Phased Assembly of Neo-Sex Chromosomes Reveals Extensive Y Degeneration and Rapid Genome Evolution in Rumex hastatulus

Y chromosomes are thought to undergo progressive degeneration due to stepwise loss of recombination and subsequent reduction in selection efficiency. However, the timescales and evolutionary forces driving degeneration remain unclear. To investigate the evolution of sex chromosomes on multiple timescales, we generated a high-quality phased genome assembly of the massive older (<10 MYA) and neo (<200,000 yr) sex chromosomes in the XYY cytotype of the dioecious plant Rumex hastatulus and a hermaphroditic outgroup Rumex salicifolius. Our assemblies, supported by fluorescence in situ hybridization, confirmed that the neo-sex chromosomes were formed by two key events: an X-autosome fusion and a reciprocal translocation between the homologous autosome and the Y chromosome. The enormous sex-linked regions of the X (296 Mb) and two Y chromosomes (503 Mb) both evolved from large repeat-rich genomic regions with low recombination; however, the complete loss of recombination on the Y still led to over 30% gene loss and major rearrangements. In the older sex-linked region, there has been a significant increase in transposable element abundance, even into and near genes. In the neo-sex-linked regions, we observed evidence of extensive rearrangements without gene degeneration and loss. Overall, we inferred significant degeneration during the first 10 million years of Y chromosome evolution but not on very short timescales. Our results indicate that even when sex chromosomes emerge from repetitive regions of already-low recombination, the complete loss of recombination on the Y chromosome still leads to a substantial increase in repetitive element content and gene degeneration.

Unveiling invasive insect threats to plant biodiversity: Leveraging eDNA metabarcoding and saturated salt trap solutions for biosurveillance

The negative global impacts of invasive alien species (IAS) on biodiversity are second only to habitat loss. eDNA metabarcoding allows for a faster and more comprehensive evaluation of community species composition, with a higher taxonomic resolution and less taxonomic expertise required than traditional morphological-based biosurveillance. These advantages have positioned eDNA metabarcoding as the standard method for molecular-based detection of invasive alien species, where fast and accurate detectability allows prompt responses to mitigate their adverse effects. Here, eDNA metabarcoding is used for biosurveillance of invasive alien species regulated by Canada in high-risk areas with four main objectives: i) validate the effectiveness of eDNA metabarcoding of salt trap solutions as a molecular technique for IAS detection, ii) compare detection from DNA extracts obtained from filter quarters versus whole filters, iii) benchmark two different bioinformatic pipelines (MetaWorks and mBRAVE), and iv) compare canopy and ground level trapping. eDNA from up to five IAS (Agrilus planipennis, Daktulosphaira vitifoliae, Lymantria dispar, Popillia japonica, and Trichoferus campestris) were successfully detected across years from 2017 to 2022 in southern Ontario, Canada, with successful morphological validation for all except Lymantria dispar and Trichoferus campestris. Analysis of filter quarters in contrast to whole filters was demonstrated to be insufficient for effective IAS detection in each sample. All IAS were detected in only one filter quarter, suggesting a patchy eDNA distribution on the filter. The MetaWorks and mBRAVE bioinformatics pipelines proved effective in identifying IAS, with MetaWorks yielding a higher success rate when comparing molecular and morphological identifications. Ground-level and canopy-level sampling showed differential IAS recovery rates based on the molecular detection, which also varied per collection year, with all found IAS detected at the canopy level in 2022 while only one (Lymantria dispar) in 2020. The present study ratifies the efficacy and importance of eDNA-based detection in a regulatory context and the utility of adding eDNA metabarcoding of saturated salt trap solutions, a critical tool for IAS detection.

