The Salivary Mycobiome Contains 2 Ecologically Distinct Mycotypes.

A broad range of fungi has been detected in molecular surveys of the oral mycobiome. However, knowledge is still lacking on interindividual variability of these communities and the ecologic and clinical significance of oral fungal commensals. In this cross-sectional study, we use internal transcribed spacer 1 amplicon sequencing to evaluate the salivary mycobiome in 59 subjects, 36 of whom were scheduled to receive cancer chemotherapy. Analysis of the broad population structure of fungal communities in the whole cohort identified 2 well-demarcated genus-level community types (mycotypes), with Candida and Malassezia as the main taxa driving cluster partitioning. The Candida mycotype had lower diversity than the Malassezia mycotype and was positively correlated with cancer and steroid use in these subjects, smoking, caries, utilizing a removable prosthesis, and plaque index. Mycotypes were also associated with metabolically distinct bacteria indicative of divergent oral environments, with aciduric species enriched in the Candida mycotype and inflammophilic bacteria increased in the Malassezia mycotype. Similar to their fungal counterparts, coexisting bacterial communities associated with the Candida mycotype showed lower diversity than those associated with the Malassezia mycotype, suggesting that common environmental pressures affected bacteria and fungi. Mycotypes were also seen in an independent cohort of 24 subjects, in which cultivation revealed Malassezia as viable oral mycobiome members, although the low-abundance Malassezia sympodialis was the only Malassezia species recovered. There was a high degree of concordance between the molecular detection and cultivability of Candida, while cultivation showed low sensitivity for detection of the Malassezia mycotype. Overall, our work provides insights into the oral mycobiome landscape, revealing 2 community classes with apparently distinct ecologic constraints and specific associations with coexisting bacteria and clinical parameters. The utility of mycotypes as biomarkers for oral diseases warrants further study.

Using high throughput sequencing to explore the biodiversity in oral bacterial communities.

High throughput sequencing of 16S ribosomal RNA gene amplicons is a cost-effective method for characterization of oral bacterial communities. However, before undertaking large-scale studies, it is necessary to understand the technique-associated limitations and intrinsic variability of the oral ecosystem. In this work we evaluated bias in species representation using an in vitro-assembled mock community of oral bacteria. We then characterized the bacterial communities in saliva and buccal mucosa of five healthy subjects to investigate the power of high throughput sequencing in revealing their diversity and biogeography patterns. Mock community analysis showed primer and DNA isolation biases and an overestimation of diversity that was reduced after eliminating singleton operational taxonomic units (OTUs). Sequencing of salivary and mucosal communities found a total of 455 OTUs (0.3% dissimilarity) with only 78 of these present in all subjects. We demonstrate that this variability was partly the result of incomplete richness coverage even at great sequencing depths, and so comparing communities by their structure was more effective than comparisons based solely on membership. With respect to oral biogeography, we found inter-subject variability in community structure was lower than site differences between salivary and mucosal communities within subjects. These differences were evident at very low sequencing depths and were mostly caused by the abundance of Streptococcus mitis and Gemella haemolysans in mucosa. In summary, we present an experimental and data analysis framework that will facilitate design and interpretation of pyrosequencing-based studies. Despite challenges associated with this technique, we demonstrate its power for evaluation of oral diversity and biogeography patterns.

Potentials and limitations of histone repeat sequences for phylogenetic reconstruction of Sophophora.

