collection of lines with precisely mapped attP sites that allow the insertion of transgenes into many different predetermined intergenic locations throughout the fly genome. By using regulatory elements of the nanos and vasa genes, we established endogenous sources of the phiC31 integrase, eliminating the difficulties of coinjecting integrase mRNA and raising the transformation efficiency. Moreover, to discriminate between specific and rare nonspecific integration events, a white gene-based reconstitution system was generated that enables visual selection for precise attP targeting. Finally, we demonstrate that our chromosomal attP sites can be modified in situ, extending their scope while retaining their properties as landing sites. The efficiency, ease-of-use, and versatility obtained here with the phiC31-based integration system represents an important advance in transgenesis and opens up the possibility of systematic, high-throughput screening of large cDNA sets and regulatory elements.

https://www.pnas.org/content/pnas/104/9/3312.full.pdf

An optimized transgenesis system for Drosophila using germ-line-specific φC31 integrases

The finding that total viral abundance is higher than total prokaryotic abundance and that a significant fraction of the prokaryotic community is infected with phages in aquatic systems has stimulated research on the ecology of prokaryotic viruses and their role in ecosystems. This review treats the ecology of prokaryotic viruses ('phages') in marine, freshwater and soil systems from a 'virus point of view'. The abundance of viruses varies strongly in different environments and is related to bacterial abundance or activity suggesting that the majority of the viruses found in the environment are typically phages. Data on phage diversity are sparse but indicate that phages are extremely diverse in natural systems. Lytic phages are predators of prokaryotes, whereas lysogenic and chronic infections represent a parasitic interaction. Some forms of lysogeny might be described best as mutualism. The little existing ecological data on phage populations indicate a large variety of environmental niches and survival strategies. The host cell is the main resource for phages and the resource quality, i.e., the metabolic state of the host cell, is a critical factor in all steps of the phage life cycle. Virus-induced mortality of prokaryotes varies strongly on a temporal and spatial scale and shows that phages can be important predators of bacterioplankton. This mortality and the release of cell lysis products into the environment can strongly influence microbial food web processes and biogeochemical cycles. Phages can also affect host diversity, e.g., by 'killing the winner' and keeping in check competitively dominant species or populations. Moreover, they mediate gene transfer between prokaryotes, but this remains largely unknown in the environment. Genomics or proteomics are providing us now with powerful tools in phage ecology, but final testing will have to be performed in the environment.

Ecology of prokaryotic viruses

Summary: Actinobacteria constitute one of the largest phyla among Bacteria and represent gram-positive bacteria with a high G+C content in their DNA. This bacterial group includes microorganisms exhibiting a wide spectrum of morphologies, from coccoid to fragmenting hyphal forms, as well as possessing highly variable physiological and metabolic properties. Furthermore, Actinobacteria members have adopted different lifestyles, and can be pathogens (e.g., Corynebacterium, Mycobacterium, Nocardia, Tropheryma, and Propionibacterium), soil inhabitants (Streptomyces), plant commensals (Leifsonia), or gastrointestinal commensals (Bifidobacterium). The divergence of Actinobacteria from other bacteria is ancient, making it impossible to identify the phylogenetically closest bacterial group to Actinobacteria. Genome sequence analysis has revolutionized every aspect of bacterial biology by enhancing the understanding of the genetics, physiology, and evolutionary development of bacteria. Various actinobacterial genomes have been sequenced, revealing a wide genomic heterogeneity probably as a reflection of their biodiversity. This review provides an account of the recent explosion of actinobacterial genomics data and an attempt to place this in a biological and evolutionary context.

Genomics of Actinobacteria: Tracing the Evolutionary History of an Ancient Phylum

Epigraph
There is something fascinating about science. One gets such wholesale returns of conjecture out of such a trifling investment of fact.

Mark Twain 1883 
Life on the Mississippi

Summary Bacterial genome nucleotide sequences are being completed at a rapid and increasing rate. Integrated virus genomes (prophages) are common in such genomes. Fifty-one of the 82 such genomes published to date carry prophages, and these contain 230 recognizable putative prophages. Prophages can constitute as much as 10–20% of a bacterium's genome and are major contributors to differences between individuals within species. Many of these prophages appear to be defective and are in a state of mutational decay. Prophages, including defective ones, can contribute important biological properties to their bacterial hosts. Therefore, if we are to comprehend bacterial genomes fully, it is essential that we are able to recognize accurately and understand their prophages from nucleotide sequence analysis. Analysis of the evolution of prophages can shed light on the evolution of both bacteriophages and their hosts. Comparison of the Rac prophages in the sequenced genomes of three Escherichia coli strains and the Pnm prophages in two Neisseria meningitidis strains suggests that some prophages can lie in residence for very long times, perhaps millions of years, and that recombination events have occurred between related prophages that reside at different locations in a bacterium's genome. In addition, many genes in defective prophages remain functional, so a significant portion of the temperate bacteriophage gene pool resides in prophages.

https://onlinelibrary.wiley.com/doi/pdf/10.1046/j.1365-2958.2003.03580.x

Prophages and bacterial genomics: what have we learned so far?

