CHROMOSOME STRUCTURE IN PHAGE T4. I. CIRCULARITY OF THE LINKAGE MAP

Dual pathogenicity island transfer by piggybacking lateral transduction

Lateral transduction (LT) is the process by which temperate phages mobilize large sections of bacterial genomes. Despite its importance, LT has only been observed during prophage induction. Here, we report that superantigen-carrying staphylococcal pathogenicity islands (SaPIs) employ a related but more versatile and complex mechanism of gene transfer to drive chromosomal hypermobility while self-transferring with additional virulence genes from the host. We found that after phage infection or prophage induction, activated SaPIs form concatamers in the bacterial chromosome by switching between parallel genomic tracks in replication bubbles. This dynamic life cycle enables SaPIbov1 to piggyback its LT of staphylococcal pathogenicity island vSaα, which encodes an array of genes involved in host-pathogen interactions, allowing both islands to be mobilized intact and transferred in a single infective particle. Our findings highlight previously unknown roles of pathogenicity islands in bacterial virulence and show that their evolutionary impact extends beyond the genes they carry.

Suppressor Mutants: History and Today's Applications

For decades, biologist have exploited the near boundless advantages that molecular and genetic tools and analysis provide for our ability to understand biological systems. One of these genetic tools, suppressor analysis, has proven invaluable in furthering our understanding of biological processes and pathways and in discovering unknown interactions between genes and gene products. The power of suppressor analysis lies in its ability to discover genetic interactions in an unbiased manner, often leading to surprising discoveries. With advancements in technology, high-throughput approaches have aided in large-scale identification of suppressors and have helped provide insight into the core functional mechanisms through which suppressors act. In this review, we examine some of the fundamental discoveries that have been made possible through analysis of suppressor mutations. In addition, we cover the different types of suppressor mutants that can be isolated and the biological insights afforded by each type. Moreover, we provide considerations for the design of experiments to isolate suppressor mutants and for strategies to identify intergenic suppressor mutations. Finally, we provide guidance and example protocols for the isolation and mapping of suppressor mutants.

Lateral transduction is inherent to the life cycle of the archetypical Salmonella phage P22

Lysogenic induction ends the stable association between a bacteriophage and its host, and the transition to the lytic cycle begins with early prophage excision followed by DNA replication and packaging (ERP). This temporal program is considered universal for P22-like temperate phages, though there is no direct evidence to support the timing and sequence of these events. Here we report that the long-standing ERP program is an observation of the experimentally favored Salmonella phage P22 tsc229 heat-inducible mutant, and that wild-type P22 actually follows the replication-packaging-excision (RPE) program. We find that P22 tsc229 excises early after induction, but P22 delays excision to just before it is detrimental to phage production. This allows P22 to engage in lateral transduction. Thus, at minimal expense to itself, P22 has tuned the timing of excision to balance propagation with lateral transduction, powering the evolution of its host through gene transfer in the interest of self-preservation.

Comprehensive discovery of CRISPR-targeted terminally redundant sequences in the human gut metagenome: Viruses, plasmids, and more

Viruses are the most numerous biological entity, existing in all environments and infecting all cellular organisms. Compared with cellular life, the evolution and origin of viruses are poorly understood; viruses are enormously diverse, and most lack sequence similarity to cellular genes. To uncover viral sequences without relying on either reference viral sequences from databases or marker genes that characterize specific viral taxa, we developed an analysis pipeline for virus inference based on clustered regularly interspaced short palindromic repeats (CRISPR). CRISPR is a prokaryotic nucleic acid restriction system that stores the memory of previous exposure. Our protocol can infer CRISPR-targeted sequences, including viruses, plasmids, and previously uncharacterized elements, and predict their hosts using unassembled short-read metagenomic sequencing data. By analyzing human gut metagenomic data, we extracted 11,391 terminally redundant CRISPR-targeted sequences, which are likely complete circular genomes. The sequences included 2,154 tailed-phage genomes, together with 257 complete crAssphage genomes, 11 genomes larger than 200 kilobases, 766 genomes of Microviridae species, 56 genomes of Inoviridae species, and 95 previously uncharacterized circular small genomes that have no reliably predicted protein-coding gene. We predicted the host(s) of approximately 70% of the discovered genomes at the taxonomic level of phylum by linking protospacers to taxonomically assigned CRISPR direct repeats. These results demonstrate that our protocol is efficient for de novo inference of CRISPR-targeted sequences and their host prediction.

