Comparative genomics of Czech vaccine strains of Bordetella pertussis.

Bordetella pertussis is a strictly human pathogen causing the respiratory infectious disease called whooping cough or pertussis. B. pertussis adaptation to acellular pertussis vaccine pressure has been repeatedly highlighted, but recent data indicate that adaptation of circulating strains started already in the era of the whole cell pertussis vaccine (wP) use. We sequenced the genomes of five B. pertussis wP vaccine strains isolated in the former Czechoslovakia in the pre-wP (1954-1957) and early wP (1958-1965) eras, when only limited population travel into and out of the country was possible. Four isolates exhibit a similar genome organization and form a distinct phylogenetic cluster with a geographic signature. The fifth strain is rather distinct, both in genome organization and SNP-based phylogeny. Surprisingly, despite isolation of this strain before 1966, its closest sequenced relative appears to be a recent isolate from the US. On the genome content level, the five vaccine strains contained both new and already described regions of difference. One of the new regions contains duplicated genes potentially associated with transport across the membrane. The prevalence of this region in recent isolates indicates that its spread might be associated with selective advantage leading to increased strain fitness

Satellite Subgenomic Particles Are Key Regulators of Adeno-Associated Virus Life Cycle

Historically, adeno-associated virus (AAV)-defective interfering particles (DI) were known as abnormal virions arising from natural replication and encapsidation errors. Through single virion genome analysis, we revealed that a major category of DI particles contains a double-stranded DNA genome in a "snapback" configuration. The 5'- snapback genomes (SBGs) include the P5 promoters and partial rep gene sequences. The 3'-SBGs contains the capsid region. The molecular configuration of 5'-SBGs theoretically may allow double-stranded RNA transcription in their dimer configuration. Our studies demonstrated that 5-SBG regulated AAV rep expression and improved AAV packaging. In contrast, 3'-SBGs at its dimer configuration increased levels of cap protein. The generation and accumulation of 5'-SBGs and 3'-SBGs appears to be coordinated to balance the viral gene expression level. Therefore, the functions of 5'-SBGs and 3'-SBGs may help maximize the yield of AAV progenies. We postulate that AAV virus population behaved as a colony and utilizes its subgenomic particles to overcome the size limit of a viral genome and encodes additional essential functions

Oligonucleotide microarray analysis of gene expression in follicle-stimulating hormone-treated rat Sertoli cells

Spermatogenesis requires the presence of functional somatic Sertoli cells in the seminiferous tubules of the testis. Sertoli cells provide support and factors necessary for the successful progression of germ cells into spermatozoa. Sertoli cells are regulated to a large degree by the glycoprotein hormone FSH, which is required for the testis to acquire full size and spermatogenic capacity. Signaling events initiated by the binding of FSH to its receptor lead to an alteration of Sertoli cell gene expression. To characterize the changes in gene expression in FSH-treated Sertoli cells, we used the mRNA from these cells to screen Affymetrix U34A rat GeneChip oligonucleotide microarrays. Sertoli cells from 20-d-old rats were cultured in the presence of 25 ng/ml ovine FSH. At 0, 2, 4, 8, and 24 h after the addition of FSH, total RNA was purified and used to prepare biotinylated target, which was hybridized to the U34A rat microarray containing approximately 9000 rat genes. Analysis identified 100-300 transcripts at each time point that were up-regulated or down-regulated by 2-fold or greater. Genes previously reported to be FSH or cAMP regulated in rat Sertoli cells were identified, in addition to numerous genes not reported to be expressed or FSH regulated in Sertoli cells. The expression patterns of five of these genes, encoding nerve growth factor inducible gene B, PRL-1, PC3 nerve growth factor-inducible antiproliferative putative secreted protein, diacylglycerol acyltransferase, and an expressed sequence tag, in FSH- and N,O'-dibutyryl cAMP-treated rat Sertoli cells were confirmed and characterized by Northern blot analysis. Thus, we have begun to define the transcriptome induced and repressed by FSH in rat Sertoli cells, and we have generated datasets of genes available for further analysis in regard to spermatogenesis and Sertoli cell signaling

Follicle-Stimulating Hormone Induced Changes in Gene Expression of Murine Testis

Abstract Even though FSH is not required for qualitatively normal spermatogenesis, it plays an important role in the spermatogenic capacity of the testis. Although the actions of FSH are well documented, most of these studies were done in vitro, and the molecular targets of FSH in vivo remain largely unverified. To understand the complete mechanism of FSH actions in spermatogenesis, it is important to identify the genes that are involved in its signaling, and know how these genes are affected by FSH. We have used hypogonadal (hpg) mouse that lacks circulating FSH as an in vivo model in conjunction with the Affymetrix murine GeneChip U74A (12,488 genes) to monitor changes in testicular gene expression as a result of FSH signaling. Hpg mice were injected with 10 IU ovine FSH, killed 4, 8, 12, or 24 h post treatment, and their testicular gene expression was compared with that of untreated control hpg mice. The abundance of a large number of mRNAs was affected by the FSH treatment. The primary effect of FSH resulted in increased steady-state levels of many mRNAs in testes of hpg mice. Several transcripts were identified whose abundance was decreased as well. We have used real-time PCR to confirm the changes in levels of transcripts such as renin-1, Kruppel-like factor 4, Mad4 (max-interacting protein repressor), Nur-related protein 1, and hairy/enhancer of splits gene 1 that were found to be regulated by FSH in testes of hpg mice

Identification of Testosterone-Regulated Genes in Testes of Hypogonadal Mice Using Oligonucleotide Microarray