Characterization of DNA binding protein of porcine adenovirus type 3

To identify and characterize the protein encoded by the E2A region of porcine adenovirus (PAV)-3, DNA sequence coding for a portion (amino acids 102-457) of the DNA binding protein (DBP) open reaching frame was cloned and expressed in Escherichia coli as a fusion protein with glutathione S-transferase protein of Schistosoma japonica. The affinity-purified fusion protein was used to immunize rabbits. Immunoprecipitation/Western blot analysis demonstrated that the antisera specifically recognized a protein of 50 kD in PAV-3-infected cells. Immunoperoxidase staining detected the DBP protein predominantly in the nucleus of the cells. Western blot analysis demonstrated that DBP was detected as early as 6 h after infection and remained detectable throughout the infection. Based on these results, a novel assay for quantitation of PAV-3 was established. The assay is less time consuming and can be performed in different porcine cells. In addition, virus titers determined by this assay are comparable to the standard plaque assay.

Determination of bovine adenovirus-3 titer based on immunohistochemical detection of DNA binding protein in infected cells

DNA sequence coding for a portion of DNA binding protein (amino acids 3-58) of bovine adenovirus type-3 (BAV-3) was cloned and expressed in Escherichia coli as a fusion protein with Schistosoma japonicum glutathione S-transferase. The fusion protein was affinity purified and used to immunize rabbits. Immunoprecipitation and Western blot analysis showed that the antiserum could specifically recognize a protein of 48 kDa in BAV-3-infected cells, which was produced both in early and late phases of BAV-3 life cycle. Based on the ability of antiserum to recognize DNA binding protein, a novel assay for BAV-3 quantitation was established. The assay is less time consuming and can be performed on a wide variety of bovine cells. In addition, virus titers determined by this assay are comparable to the standard plaque assay.

The immunogenicity and efficacy of replication-defective and replication-competent bovine adenovirus-3 expressing bovine herpesvirus-1 glycoprotein gD in cattle

Replication-competent and replication-defective bovine adenovirus type 3 recombinants expressing the bovine herpesvirus type 1 (BHV-1) glycoprotein D (gD) were tested for induction of gD specific immune responses in calves using intratracheal (1st and 2nd immunization) and sub-cutaneous (3rd immunization) route of immunization. The replication-defective recombinant BAV501 induced systemic immune responses against gD as low titers of anti gD-IgG were detected in the serum. However, the efficacy of the replication-competent BAV3.E3gD to induce gD-specific antibodies in the serum and the nasal secretions was superior to that of replication-defective BAV501 when both viruses were given at the same dosage. Partial protection from challenge was induced in calves immunized with replication-competent BAV3.E3gD. A dramatic increase in the titers of anti-gD IgG and IgA levels, both in serum and nasal secretions, following BHV-1 challenge (anamnestic response) suggested that the animals immunized with replication-defective BAV501 had been primed for gD-specific antibody responses.

Mucosal immunization of calves with recombinant bovine adenovirus-3: induction of protective immunity to bovine herpesvirus-1

To determine the potential of replication-competent (E3-deleted) bovine adenovirus-3 (BAV-3) as a delivery system for vaccine antigens in calves, we evaluated the ability of recombinant BAV-3 expressing different forms of of bovine herpesvirus-1 (BHV-1) glycoprotein gD to protect against BHV-1 infection in calves that had pre-existing BAV-3 specific antibodies. Three- to four-month-old calves, vaccinated intranasally with recombinant BAV-3 expressing full-length gD (BAV3.E3gD) or a truncated version of gD (gDt) (BAV3.E3gDt), or with E3-deleted BAV-3 (BAV3.E3d; control), were challenged with BHV-1 strain 108. Vaccination with BAV3.E3gD or BAV3.E3gDt induced gD-specific antibody responses in serum and nasal secretions, and primed calves for gD-specific lymphoproliferative responses. In addition, all calves developed complement-independent neutralizing antibodies against BHV-1. Protection against viral challenge was observed in calves vaccinated with recombinant BAV3.E3gD or BAV3.E3gDt as shown by a significant reduction in body temperature and clinical disease, and a partial reduction in the amount and duration of virus excretion in nasal secretions. These results indicate that replication-competent BAV-3-based vectors can induce protective immune responses in calves (the natural host) that have pre-existing BAV-3-specific antibodies.