The evolution and origins of viruses are long-standing questions in the field of biology. Viral genomes provide fundamental information to infer the evolution and origin of viruses. However, viruses are extraordinarily diverse, and there are no single genes shared across entire species. Several methods were developed to collect viral genomes from metagenome. To infer viral genomes from metagenome, previous approaches relied on reference viral genomes. We thought that such reference-based methods may not be sufficient to uncover diverse viral genomes; therefore, we developed a pipeline that utilizes CRISPR, a prokaryotic adaptive immunological memory. Using this pipeline, we discovered more than 10,000 positively complete CRISPR-targeted genomes from human gut metagenome datasets. A substantial portion of the discovered genomes encoded various types of capsid proteins, supporting the contention that these sequences are viral. Although the majority of these capsid-protein-coding sequences were previously characterized, we notably discovered Inoviridae genomes that were previously difficult to infer as being viral. Furthermore, some of the remaining unclassified sequences without a detectable capsid-protein-encoding gene had a notably low protein-coding ratio. Overall, our pipeline successfully discovered viruses and previously uncharacterized presumably mobile genetic elements targeted by CRISPR.

The Doctor of Delayed Publications: The Remarkable Life of George Streisinger (1927-1984)

The history of science offers multiple examples of how the perseverance of a single visionary person could open the floodgates for a whole new area of research. Zebrafish research is one of these fields with an exciting founding story, as it was the dogged persistence of one man, George Streisinger, that ultimately lifted this little fish out of the obscurity of pet shops into the pantheon of genetic model organisms. The Hungarian born Streisinger was one of the most gifted geneticists of his era and his network of mentors and friends really reads like a who-is-who of 20th century genetics. And it was not only science where he excelled: the way he took his civic duties seriously and outspokenly fought social injustice wherever he met it offers an important lesson on integrity for today's scientists as well.

Capsids and Genomes of Jumbo-Sized Bacteriophages Reveal the Evolutionary Reach of the HK97 Fold

Large icosahedral viruses that infect bacteria represent an extreme of the coevolution of capsids and the genomes they accommodate. One subset of these large viruses is the jumbophages, tailed phages with double-stranded DNA genomes of at least 200,000 bp. We explored the mechanism leading to increased capsid and genome sizes by characterizing structures of several jumbophage capsids and the DNA packaged within them. Capsid structures determined for six jumbophages were consistent with the canonical phage HK97 fold, and three had capsid geometries with novel triangulation numbers (T=25, T=28, and T=52). Packaged DNA (chromosome) sizes were larger than the genome sizes, indicating that all jumbophages use a head-full DNA packaging mechanism. For two phages (PAU and G), the sizes appeared very much larger than their genome length. We used two-dimensional DNA gel electrophoresis to show that these two DNAs migrated abnormally due to base modifications and to allow us to calculate their actual chromosome sizes. Our results support a ratchet model of capsid and genome coevolution whereby mutations lead to increased capsid volume and allow the acquisition of additional genes. Once the added genes and larger capsid are established, mutations that restore the smaller size are disfavored.

A large family of viruses share the same fold of the capsid protein as bacteriophage HK97, a virus that infects bacteria. Members of this family use different numbers of the capsid protein to build capsids of different sizes. Here, we examined the structures of extremely large capsids and measured their DNA content relative to the sequenced genome lengths, aiming to understand the process that increases size. We concluded that mutational changes leading to larger capsids become locked in by subsequent changes to the genome organization.