Integration, excision, and inversion of defined DNA segments commonly occur through site-specific recombination, a process of DNA breakage and reunion that requires no DNA synthesis or high-energy cofactor. Virtually all identified site-specific recombinases fall into one of just two families, the tyrosine recombinases and the serine recombinases, named after the amino acid residue that forms a covalent protein-DNA linkage in the reaction intermediate. Their recombination mechanisms are distinctly different. Tyrosine recombinases break and rejoin single strands in pairs to form a Holliday junction intermediate. By contrast, serine recombinases cut all strands in advance of strand exchange and religation. Many natural systems of site-specific recombination impose sophisticated regulatory mechanisms on the basic recombinational process to favor one particular outcome of recombination over another (for example, excision over inversion or deletion). Details of the site-specific recombination processes...

pdf/mechanisms-of-site-specific-recombination-p82pr0exg7.pdf

Mechanisms of Site-Specific Recombination*

The completed genome sequence of the temperate Streptomyces phage straight phiC31 is reported. straight phiC31 contains genes that are related by sequence similarities to several other dsDNA phages infecting many diverse bacterial hosts, including Escherichia, Arthrobacter, Mycobacterium, Rhodobacter, Staphylococcus, Bacillus, Streptococcus, Lactobacillus and Lactococcus. These observations provide further evidence that dsDNA phages from diverse bacterial hosts are related and have had access to a common genetic pool. Analysis of the late genes was particularly informative. The sequences of the head assembly proteins (portal, head protease and major capsid) were conserved between straight phiC31, coliphage HK97, staphylococcal phage straight phiPVL, two Rhodobacter capsulatus prophages and two Mycobacterium tuberculosis prophages. These phages and prophages (where non-defective) from evolutionarily diverse hosts are, therefore, likely to share a common head assembly mechanism i.e. that of HK97. The organisation of the tail genes in straight phiC31 is highly reminiscent of tail regions from other phage genomes. The unusual organisation of the putative lysis genes in straight phiC31 is discussed, and speculations are made as to the roles of some inessential early gene products. Similarities between certain phage gene products and eukaryotic dsDNA virus proteins were noted, in particular, the primase/helicases and the terminases (large subunits). Furthermore, the complete sequence clarifies the overall transcription map of the phage during lytic growth and the positions of elements involved in the maintenance of lysogeny.

/pdf/the-complete-genome-sequence-of-the-streptomyces-temperate-4y9wxeu0az.pdf

The complete genome sequence of the Streptomyces temperate phage φC31: evolutionary relationships to other viruses

The repressor gene, c, is required for maintenance of lysogeny in the Streptomyces phage phi C31. The c gene expresses three in-frame N-terminally different protein isoforms at least one of which is thought to bind to a 17bp highly conserved inverted repeat (CIR) sequence found at 18 (or more) loci throughout the phi C31 genome. Here we present evidence that one of these loci, CIR6, and its interaction with the products of the repressor gene are critical in the control of the lytic pathway in phi C31. To the right of CIR6, according to the standard map of phi C31, an 'immediate-early' promoter, ap1, was discovered after insertion of a fragment containing CIR6 upstream of a promoterless kanamycin-resistance gene, aphII, to form pCIA2. pCIA2 conferred kanamycin resistance upon Streptomyces coelicolor A3(2) but not upon a phi C31 lysogen of S. coelicolor. Operator-constitutive (Oc) mutants of pCIA2 were isolated and the mutations lay in CIR6, i.e. CIR6:G14T and CIR6:C2A. Primer extension analysis of RNA prepared from an induced, temperature-sensitive lysogen of S. coelicolor localized a mRNA 5' endpoint 21 bp to the right of CIR6. The importance of the ap1/CIR6 region in the regulation of lytic growth was demonstrated by the analysis of a virulent mutant, phi C31 vir1, capable of forming plaques on an S. coelicolor phi C31 lysogen. phi C31vir1 contained a DNA inversion with the breakpoints lying within the integrase gene (which lies approximately 7 kbp to the right of CIR6) and in the essential early region between CIR6 and the -10 sequence for ap1. The separation of ap1 from its operator was thought to be the basis for the virulent phenotype in phi C31 vir1. Band-shift assays and DNase I footprinting experiments using purified 42 kDa repressor isoform confirmed that CIRs 5 and 6 were indeed the targets for binding of this protein. The 42 kDa repressor bound to CIR6 with higher affinity than to CIR5 in spite of their identical core sequences. Repressor bound at CIR6 facilitated binding at CIR5. The high-affinity binding to CIR6 was abolished with the Oc mutant, CIR6:G14T. Hydroxyl radical footprinting and dimethyl sulphate methylation protection of the 42 kDa repressor-CIR6 interaction suggested that the protein bound in the major groove and to one face of the DNA.