Characterization of early region 1 and pIX of bovine adenovirus-3

The mRNAs from early region 1 (E1) and pIX of bovine adenovirus type 3 (BAV-3) have been studied by Northern blot, S1 nuclease, and cDNA analysis and transcriptional maps for the regions were constructed. The transcriptional map for the E1 region of BAV-3 is different from those of mouse and human adenoviruses for which transcriptional maps for the regions have been constructed. The E1A region of BAV-3 is located between 0.8 and 10.5 map units and several different transcripts are produced from the region using alternative splice donor sites. The transcripts from the E1A region overlap with those of E1B and pIX. In BAV-3, the E1B region maps between 4.2 and 10.5 map units and encodes two major mRNA species. The mRNAs of E1B region differ from each other in that the smaller mRNA coding for the 157R protein has a large intron removed from a region corresponding to the coding region of E1B 420R protein. As in HAVs, the E1B 420R protein of BAV-3 could be translated only by internal initiation from the larger bicistronic mRNA as there are no transcripts produced exclusively for the production of 420R protein. The transcriptional unit of pIX is transcribed from an independent promoter and encodes a structural component of the adenovirus capsid. To identify and characterize the proteins produced from the region, antibodies were raised in rabbits that recognized specific proteins in Western blot and immunoprecipitation assays.

Genetic organization and DNA sequence of early region 4 of bovine adenovirus type 3

We have identified and sequenced 3614 nucleotides located at the extreme right-end of the bovine adenovirus type 3 (BAV3) genome from map units 89.5-100. Analysis of the sequence revealed an inverted terminal repeat (ITR) of 195 bp, and identified five open reading frames (ORFs) designated ORF1, ORF2, ORF3, ORF4 and ORF5. When compared with known E4 ORFs of other adenoviruses, ORFs 1, 2 and 4, which code for proteins of 143, 69 and 143 amino acids respectively, were found to be unique to BAV3. ORFs 3 and 5, which code for proteins of 268 and 219 amino acids respectively, showed partial homology to the E4 34 kDa protein of human adenovirus 2. Nucleotide sequence analysis also identified two potential TATA boxes upstream of ORF1 and a potential polyadenylation signal downstream of ORF5 suggesting that E4 transcripts may be 3' co-terminal.

Characterization of bovine adenovirus type 3 early region 2B

We have determined the nucleotide sequence of a 6999 base pair region of bovine adenovirus-3 covering map units 9.0 to 29.17, which contained the adenovirus homologs of IVa2 protein and the DNA replication proteins, precursor of terminal protein and DNA polymerase proteins. Analysis of the sequence for cis-acting elements suggests that transcripts of DNA polymerase and precursor of terminal protein are 3' co-terminal. In addition, this region also contains major late promoter sequence. The sequence to the left of IVa2 contains the ORF of pIX with a potential TATA box immediately upstream and two polyadenylation consensus signals immediately downstream of the ORF.

Nucleotide sequence, genome organization, and transcription map of bovine adenovirus type 3

The complete DNA sequence of bovine adenovirus type 3 is reported here. The size of the genome is 34,446 bp in length with a G+C content of 54%. All the genes of the early and late regions are present in the expected locations of the genome. However, the late-region genes are organized into seven families, instead of five as they are in human adenovirus type 2. The deduced amino acid sequences of open reading frames (ORFs) in the late regions and early region 2 (E2) and for IVa2 show higher degrees of homology, whereas the predicted amino acid sequences of ORFs in the E1, E3, and E4 regions and the pIX, fiber, and 33,000-molecular-weight nonstructural proteins show little or no homology with the corresponding proteins of other adenoviruses. In addition, the penton base protein lacks the integrin binding motif, RGD, but has an LDV motif instead of an MDV motif. Interestingly, as in other animal adenoviruses, the virus-associated RNA genes appear to be absent from their usual location. Sequence analysis of cDNA clones representing the early- and late-region genes identified splice acceptor and splice donor sites, polyadenylation signals and polyadenylation sites, and tripartite leader sequences.