Simplified DNA sequence acquisition has provided many new data sets that are useful for phylogenetic reconstruction, including single- and multiple-copy nuclear and organellar genes. Although transcribed regions receive much attention, nontranscribed regions have recently been added to the repertoire of sequences suitable for phylogenetic studies, especially for closely related taxa. We evaluated the efficacy of a small portion of the histone repeat for phylogenetic reconstruction among Drosophila species. Histone repeats in invertebrates offer distinct advantages similar to those of widely used ribosomal repeats. First, the units are tandemly repeated and undergo concerted evolution. Second, histone repeats include both highly conserved coding and variable intergenic regions. This composition facilitates application of "universal" primers spanning potentially informative sites. We examined a small region of the histone repeat, including the intergenic spacer segments of coding regions from the divergently transcribed H2A and H2B histone genes. The spacer (about 230 bp) exists as a mosaic with highly conserved functional motifs interspersed with rapidly diverging regions; the former aid in alignment of the spacer. There are no ambiguities in alignment of coding regions. Coding and noncoding regions were analyzed together and separately for phylogenetic information. Parsimony, distance, and maximum-likelihood methods successfully retrieve the corroborated phylogeny for the taxa examined. This study demonstrates the resolving power of a small histone region which may now be added to the growing collection of phylogenetically useful DNA sequences.

Drosophila virilis has atypical kinds and arrangements of histone repeats.

Genomic and P1 clone DNAs of Drosophila virilis were analyzed to determine the structure and organization of histone genes in this species. The species contains unique and variable repeat types, in comparison with the related species Drosophila melanogaster, with quartet repeats lacking the H1 gene and multi-length variant quintet repeats containing the H1 gene. Unexpectedly, the H1-containing repeats are highly polymorphic in length, and thus not in a strict tandem arrangement, while the H1-less repeats are very uniform and tandemly reiterated. Despite such differences, the relative positions and transcriptional polarities of the histone gene subtypes of one subcloned quintet are similar to the major histone repeat type of D. melanogaster. For the first time, the histone H1 gene has been shown to be associated with other histone gene subtypes and is present at both chromosomal loci. DNA sequence variants of the H1 gene have been mapped to individual P1 clones and found to be in a partitioned organization. The P1 cloning system has proved useful in completely retrieving a complex repetitive locus in vitro and in examining the structure and organization of the histone genes of D. virilis.

High density of an SAR-associated motif differentiates heterochromatin from euchromatin.

Heterochromatin is an important component of eukaryotic chromosomes, comprising a significant portion of the total DNA in genomes. Despite its prevalence, long-standing cytological descriptions, and predominant composition of tandemly repeated DNA, no general theory unites heterochromatic with its functions. In an attempt to identify heterochromatic sequence tags, we have analysed heterochromatic sequences from Drosophila melanogaster for the presence of motifs that are known to define regions that anchor the chromosomal DNA to the scaffold (scaffold attachment regions or SARs). The SARs of Drosophila melanogaster are characterized by the presence of a small conserved sequence (the A-box) that is clustered in overall A + T-rich regions. In comparing heterochromatic and euchromatic sequences we find that heterochromatic regions are several-fold enriched for these operationally defined SARs. This high density of SAR-associated sequences not only serves as a molecular tag for heterochromatin but also suggests a hypothesis for its special properties.

Low codon bias and high rates of synonymous substitution in Drosophila hydei and D. melanogaster histone genes.

We have evaluated codon usage bias in Drosophila histone genes and have obtained the nucleotide sequence of a 5,161-bp D. hydei histone gene repeat unit. This repeat contains genes for all five histone proteins (H1, H2a, H2b, H3, and H4) and differs from the previously reported one by a second EcoRI site. These D. hydei repeats have been aligned to each other and to the 5.0-kb (i.e., long) and 4.8-kb (i.e., short) histone repeat types from D. melanogaster. In each species, base composition at synonymous sites is similar to the average genomic composition and approaches that in the small intergenic spacers of the histone gene repeats. Accumulation of synonymous changes at synonymous sites after the species diverged is quite high. Both of these features are consistent with the relatively low codon usage bias observed in these genes when compared with other Drosophila genes. Thus, the generalization that abundantly expressed genes in Drosophila have high codon bias and low rates of silent substitution does not hold for the histone genes.

Probe mapping to facilitate transposon-based DNA sequencing.