Predicting genome terminus sequences of Bacillus cereus-group bacteriophage using next generation sequencing data

Background

Most tailed bacteriophages (phages) feature linear dsDNA genomes. Characterizing novel phages requires an understanding of complete genome sequences, including the definition of genome physical ends.

Result

We sequenced 48 Bacillus cereus phage isolates and analyzed Next-generation sequencing (NGS) data to resolve the genome configuration of these novel phages. Most assembled contigs featured reads that mapped to both contig ends and formed circularized contigs. Independent assemblies of 31 nearly identical I48-like Bacillus phage isolates allowed us to observe that the assembly programs tended to produce random cleavage on circularized contigs. However, currently available assemblers were not capable of reporting the underlying phage genome configuration from sequence data. To identify the genome configuration of sequenced phage in silico, a terminus prediction method was developed by means of ‘neighboring coverage ratios’ and ‘read edge frequencies’ from read alignment files. Termini were confirmed by primer walking and supported by phylogenetic inference of large DNA terminase protein sequences.

Conclusions

The Terminus package using phage NGS data along with the contig circularity could efficiently identify the proximal positions of phage genome terminus. Complete phage genome sequences allow a proposed characterization of the potential packaging mechanisms and more precise genome annotation.

Electronic supplementary material

The online version of this article (doi:10.1186/s12864-017-3744-0) contains supplementary material, which is available to authorized users.

A single-step competitive binding assay for mapping of single DNA molecules

Optical mapping of genomic DNA is of relevance for a plethora of applications such as scaffolding for sequencing and detection of structural variations as well as identification of pathogens like bacteria and viruses. For future clinical applications it is desirable to have a fast and robust mapping method based on as few steps as possible. We here demonstrate a single-step method to obtain a DNA barcode that is directly visualized using nanofluidic devices and fluorescence microscopy. Using a mixture of YOYO-1, a bright DNA dye, and netropsin, a natural antibiotic with very high AT specificity, we obtain a DNA map with a fluorescence intensity profile along the DNA that reflects the underlying sequence. The netropsin binds to AT-tetrads and blocks these binding sites from YOYO-1 binding which results in lower fluorescence intensity from AT-rich regions of the DNA. We thus obtain a DNA barcode that is dark in AT-rich regions and bright in GC-rich regions with kilobasepair resolution. We demonstrate the versatility of the method by obtaining a barcode on DNA from the phage T4 that captures its circular permutation and agrees well with its known sequence.

DNA in nanochannels--directly visualizing genomic information

The power of nanofluidic channels to analyze DNA is described along with practical experimental hints. As an introduction, a general overview is given on conventional DNA analysis tools, as well as tools under development towards the $1000 genome. The focus of this tutorial review is the stretching of DNA in nanoscale channels for coarse-grained mapping of DNA. To understand the behavior of the DNA, basic theory is discussed. Experimental details are revealed so that the reader, with the proper equipment, should be able to perform experiments. Basic approaches to the analysis of the data are discussed. Finally, potential future directions are discussed including the application of melting mapping as a simple barcode for the DNA.

Microsatellites: evolution and mutational processes

Microsatellites (simple sequence repeats) are ubiquitous in eukaryotic genomes, and they are highly polymorphic. They are currently the primary tools for most genetic mapping and for studies comparing the differentiation of human and other mammalian populations. More and more inherited human diseases are now recognized as resulting from mutations in particular microsatellites, and such microsatellite mutations can serve as markers for some cancers. The majority of microsatellite mutational changes probably consist of insertion or deletion of one or a few repeat units through replication slippage, whereas larger (much rarer) changes are important in producing observed allele distributions. Comparisons of microsatellite allele frequencies between humans and chimpanzees suggest that there are constraints on the overall length of microsatellites. Sequence analyses of microsatellites in diverse human and non-human populations indicate that the structure of many repeats may not be as simple as previously believed, in that alleles differ in base composition as well as in repeat length. Single base changes that result in long uninterrupted repeats may lead to increased mutation rates, including the extreme trinucleotide repeat instability responsible for several inherited diseases.