Mapping of functional regions on the transferrin-binding protein (TfbA) of Actinobacillus pleuropneumoniae

Actinobacillus pleuropneumoniae can use porcine transferrin as the sole source of iron. Two proteins with molecular masses of approximately 60 kDa (TfbA) and 110 kDa have been shown to specifically bind porcine transferrin; from the TfbA protein, three isoforms from A. pleuropneumoniae serotypes 1, 5, and 7 have been identified and characterized by nucleotide sequence analysis. Here we defined the transferrin-binding region(s) of the TfbA protein of A. pleuropneumoniae serotype 7 by TnphoA mutagenesis, random mutagenesis, and peptide spot synthesis. The amino-terminal half of the TfbA molecule, which has only 36% amino acid sequence identity among the three isoforms, was shown to be responsible for transferrin binding by TnphoA mutagenesis. This result was confirmed by analysis of six random mutants with decreased transferrin binding affinity. The subsequent analysis of overlapping 16-mer peptides comprising the amino-terminal half of the TfbA molecule revealed three domains of 13 or 14 amino acids in length with transferrin-binding activity. They overlapped, or were very close to, point mutations decreasing transferrin-binding ability. The first and third domains were unique to the TfbA protein of A. pleuropneumoniae serotype 7. In contrast, the sequence of the second domain was present in almost identical forms (12 of 14 residues) in the TfbA proteins of A. pleuropneumoniae serotypes 1 and 5; in addition, a sequence consisting of functionally homologous amino acids was present in the otherwise completely distinct small transferrin-binding proteins of Neisseria gonorrhoeae (TbpB), N. meningitidis (Tbp2), and Haemophilus influenzae (Tbp2).

Delineation of the essential function of bovine herpesvirus 1 gD: an indication for the modulatory role of gD in virus entry

The entry process of alphaherpesviruses consists of two steps, initial virus attachment and subsequent virus penetration involving membrane fusion. Glycoprotein D (gD) of the alphaherpesvirus bovine herpesvirus 1 (BHV 1) is an essential envelope protein, and it has been previously documented that gD plays a significant part in both of the virus entry steps. In order to gain further insight into the virus entry process, we attempted to define the essential function of BHV 1 gD. We replaced the gD transmembrane and cytoplasmic domains with a lipid-addition signal sequence from human decay accelerating factor and produced a stably transfected Madin Darby bovine kidney (MDBK) cell line that expresses a nonfusogenic, glycosylphosphatidylinositol (GPI)-anchored gD. We found that this cell line was able to support the growth of a gD gene-deletion mutant; the resultant gD mutant progeny contained the GPI-anchored gD on its virions and was able to enter into and produce a production infection in MDBK cells. This result suggests that fusion activity does not constitute the essential function of gD. In addition, we found that a gD-null virus (a virus containing no gD on its virion) could infect gD-expressing cells, but not normal MDBK cells. The ability of the gD-null virus to infect gD-expressing cells was dependent on the gD present on the cell surface, since either treating cells with phosphatidylinositol-specific phospholipase C to remove the GPI-anchored gD or incubating cells with gD monoclonal antibodies could block gD-null virus infection. This demonstrates that gD present on the cell surface can act in trans to facilitate the entry of virion lacking gD. This indicates that essential gD function can take place in the absence of gD-mediated virus attachment and membrane fusion. We also found that the gD monoclonal antibodies that block gD-null virus entry into gD-expressing cells are strictly restricted to the monoclonal antibodies that show postadsorption neutralization activity, indicating that the trans-acting function exhibited by the gD present on the cell surface represents the same function as defined by postadsorption antibody neurtralization. The results from this study suggest that the essential function of gD in virus entry is to modulate other virus-cell interaction(s) involved in productive virus penetration.

Replacement of the folC gene, encoding folylpolyglutamate synthetase-dihydrofolate synthetase in Escherichia coli, with genes mutagenized in vitro