A promising strategy for DNA sequencing exploits transposons to provide mobile sites for the binding of sequencing primers. For such a strategy to be maximally efficient, the location and orientation of the transposon must be readily determined and the insertion sites should be randomly distributed. We demonstrate an efficient probe-based method for the localization and orientation of transposon-borne primer sites, which is adaptable to large-scale sequencing strategies. This approach requires no prior restriction enzyme mapping or knowledge of the cloned sequence and eliminates the inefficiency inherent in totally random sequencing methods. To test the efficiency of probe mapping, 49 insertions of the transposon gamma delta (Tn1000) in a cloned fragment of Drosophila melanogaster DNA were mapped and oriented. In addition, oligonucleotide primers specific for unique subterminal gamma delta segments were used to prime dideoxynucleotide double-stranded sequencing. These data provided an opportunity to rigorously examine gamma delta insertion sites. The insertions were quite randomly distributed, even though the target DNA fragment had both A + T-rich and G + C-rich regions; in G + C-rich DNA, the insertions were found in A + T-rich "valleys." These data demonstrate that gamma delta is an excellent choice for supplying mobile primer binding sites to cloned DNA and that transposon-based probe mapping permits the sequences of large cloned segments to be determined without any subcloning.

On the origins of tandemly repeated genes: does histone gene copy number in Drosophila reflect chromosomal location?

Widely regarded beliefs about Drosophila histone gene copy numbers and developmental requirements have been generalized from fairly limited data since studies on histone gene arrangements and copy numbers have been largely confined to a single species, D. melanogaster. Histone gene copy numbers and chromosomal locations were examined in three species: D. melangaster, D. hydei and D. hawaiiensis. Quantitative whole genome blot analysis of DNA from diploid tissues revealed a tenfold variability in histone gene copy numbers for these three species. In situ hybridization to polytene chromosomes showed that the histone DNA (hDNA) chromosomal location is different in all three species. These observations lead us to propose a relationship between histone gene reiteration and chromosomal position.

Evidence for horizontal transmission of the P transposable element between Drosophila species.

Several studies have suggested that P elements have rapidly spread through natural populations of Drosophila melanogaster within the last four decades. This observation, together with the observation that P elements are absent in the other species of the melanogaster subgroup, has lead to the suggestion that P elements may have entered the D. melanogaster genome by horizontal transmission from some more distantly related species. In an effort to identify the potential donor in the horizontal transfer event, we have undertaken an extensive survey of the genus Drosophila using Southern blot analysis. The results showed that P-homologous sequences are essentially confined to the subgenus Sophophora. The strongest P hybridization occurs in species from the closely related willistoni group. A wild-derived strain of D. willistoni was subsequently selected for a more comprehensive molecular examination. As part of the analysis, a complete P element was cloned and sequenced from this line. Its nucleotide sequence was found to be identical to the D. melanogaster canonical P, with the exception of a single base substitution at position 32. When the cloned element was injected into D. melanogaster embryos, it was able to both promote transposition of a coinjected marked transposon and induce singed-weak mutability, thus demonstrating its ability to function as an autonomous element. The results of this study suggest that D. willistoni may have served as the donor species in the horizontal transfer of P elements to D. melanogaster.

pBR322-derived multicopy plasmids harboring large inserts are often dimers in Escherichia coli K-12.

pBR322-related plasmids that are 2.3 to 5.1 kb were found predominantly as monomers, while plasmids that are 7.7 to 15.2 kb were found predominantly as dimers in rec+ cells of Escherichia coli K-12.

The distribution of P-element sequences in Drosophila: the willistoni and saltans species groups.

This report describes the distribution of P-element sequences among members of the closely related willistoni and saltans species groups of the subgenus Sophophora. Gel-blotting analyses showed that many, but not all, species from each of these groups possess sequences with homology to the P transposable element of Drosophila melanogaster, a sophophoran species belonging to the melanogaster species group. Furthermore, P-homologous fragments are present in lower numbers in willistoni- and saltans-group species than in D. melanogaster P strains, and, in some species of those two groups, exhibit species-characteristic hybridization patterns. On the basis of these results, it is proposed that P elements have had a long evolutionary history in the willistoni and saltans lineages.