Bacteriophage T4 genome

Phage T4 has provided countless contributions to the paradigms of genetics and biochemistry. Its complete genome sequence of 168,903 bp encodes about 300 gene products. T4 biology and its genomic sequence provide the best-understood model for modern functional genomics and proteomics. Variations on gene expression, including overlapping genes, internal translation initiation, spliced genes, translational bypassing, and RNA processing, alert us to the caveats of purely computational methods. The T4 transcriptional pattern reflects its dependence on the host RNA polymerase and the use of phage-encoded proteins that sequentially modify RNA polymerase; transcriptional activator proteins, a phage sigma factor, anti-sigma, and sigma decoy proteins also act to specify early, middle, and late promoter recognition. Posttranscriptional controls by T4 provide excellent systems for the study of RNA-dependent processes, particularly at the structural level. The redundancy of DNA replication and recombination systems of T4 reveals how phage and other genomes are stably replicated and repaired in different environments, providing insight into genome evolution and adaptations to new hosts and growth environments. Moreover, genomic sequence analysis has provided new insights into tail fiber variation, lysis, gene duplications, and membrane localization of proteins, while high-resolution structural determination of the "cell-puncturing device," combined with the three-dimensional image reconstruction of the baseplate, has revealed the mechanism of penetration during infection. Despite these advances, nearly 130 potential T4 genes remain uncharacterized. Current phage-sequencing initiatives are now revealing the similarities and differences among members of the T4 family, including those that infect bacteria other than Escherichia coli. T4 functional genomics will aid in the interpretation of these newly sequenced T4-related genomes and in broadening our understanding of the complex evolution and ecology of phages-the most abundant and among the most ancient biological entities on Earth.

Headwaters of the zebrafish -- emergence of a new model vertebrate

The understanding of vertebrate development has advanced considerably in recent years, primarily due to the study of a few model organisms. The zebrafish, the newest of these models, has risen to prominence because both genetic and experimental embryological methods can be easily applied to this animal. The combination of approaches has proven powerful, yielding insights into the formation and function of individual tissues, organ systems and neural networks, and into human disease mechanisms. Here, we provide a personal perspective on the history of zebrafish research, from the assembly of the first genetic and embryological tools through to sequencing of the genome.

Cytological evidence for association of the ends of the linear chromosome in Streptomyces coelicolor

The chromosome of the filamentous bacterium Streptomyces coelicolor is linear, but the genetic map is circular. We present cytological evidence based on the use of fluorescence in situ hybridization showing that the ends of the chromosome frequently colocalize, in agreement with the idea that the ends are held together, effectively forming a circular chromosome. These observations provide a possible explanation for how a linear bacterial chromosome can exhibit a circular genetic map.

Streptomyces genomes: circular genetic maps from the linear chromosomes

Streptomyces chromosomes are linear DNA molecules and yet their genetic maps based on linkage analysis are circular. The only other known examples of this phenomenon are in the bacteriophages T2 and T4, the linear genomic sequences of which are circularly permuted and terminally redundant, and in which replication intermediates include long concatemers. These structural and functional features are not found in Streptomyces. Instead, the circularity of Streptomyces genetic maps appears to be caused by a completely different mechanism postulated by Stahl & Steinberg (1964, Genetics 50, 531-538)--a strong bias toward even numbers of crossovers during recombination creates misleading genetic linkages between markers on the opposite arms of the chromosome. This was demonstrated by physical inspection of the telomeres in recombinant chromosomes after interspecies conjugation promoted by a linear or circular plasmid. The preference for even numbers of crossovers is probably demanded by the merozygosity of the recombining chromosomes, and by the association between the telomeres mediated by interactions of covalently bound terminal proteins.