The folylpolyglutamate synthetase-dihydrofolate synthetase gene (folC) in Escherichia coli was deleted from the bacterial chromosome and replaced by a selectable Kmr marker. The deletion strain required a complementing gene expressing folylpolyglutamate synthetase encoded on a plasmid for viability, indicating that folC is an essential gene in E. coli. The complementing folC gene was cloned into the vector pPM103 (pSC101, temperature sensitive for replication), which segregated spontaneously at 42 degrees C in the absence of selection. This complementing plasmid was replaced in the folC deletion strain by compatible pUC plasmids containing folC genes with mutations generated in vitro, producing strains which express only mutant folylpolyglutamate synthetase. Mutant folC genes expressing insufficient enzyme activity could not complement the chromosomal deletion, resulting in retention of the pPM103 plasmid. Some mutant genes expressing low levels of enzyme activity replaced the complementing plasmid, but the strains produced were auxotrophic for products of folate-dependent pathways. The folylpolyglutamate synthetase gene from Lactobacillus casei, which may lack dihydrofolate synthetase activity, replaced the complementing plasmid, but the strain was auxotrophic for all folate end products.

Characterization of a mutation affecting the function of Escherichia coli folylpolyglutamate synthetase-dihydrofolate synthetase and further mutations produced in vitro at the same locus

The folC gene from mutant strain SF4 was cloned into a pUC19 plasmid. Expression of the mutant gene from the lac promoter of the plasmid complemented the auxotrophy for methionine of the SF4 strain. The only difference in sequence between the mutant and wild-type genes was a G925A base change resulting in an A309T amino acid change. The mutant enzyme had a 30-fold higher Km for 10-formyltetrahydrofolate as well as a 60-fold higher Km for glutamate and a 200-fold higher Km for dihydropteroate of the dihydrofolate synthetase activity. Site-specific mutagenesis was used to substitute other amino acids at codon 309. Mutants with glycine, isoleucine, and valine substitutions at this position, when expressed from multicopy plasmids, complemented the SF4 strain. The glycine mutant had properties similar to the wild-type enzyme, whereas the isoleucine and valine mutants had properties similar to the threonine mutant, SF4. Mutant genes with arginine, glutamate, and leucine substitutions, which did not complement the SF4 strain, could complement a folC deletion strain, but produced smaller colonies on complex plates and did not grow on minimal medium. In the deletion strain, an increasing requirement for folate product supplements was observed as the folylpolyglutamate synthetase-dihydrofolate synthetase activities of the complementing mutants decreased.

Homologies between members of the germin gene family in hexaploid wheat and similarities between these wheat germins and certain Physarum spherulins

By screening approximately 10(6) plaques in a wheat DNA library with a "full-length" germin cDNA probe, two genomic clones were detected. When digested with EcoRI, one clone yielded a 2.8-kilobase pair fragment (gf-2.8) and the other yielded a 3.8-kilobase pair fragment (gf-3.8). By nucleotide sequencing, each of gf-2.8 and gf-3.8 was found to encode a complete sequence for germin and germin mRNA, and to contain appreciable amounts of 5'- and 3'-flanking sequences. The "cap" site in gf-2.8 was determined by primer extension and the corresponding site in gf-3.8 was deduced by analogy. The mRNA coding sequences in gf-2.8 and gf-3.8 are intronless and 87% homologous with one another. The 5'-flanking regions in gf-2.8 and gf-3.8 contain recognizable sites of what are probably cis-acting elements but there is otherwise little if any significant similarity between them. In addition to putative TATA and CAAT boxes in the 5'-flanking regions of gf-2.8 and gf-3.8, there are AT-rich inverted-repeats, GC boxes, long purine-rich sequences, two 19-base pair direct-repeat sequences in gf-2.8, and a remarkably long (200-base pair) inverted-repeat sequence (approximately 90% homology) in gf-3.8. An 8% difference between the mature-protein coding regions in gf-2.8 and gf-3.8 is reflected by a corresponding 7% difference between the corresponding 201-residue proteins. Most significantly, the same 8% difference between the mature-protein coding regions in gf-2.8 and gf-3.8 is allied with no change whatever in a central part (61-151) of the encoded polypeptide sequences. It seems likely that this central, strongly conserved core in the germins is of first importance in the biochemical involvements of the proteins. When an equivalence is assumed between like amino acids, the gf-2.8 and gf-3.8 germins show significant (approximately 44%) similarity to spherulins 1a and 1b of Physarum polycephalum, a similarity that increases to approximately 50% in the conserved core of germin. Near the middle (87-96) of the conserved core in the germins is a rare PH(I/T)HPRATEI decapeptide sequence which is shared by spherulins (1a and 1b) and germins (gf-2.8 and gf-3.8). These similarities are discussed in the context of evidence which can be interpreted to suggest that the biochemistry of germins and spherulins is involved with cellular, perhaps cell-wall responses to desiccation, hydration, and osmotic stress.(ABSTRACT TRUNCATED AT 400 WORDS)