Control of lytic development in the Streptomyces temperate phage phi C31.

Three protein isoforms (74, 54 and 42 kDa) are expressed from repressor gene c in the Streptomyces temperate bacteriophage phiC31. Because expression of the two smaller isoforms, 54 and 42 kDa, is sufficient for superinfection immunity, the interaction between these isoforms was studied. The native 42 kDa repressor (Nat42) and an N-terminally 6x histidine-tagged 54 kDa isoform (His54) were shown by co-purification on a Ni-NTA column to interact in Streptomyces lividans . In vitro three repressor preparations, containing Nat42, His54 and the native 54 and 42 kDa isoforms expressed together (Nat54&42), were subjected to chemical crosslinking and gel filtration analysis. Homo- and hetero-tetramers were observed. Previous work showed that the smallest isoform bound to 17 bp operators containing aconservedinvertedrepeat (CIR) and that the CIRs were located at 16 loci throughout the phiC31 genome. One of the CIRs (CIR6) is believed to be critical for regulating the lytic pathway. The DNA binding activities of the three repressor preparations were studied using fragments containing CIRs (CIR3-CIR6) from the essential early region as templates for DNase I footprinting. Whereas Nat42 bound to CIR6, poorly to CIR5 but undetectably to CIR3 or CIR4, the Nat54&42 preparation could bind to all CIRs tested, albeit poorly to CIR3 and CIR4. The His54 isoform bound all CIRs tested. Isoforms expressed from the phiC31 repressor gene, like those which are expressed from many eukaryotic transcription factor genes, apparently have different binding specificities.

/pdf/oligomeric-properties-and-dna-binding-specificities-of-7cncomk6dp.pdf

Oligomeric properties and DNA binding specificities of repressor isoforms from the Streptomyces bacteriophage øC31

The repressor gene from the Streptomyces phage φC31 expresses three N-terminally different, in-frame protein isoforms of polypeptide molecular masses 74, 54 and 42 kDa Their precise role in the lysis versus lysogeny decision is currently being investigated and a study of their structural and interactive properties was considered an important aid in this investigation The preliminary data presented here shows that the native 42 kDa isoform and a Histidine (His-)-tagged form exist as dimers or tetramers, depending on the conditions as determined by sedimentation equilibrium in the analytical ultracentrifuge

Investigations of the oligometric state of the 42 kDa repressor isoform from the streptomcyes temperate bacteriophage φC31

The genome of the Streptomyces temperate phage phiC31 integrates into the host chromosome via a recombinase belonging to a novel group of phage integrases related to the resolvase/invertase enzymes. Previously, it was demonstrated that, in an in vitro recombination assay, phiC31 integrase catalyses integration (attP/attB recombination) but not excision (attL/attR). The mechanism responsible for this recombination site selectivity was therefore investigated. Purified integrase was shown to bind with similar apparent binding affinities to between 46 bp and 54 bp of DNA at each of the attachment sites, attP, attB, attL and attR. Assays using recombination sites of 50 bp and 51 bp for attP and attB, respectively, showed that these fragments were functional in attP/attB recombination and maintained strict site selectivity, i.e. no recombination between non-permissive sites, such as attP/attP, attB/attL, etc., was observed. Using bandshifts and supershift assays in which permissive and non-permissive combinations of att sites were used in the presence of integrase, only the attP/attB combination could generate supershifts. Recombination products were isolated from the supershifted complexes. It was concluded that these supershifted complexes contained the recombination synapse and that site specificity, and therefore directionality, is determined at the level of stable synapse formation.

https://onlinelibrary.wiley.com/doi/pdf/10.1046/j.1365-2958.2000.02142.x

Control of directionality in the site-specific recombination system of the Streptomyces phage phiC31.

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