Capsid expansion follows the initiation of DNA packaging in bacteriophage T4

Most bacteriophages undergo a dramatic expansion of their capsids during morphogenesis. In phages lambda, T3, T7 and P22, it has been shown that expansion occurs during the packaging of DNA into the capsid. The terminase-DNA complex docks with the portal vertex of an unexpanded prohead and begins packaging. After some of the DNA has entered, the major head protein undergoes a conformational change that increases both the volume and stability of the capsid. In phage T4, the link between packaging and expansion has not been established. We explored the possibility of such a connection using a pulse-chase protocol and high resolution sucrose gradient analysis of capsid intermediates isolated from wild-type T4-infected cells. We show that the first particle appearing after the pulse is an unexpanded prohead, which can be isolated in vitro as the ESP (empty small particle). The next intermediate to appear is also unexpanded, but contains DNA. This new intermediate, the ISP (initiated small particle), can also be isolated on agarose gels, permitting confirmation of both its expansion state and DNA content ( approximately 10 kbp). It appears, therefore, that >/=8% of the T4 genome enters the head shell prior to expansion. Following packaging of an undetermined amount of DNA, the capsid expands, producing the ILP (initiated large particle), which is finally converted to a full head upon the completion of packaging. An expanded, empty prohead, the ELP (empty large particle), was also observed during 37 degrees C infections, but failed to mature to phage during the chase. Thus the ELP is unlikely to be an intermediate in normal head assembly. We conclude by suggesting that studies on assembly benefit from an emphasis on the processes involved, rather than on the structural intermediates which accumulate if these processes are interrupted.

Recombination in phage lambda: one geneticist's historical perspective

Several features of bacteriophage lambda suit it for the study of genetic recombination. Central among them are those that make it possible to correlate inheritance of DNA with the inheritance of information encoded by DNA through density-label equilibrium centrifugation. Such studies have revealed relationships between DNA replication and recombination, have identified roles for double-strand breaks in the initiation of recombination, and have elucidated the role of the recombination-stimulating sequence, chi.

The largest (70 kDa) product of the bacteriophage T4 DNA terminase gene 17 binds to single-stranded DNA segments and digests them towards junctions with double-stranded DNA

Bacteriophage terminases are oligomeric multifunctional proteins that bind to vegetative DNA, cut it and, together with portal proteins, translocate the DNA into preformed heads. Most terminases are encoded by two partially overlapping genes. In phage T4 they are genes 16 and 17. We have shown before that the larger of these, gene 17, can yield, in addition to a full-length 70 kDa product, several shorter peptides. At least two of these, gene product (gp) 17' and gp17", are initiated in the same reading frame as the 70 kDa gp17 from internal ribosome binding sites. Most of the shorter gp17 s contain predicted ATPase motifs, but only the largest (70 kDa) peptide has a predicted single-stranded DNA binding domain. Here we describe the DNA binding and cutting properties of the purified 70 kDa protein, expressed from two different clones containing gene 17 but no other T4 gene. Epitope-specific antibodies, which recognize several different gene 17 products in extracts of induced clones or of T4-infected cells, precipitate the purified 70 kDa gp17. When Mg2+ is chelated by EDTA this 70 kDa protein binds to single-stranded DNA, preferentially to junctions of single- and double-stranded DNA segments. It does not bind to blunt-ended double-stranded DNA. When Mg2+ is present the purified 70 kDa gp17 digests single-stranded segments preferentially up to junctions with double-stranded DNA. A 70 kDa gp17 from a P379L temperature sensitive (ts) mutant, which has lost the nuclease and ATPase activities, retains the single-stranded DNA binding activity. Taken together with earlier findings these results support a model for packaging of T4 DNA from single-stranded regions in recombinational or replicative intermediates, which occur at nearly random positions of the genome. This mechanism may be an alternative to site-specific initiation of packaging proposed by other investigators.