Differential expression of histone sequences in Drosophila following heat shock.

The expression of the sequences encoding the four nucleosomal histone proteins was examined following heat shock of a variety of Drosophila cells and was found to be highly differential. In Drosophila melanogaster KC-O cells grown in suspension culture, there is a continuation of the synthesis of all four of the nucleosomal histone proteins following heat shock. Analysis of RNA from these cells confirms that histone messengers are transcribed and located on polysomes. This exact same pattern of histone protein synthesis occurs in KC-O cells grown to low density on plates. In contrast, KC-O cells grown to high density on plates exhibit a dramatic elevation of H2b protein synthesis relative to the synthesis of the other core histones. Organs from D melanogaster third instar larvae were examined to ascertain whether histone protein synthesis continues following heat shock in the organism. Different tissue types exhibited differential histone synthesis. Imaginal disks excised from heat-shocked larvae continue to synthesize nucleosomal histones in a variable fashion. In contrast, neither fat bodies, brains, nor salivary glands continues to synthesize core histone proteins at a significant level. D hydei plated cell cultures and larval tissues fail to synthesize histones at any detectable level following a heat shock. Based on these observations, we propose that there is a differential synthesis of nucleosomal proteins in Drosophila that is highly dependent on the state of the cells prior to the heat shock.

Molecular analysis of P element behavior in Drosophila simulans transformants.

In this report we describe the successful transformation of Drosophila simulans with an autonomous P element from Drosophila melanogaster without the use of a selectable marker. This result demonstrates that there is no species barrier for P element transposition. Utilizing gel blotting and in situ hybridization techniques, we have monitored the behavior of newly-introduced P elements in several D. simulans transformed lines over twelve generations. In most instances, an overall increase in the number of P elements was observed. An examination of the frequency of P-element-bearing individuals in one line revealed the rapid spread of P elements through the population. Analysis of well-characterized sublines confirmed that P elements increase in number by transposition to new genomic sites. The formation of degenerate elements occurred in at least one case. These observations suggest that P elements may behave similarly in D. melanogaster and D. simulans.

Sequences homologous to P elements occur in Drosophila paulistorum.

P elements, a class of mobile genetic elements that cause hybrid dysgenesis in Drosophila melanogaster, have thus far been shown to occur only in this species. Using whole genome blot analysis, we present evidence which indicates that sequences homologous to D. melanogaster P elements also occur in Drosophila paulistorum, a distant relative. D. paulistorum is considered a species complex, consisting of six known incipient species or semispecies. All six semispecies possess P element homologous sequences. We further show that there is conservation of restriction enzyme recognition sites between the D. melanogaster and D. paulistorum P element sequences. The presence of P elements in these two species may clarify the roles of recent invasion and rapid loss in the temporal distribution of P elements in Drosophila.

Regulation of the Escherichia coli K-12 uvrB operon.

The UV light inducibility of the uvrB operon of Escherichia coli K-12 was previously demonstrated by exploiting a strain in which the gene for the enzyme beta-galactosidase was inserted into the uvrB operon. This insert is now shown to be located within the structural gene for the uvrB enzyme, leaving the regulatory sequences of the operon intact. Analyses to quantitate the induction of this system show that derepression of the operon is first detectable 5 min after UV exposure, with the rate of synthesis increasing to four to six times the uninduced rate during the subsequent 30 min. Induction is unaffected by mutations in other components of nucleotide excision repair. The control of uvrB was found to result from direct repression by the lexA gene product, with the recA gene product playing an indirect role. Nucleotide excision repair thus seems to be part of the SOS response.

Polymorphism and stability in the histone gene cluster of Drosophila melanogaster.