Abstract FSH and testosterone (T) are required for normal spermatogenesis in mammalian males. These hormones regulate the function of Sertoli cells, which in turn support the differentiation of germ cells in the seminiferous tubules. The molecular targets for these hormones in the testis remain elusive. In this study, we have used hypogonadal (hpg) mice as an in vivo model to examine the actions of T on gene expression in murine testis. This expression pattern was analyzed using Affymetrix Murine GeneChip U74v.2 A, B, C (36,899 transcripts) along with Microarray Suite version 5.0, GeneSpring software, and real-time PCR. hpg mice aged 35–45 d were injected sc with 25 mg testosterone proprionate (TP) in 100 ml of sesame oil, and the animals were killed 4, 8, 12, or 24 h after TP treatments. Untreated hpg mice were used as controls. Gene expression from testes of hpg mice treated with TP was compared with that of testes of untreated hpg mice. At all experimental time points earlier than 24 h, there were more mRNAs with reduced than increased abundance in testes of hpg mice after TP treatment. This study suggests that in murine testis, the primary action of T might be to repress gene expression

Deciphering the Roles of the Histone H2B N-Terminal Domain in Genome-Wide Transcription

Histone N-terminal domains are frequent targets of posttranslational modifications. Multiple acetylated lysine residues have been identified in the N-terminal domain of H2B (K6, K11, K16, K17, K21, and K22), but little is known about how these modifications regulate transcription. We systematically mutated the N-terminal domain of histone H2B, both at known sites of lysine acetylation and elsewhere, and characterized the resulting changes in genome-wide expression in each mutant strain. Our results indicate that known sites of lysine acetylation in this domain are required for gene-specific transcriptional activation. However, the entire H2B N-terminal domain is principally required for the transcriptional repression of a large subset of the yeast genome. We find that the histone H2B repression (HBR) domain, comprised of residues 30 to 37, is necessary and sufficient for this repression. Many of the genes repressed by the HBR domain are located adjacent to telomeres or function in vitamin and carbohydrate metabolism. Deletion of the HBR domain also confers an increased sensitivity to DNA damage by UV irradiation. We mapped the critical residues in the HBR domain required for its repression function. Finally, comparisons of these data with previous studies reveal that a surprising number of genes are coregulated by the N-terminal domains of histone H2B, H3, and H4

Redundant roles for histone H3 N-terminal lysine residues in subtelomeric gene repression in Saccharomyces cerevisiae

The transcription of genes located in subtelomeric regions of yeast chromosomes is repressed relative to the rest of the genome. This repression requires wild-type nucleosome levels but not the telomere silencing factors Sir2, Sir3, Sir4, and Rap1. Subtelomeric heterochromatin is characterized by the absence of acetylation or methylation of histone H3 lysine residues, but it is not known whether histone H3 hypoacetylation or hypomethylation is a prerequisite for the establishment of subtelomeric heterochromatin. We have systematically mutated the N-terminal tails of histone H3 and H4 in Saccharomyces cerevisiae and characterized the effects each mutant has on genome-wide expression. Our results show that subtelomeric transcriptional repression is dependent on the histone H3 N-terminal domain, but not the histone H4 N-terminal domain. Mutating lysine-4, lysine-9, lysine-14, lysine-18, lysine-23, and lysine-27 to glycine in histone H3 is also sufficient to significantly reduce subtelomeric gene repression. Individual histone H3 lysine mutations, however, have little effect on subtelomeric gene repression or genome-wide expression, indicating that these six lysine residues have redundant functions. We propose that acetylation and methylation of histone H3 N-terminal lysine residues act as redundant mechanisms to demarcate regions of euchromatin from heterochromatin

Thorough molecular configuration analysis of noncanonical AAV genomes in AAV vector preparations

The unique palindromic inverted terminal repeats (ITRs) and single-stranded nature of adeno-associated virus (AAV) DNA are major hurdles to current sequencing technologies. Due to these characteristics, sequencing noncanonical AAV genomes present in AAV vector preparations remains challenging. To address this limitation, we developed thorough molecule configuration analysis of noncanonical AAV genomes (TMCA-AAV-seq). TMCA-AAV-seq takes advantage of the documented AAV packaging mechanism in which encapsidation initiates from its 3′ ITR, for AAV-seq library construction. Any AAV genome with a 3′ ITR is converted to a template suitable to adapter addition by a Bst DNA polymerase-mediated extension reaction. This extension reaction helps fix ITR heterogeneity in the AAV population and allows efficient adapter addition to even noncanonical AAV genomes. The resulting library maintains the original AAV genome configurations without introducing undesired changes. Subsequently, long-read sequencing can be performed by the Pacific Biosciences (PacBio) single-molecule, real-time (SMRT) sequencing technology platform. Finally, through comprehensive data analysis, we can recover canonical, noncanonical AAV DNA, and non-AAV vector DNA sequences, along with their molecular configurations. Our method is a robust tool for profiling thorough AAV-population genomes. TMCA-AAVseq can be further extended to all parvoviruses and their derivative vectors

Complete genome of the switchgrass endophyte Enterobacter clocace P101

TheEnterobacter cloacaecomplex is genetically very diverse. The increasing number of complete genomic sequences ofE. cloacaeis helping to determine the exact relationship among members of the complex.E. cloacaeP101 is an endophyte of switchgrass (Panicum virgatum) and is closely related to otherE. cloacaestrains isolated from plants. The P101 genome consists of a 5,369,929 bp chromosome. The chromosome has 5,164 protein-coding regions, 100 tRNA sequences, and 8 rRNA operons