The roles of the bacteriophage T4 r genes in lysis inhibition and fine-structure genetics: a new perspective

Seldom has the study of a set of genes contributed more to our understanding of molecular genetics than has the characterization of the rapid-lysis genes of bacteriophage T4. For example, T4 rII mutants were used to define gene structure and mutagen effects at the molecular level and to help unravel the genetic code. The large-plaque morphology of these mutants reflects a block in expressing lysis inhibition (LIN), the ability to delay lysis for several hours in response to sensing external related phages attacking the cell, which is a unique and highly adaptive attribute of the T4 family of phages. However, surprisingly little is known about the mechanism of LIN, or how the various r genes affect its expression. Here, we review the extensive old literature about the r genes and the lysis process and try to sort out the major players affecting lysis inhibition. We confirm that superinfection can induce lysis inhibition even while infected cells are lysing, suggesting that the signal response is virtually instantaneous and thus probably the result of post-translational regulation. We identify the rI gene as ORF tk.-2, based on sequence analysis of canonical rI mutants. The rI gene encodes a peptide of 97 amino acids (Mr = 11.1 kD; pI = 4.8) that probably is secreted into the periplasmic space. This gene is widely conserved among T-even phage. We then present a model for LIN, postulating that rI is largely responsible for regulating the gpt holin protein in response to superinfection. The evidence suggests that the rIIA and B genes are not directly involved in lysis inhibition; rather, when they are absent, an alternate pathway for lysis develops which depends on the presence of genes from any of several possible prophages and is not sensitive to lysis inhibition.

Repair of double-strand breaks in bacteriophage T4 by a mechanism that involves extensive DNA replication

We investigated double-strand break (dsb) repair in bacteriophage T4 using a physical assay that involves a plasmid substrate with two inverted DNA segments. A dsb introduced into one repeat during a T4 infection induces efficient dsb repair using the second repeat as a template. This reaction is characterized by the following interesting features. First, the dsb induces a repair reaction that is directly coupled to extensive plasmid replication; the repaired/replicated product is in the form of long plasmid concatemers. Second, repair of the dsb site is frequently associated with exchange of flanking DNA. Third, the repair reaction is absolutely dependent on the products of genes uvsX, uvsY, 32, 46, and 59, which are also required for phage genomic recombination-dependent DNA replication. Fourth, the coupled repair/replication reaction is only partly dependent on endonuclease VII (gp49), suggesting that either another Holliday-junction-cleaving activity or an alternate resolution pathway is active during T4 infections. Because this repair reaction is directly coupled to extensive replication, it cannot be explained by the SZOSTAK et al. model. We present and discuss a model for the coupled repair/replication reaction, called the extensive chromosome replication model for dsb repair.

Speciation by reinforcement: a model derived from studies of Drosophila

Reinforcement is an increase in premating reproductive isolation between taxa resulting from selection against hybrids. We present a model of reinforcement with a novel type of selection on female mating behavior. Previous models of reinforcement have focused on the divergence of female mating preferences between nascent species. We suggest that an increase in the level of female mating discrimination can yield reinforcement without further divergence of either male characters or female preferences. This model indicates that selection on mating discrimination is a viable mechanism for reinforcement and may allow speciation under less stringent conditions than selection on female preference. This model also incorporates empirical results from genetic studies of hybrid fitness determination in Drosophila species. We find that the details of inheritance, which include sex-linked transmission, sex-limited fertility reduction, and X-autosome epistasis, have important effects on the likelihood of reinforcement. In particular, X-autosome epistasis for hybrid fitness determination facilitates reinforcement when hybrid fertility reduction occurs in males, but hinders the process when it occurs in females. HALDANE's rule indicates that hybrid sterility will generally evolve in males prior to females within nascent species. Thus, HALDANE's rule and X-autosome epistasis provide conditions that are surprisingly favorable for reinforcement in Drosophila.