Histone genes in Drosophila melanogaster are organized into repeats of 4.8 and 5.0 kb (Lifton et al., 1978). We find these repeat sizes in every one of the more than 20 Drosophila strains we have examined. Strains differ in the relative amounts of the two repeat types, with ratios varying from 1:1 to 1:4, the 5.0 kb repeat always present in equal to or greater amounts than the 4.8 kb repeat. Restriction enzyme digestion and blotting analysis reveals that the strains also differ in a number of far less abundant fragments containing histone DNA sequences. In the Amherst and Samarkand strains, there are, in addition, many copies of 4.0 and 5.5 kb repeat-like fragments respectively. A series of stocks were made isogenic for single second chromosomes from the Amherst strain. The hybridization patterns of the histone DNA from these stocks containing different Amherst chromosomes are very similar but a number of differences in the minor fragments were seen. The stability but a number of differences in the minor fragments were seen. The stability of the histone locus restriction pattern was tested by following the DNA derived from a single second chromosome of the b Adhn2 pr cn strain over a two year period. The restriction pattern of major and minor bands remained identical. Finally, histone loci distinguishable by their restriction pattern on blots were recombined with visible markers. These chromosome will be useful in tracing the fate of specific histone loci during genetic manipulations.

Genetic modulation of RNA metabolism in Drosophila. IV. Measurement of rats of RNA synthesis by density labeling.

Accumulation of RNA was measured in adult males of two genotypes: car bb/Ybb- and car bb/YbbSuVar-5. The two genotypes have similar amounts of rDNA, which is reduced in comparison to wild type (CLARK, STRAUSBAUGH and KIEFER 1977). Although genotypically bobbed, car bb/YbbSuVar-5 flies have a wild-type phenotype; car bb/Ybb- flies are both phenotypically and genotypically bobbed (CLARK, STRAUSBAUGH and KIEFER 1977). The wild-type phenotype observed in the car bb/YbbSuVar-5 flies is thought to be the result of an increased rate of rRNA synthesis due to the presence of the YbbSuVar-5 chromosome (SHERMOEN and KIFFER 1975; CLARK, STRAUSBAUGH and KIEFER 1977; CLARK and KIEFER 1977). To further define this phenomenon, the absolute accumulation of RNA was measured in the two genotypes, using density labeling methods. The accumulation of RNA is 1.4 to 1.8 times higher in car bb/YbbSuVar-5 flies than in car bb/Ybb- flies, demonstrating that there is genetic regulation of synthesis in this genotype. The use of density-labeled nucleosides has clearly shown that there is no difference in precusor pool sizes or use between the two genotypes studied.

Genetic modulation of RNA metabolism in Drosophila. III. Requirement for an rDNA-deficient X chromosome in YbbSuVar-3-mediated increases in RNA synthesis.

Males of the genotype car bb/YbbSuVar-5 have an approximately two-fold increase in the rate of accumulation of 4S, 5S, 18S plus 28S and poly-A+ RNA molecules when compared to males of the genotype car bb/Ybb- (CLARK, STRAUSBAUGH AND KIEFER 1977; CLARK and KIEFER 1977). Experiments were designed to determine if the modulation of RNA metabolism by YbbSuVar-5 requires an rDNA deficiency on the X chromosome. Synthetic rates for 4S, 5S, and 18S plus 28S RNA's were measured in the genotypes Sam + iso/Ybb- and Sam + iso/YbbSuVar-5 by injecting adult males with 3H-uridine, allowing them to incorporate label for two hours, fractionating extracted RNA by polyacrylamide gel electrophoresis and determining the specific activities of RNA's (dpm/microgram RNA). The results of these determination showed that the synthetic rates for 4S, 5S, and 18S plus 28S RNA's are the same in these two genotypes, demonstrating that the YbbSuVar-5 chromosome does not increase transcription when paired with an X chromosome that is wild type for rDNA. Saturation hybridization was used to measure the rDNA content in several genotypes. These results showed that Sam + iso/YbbSuVar-5 males and Sam + iso/Ybb- males have equivalent amounts of rDNA.--These results are consistent with the suggestion that the Ybb- and YbbSuVar-5 chromosomes have similar amounts of rDNA. The nature of compensatory strategies in rDNA-deficient genotypes is discussed.