Mutagenesis of the folC gene encoding folylpolyglutamate synthetase-dihydrofolate synthetase in Escherichia coli

The folC gene of Escherichia coli, cloned in a pUC19 vector, was mutagenized by progressive deletions from both the 5' and the 3' ends and by TAB linker insertion. A number of 5'-deleted genes, which had the initiator ATG codon removed, produced a truncated gene product, in reduced amounts, from a secondary initiation site. The most likely position of this site at a GTG codon located 35 codons downstream of the normal start site. This product could complement the folC mutation in E. coli strain SF4 as well as a strain deleted in the folC gene. The specific activity of extracts of the mutant enzyme are 4-16% that of the wild type enzyme for the folylpolyglutamate synthetase activity and 6-19% for the dihydrofolate synthetase activity. The relative amount of protein expressed by the mutant, compared to the wild type, in maxicells was comparable to the relative specific activity, suggesting that the kcat of the mutant enzyme is similar to that of the wild type. Mutants with up to 14 amino acids deleted from the carboxy terminal could still complement the folC deletion mutant. Seven out of ten linker insertions dispersed through the coding region of the gene showed complementation of the folC mutation in strain SF4 but none of these insertion mutants were able to complement the strain containing a deleted folC gene. None of the carboxy terminal or linker insertion mutants had a specific activity greater than 0.5% that of the wild type enzyme. The dihydrofolate synthetase and folylpolyglutamate synthetase activities behaved similarly in all mutants, both retaining a large fraction of the wild type activity in the amino terminal deletions and both being very low in the carboxy terminal deletions and linker insertion mutants. These studies are consistent with a single catalytic site for the two activities catalyzed by this enzyme.

Transcription of the folC gene encoding folylpolyglutamate synthetase-dihydrofolate synthetase in Escherichia coli

The folC gene of Escherichia coli is cotranscribed with an upstream gene from two promoters located in the noncoding region 5' to the coding sequence of the upstream gene. Virtually all of the expression of the folC gene product, folylpolyglutamate synthetase-dihydrofolate synthetase, is therefore due to the upstream gene promoters. No promoter activity was found in the coding sequence of the upstream gene or in the 72-base-pair noncoding region between the two genes. It is shown that a third gene, which may overlap the coding sequence of the folC gene by 8 base pairs at the 3' end, nevertheless, has an promoter independent from that of the upstream gene-folC operon. These results contrast with those presented by Nonet et al. (M. L. Nonet, C. C. Marvel, and D. Tolan, J. Biol. Chem., 262:12209-12217, 1987), who concluded that folC was cotranscribed with the gene at its 3' end and the gene upstream to folC was cotranscribed with the gene(s) further upstream. A stable stem-loop structure resembling a rho-independent terminator is present within the noncoding region between the upstream gene and the folC gene. Folypolyglutamate synthetase expression is 6- to 15-fold lower than that of the upstream gene product, suggesting that the stem-loop terminates some of the transcription from the upstream gene promoter. We found by deletion mutagenesis and cloning sequences containing the stem-loop structure into a termination reporter plasmid that this stem-loop does not act as an effective terminator of transcription. We also found that the stem-loop does not protect the upstream gene message from degradation, since expression of the upstream gene product in maxicell experiments is the same whether the stem-loop structure is present or deleted.

Liver aspiration in the diagnosis of hepatocellular carcinoma in the Gambia

Fine needle aspiration was used for the cytological diagnosis of hepatocellular carcinoma in 151 Gambian patients. Of 133 with hepatic tumours a correct positive cytological diagnosis was obtained in 116 (87.2%). This simple test was a safe and accurate diagnostic procedure. It is particularly suitable for use in countries where medical resources are limited and hepatocellular carcinoma is prevalent.