Bacteriophage association of streptococcal pyrogenic exotoxin type C

A gene encoding streptococcal pyrogenic exotoxin type C (SPE C) was isolated from bacteriophage DNA derived from Streptococcus pyogenes CS112. The gene, designated speC2, was shown to reside near the phage attachment site of phage CS112. A restriction endonuclease map of the CS112 phage was generated, and the location and orientation of the speC2 gene were determined. Hybridization analyses of eight SPE C-producing strains revealed restriction fragment length polymorphism of the speC gene-containing DNA fragments and further showed that each speC was linked to a common CS112 phage-derived DNA fragment.

Fine structure recombinational analysis of cloned genes using yeast transformation

We describe a general method for analyzing the genetic fine structure of plasmid-borne genes in yeast. Previously we had reported that a linearized plasmid is efficiently rescued by recombination with a homologous restriction fragment when these are co-introduced by DNA-mediated transformation of yeast. Here, we show that a mutation can be localized to a small DNA interval when members of a deletion series of wild-type restriction fragments are used in the rescue of a linearized mutant plasmid. The resolution of this method is to at least 30 base pairs and is limited by the loss of a wild-type marker with proximity to a free DNA end. As a means for establishing the nonidentity of two mutations, we determined the resolution of two-point crosses with a mutant linearized plasmid and a mutant homologous restriction fragment. Recombination between mutations separated by as little as 100 base pairs was detected. Moreover, the results indicate that exchange within a marked interval results primarily from one of two single crossovers that repair the linearized plasmid. These approaches to mapping the genetic fine structure of plasmids should join existing methods in a robust approach to the mutational analysis of gene structure in yeast.

Genetic properties of linkage group XIX in Chlamydomonas reinhardtii

A unique linkage group has been identified in Chlamydomonas. To date, all mutations that have been mapped to linkage group XIX affect flagellar and basal body functions. Linkage group XIX shows several other striking genetic properties. First, the genetic map of this linkage group is circular. Genetic circularity can be achieved because the chromosome is a physically circular molecule or because of constraints on the types of recombination events that occur. A linear molecule that shows complete chromatid interference cannot be distinguished from a circular molecule. Complete chromatid interference is defined as the property that every chromatid is always involved in an even number of recombination events. If interference is not complete, three factor crosses will distinguish between a circular chromosome and a linear chromosome. Experiments of this type are underway (S.K. Dutcher, work in progress). Second, recombination levels on linkage group XIX are affected by temperature; recombination on 12 other linkage groups in Chlamydomonas is not affected by changes in temperature during any part of the meiotic life cycle (S.K. Dutcher, ms. in prep.). Patterns of interference and recombination on linkage group XIX are also different from other linkage groups. Basal bodies/centrioles are cellular organelles that are precisely replicated and partitioned in cell division. This fidelity distinguishes basal bodies/centrioles from all other cellular organelles, with the exception of the nucleus and the chromosomes. Because of the odd genetics of linkage group XIX and the strict replication and segregation of basal bodies, it is intriguing to speculate on the location of linkage group XIX. There are numerous reports in the literature of nucleic acid being associated with basal bodies. Both RNA and DNA have been reported to be localized to these structures. To date no unique species has been identified. Lwoff has suggested that basal bodies are genetically autonomous, and Sagan has suggested that they could have a symbiotic origin. Could linkage group XIX be located in the basal body and not in the nucleus? No definitive answer is available to this question. The number of chromosomes in the nucleus of Chlamydomonas has not been determined reliably. Linkage group XIX segregates as expected for a nuclear chromosome and appears to contain a region that behaves genetically as a centromere. However, any genetic information that is partitioned at meiosis in a regular manner and is present in a limited number of copies could resemble a nuclear chromosome in its segregational properties.(ABSTRACT TRUNCATED AT 400 WORDS)

Mechanism of pBR322 transduction mediated by cytosine-substituting T4 bacteriophage

A cytosine-substitution type mutant of bacteriophage T4 (T4dC phage) has been shown to mediate the transfer of plasmid pBR322. The transduction frequency was around 10(-2) per singly infected cell at low multiplicity of infection. The transductants contained either a monomer or multimers of pBR322. The transducing capacity of T4dC phage was resistant to methylmethanesulfonate treatment. The results of Southern blotting experiments have indicated that the pBR322 DNA exists as head-to-tail concatemers in the transducing particles. The mechanism of transfer of pBR322 mediated by T4dC phages is discussed.

The genome of frog virus 3, an animal DNA virus, is circularly permuted and terminally redundant

We examined the structure of the frog virus 3 (FV 3) genome by using electron microscopic and biochemical techniques. The linear FV 3 DNA molecules (Mr approximately 100 x 10(6) formed circles when partially degraded with bacteriophage lambda 5'-exonuclease and annealed, but not when the annealing was done without prior exonuclease digestion. The results suggest that the DNA molecules contain direct terminal repeats. The repeated region composed about 4% of the genome. Complete denaturation of native FV 3 DNA molecules followed by renaturation produced duplex circles each bearing two single-stranded tails at different points along the circumference. The tails presumably represent the terminal repeats. The formation of duplex circles suggests that the FV 3 genome is circularly permuted. This is further borne out by (i) failure to identify a specific restriction endonuclease fragment containing the label when the molecular ends were radiolabeled by using the polynucleotide kinase procedure, and (ii) similarity in the restriction patterns of virion DNA and large concatemeric replicating viral DNA as revealed by endonucleolytic cleavage of both DNAs with HindIII. From the above data, we conclude that the FV3 genome is both circularly permuted and terminally redundant--unique features for an animal virus.

The complete maps of BglII, SalI and XhoI restriction sites on T4 dC-DNA

T4 dC-DNA was digested with the restriction endonucleases BglII, SalI and XhoI. Overlaps in the three sets of fragments allowed the mapping of all restriction sites relative to each other along the T4 genome.

Physical mapping of the restriction fragments obtained from bacteriophage T4 dC-DNA with the restriction endonucleases SmaI, KpnI and BglII

The cytosine-containing DNA of a mutant of bacteriophage T4 was digested with restriction endonucleases SmaI, KpnI and BglII producing 5, 7 and 13 fragments respectively. Complete physical maps of the T4 genome were constructed with the enzymes SmaI and KpnI and an almost complete map with the enzyme BglII.

Transcription of bacteriophage T4 DNA in vitro: selective initiation with dinucleotides

The transcription products of phage T4 DNA in vitro are separated on polyacrylamide gels. The influence of salt, polymerase, triphosphate concentration and glucosylation on the RNA synthesis are shown. Individual transcripts are initiated selectively with dinucleotides and a single triphosphate. This technique allows the prediction of the initiation sequences of several T4 transcripts.

Multiplicity reactivation of 5-iodouracil-substituted, nonviable bacteriophage T4td8

Nonviable, 5-iodouracil (IUra)-substituted bacteriophage T4td8 can be multiplicity reactivated. The data indicate that two nonviable, IUra-substituted T4td8 phage can complement each other intracellularly to produce viable progeny. Phage particles in lysates of T4td8-infected Escherichia coli BT(-), prepared in the presence of varying mole fractions of IUra plus thymine, were examined by infecting with low and high dilutions of lysate. The yields of multiplicity reactivable particles were identical, regardless of the mole fractions of IUra present in the growth media. However, the yields of viable phage, measured at low multiplicities of infection, decreased with increasing mole fraction of IUra. The results are consistent with the hypothesis that the lethal effect of IUra is a consequence of its incorporation into DNA. Further, the IUra-induced lesion cannot involve genetic damage that shuts off expression at a single region of the genome.