ABSTRACT
Conidia play a vital role in the survival and rapid spread of fungi. Many biological processes of conidia, such as adhesion, signal transduction, the regulation of oxidative stress, and autophagy, have been well studied. In contrast, the contribution of pathogenicity factors during the development of conidia in fungal phytopathogens has been poorly investigated. To date, few reports have centered on the pathogenicity functions of fungal phytopathogen conidia. Pseudocercospora fijiensis is a hemibiotrophic fungus and the causal agent of the black Sigatoka disease in bananas and plantains. Here, a conidial transcriptome of P. fijiensis was characterized computationally. Carbohydrates, amino acids, and lipid metabolisms presented the highest number of annotations in Gene Ontology. Common conidial functions were found, but interestingly, pathogenicity factors and effectors were also identified. Upon analysis of the resulting proteins against the Pathogen-Host Interaction (PHI) database, 754 hits were identified. WideEffHunter and EffHunter effector predictors identified 618 effectors, 265 of them were shared with the PHI database. A total of 1107 conidial functions devoted to pathogenesis were found after our analysis. Regarding the conidial effectorome, it was found to comprise 40 canonical and 578 non-canonical effectors. Effectorome characterization revealed that RXLR, LysM, and Y/F/WxC are the largest effector families in the P. fijiensis conidial effectorome. Gene Ontology classification suggests that they are involved in many biological processes and metabolisms, expanding our current knowledge of fungal effectors.
ABSTRACT
As for 2020 only two complete genomes of Human papillomavirus type 13 (HPV13) are publicly available in GenBank database. In addition, reports of partial sequences of genetic regions are very limited. Therefore, genomic research that contributes to knowledge of viral components involved in HPV13 pathogenesis, and molecular mechanisms associated to multifocal epithelial hyperplasia (MEH) disease are urged. In the accompanying paper [1], we aimed to obtain the complete genome sequence of HPV13 associated to MEH disease, obtained from a Mayan boy living in Yucatan, Mexico. Coding sequences were annotated, and viral proteins traduced and deposited in GenBank with accession number MT068446. In this data report, we present the oligonucleotide list used to amplify the complete genome, a graphical abstract of process employed for the amplification of circular HPV13 genome, a representative figure of PCR products obtained for sequencing and multiple sequence alignments with the translated coding sequences of the existing genomes: X62843 is the first HPV13 genome reported [2]; it was generated from a clone obtained from a Turkish patient; DQ344807 was originally obtained from a patient in the Amazonian region [3]. The multiple sequence alignments show the main viral proteins (predicted). This provides relevant information for future molecular analysis and epidemiological studies because HPV13 is an understudied genotype associated to a neglected disease that appears more commonly in children. Additionally, the description of the methods can help in future sequencing of HPV genomes. We hope that our solutions will help researchers who do not have next-generation sequencing (NGS) platforms. A more comprehensive analysis of this data may be obtained from "Genomic characterization of Human papillomavirus type 13, associated to Multifocal Epithelial Hyperplasia, in a Mayan community" [1].
ABSTRACT
Human papillomavirus type 13 (HPV13) is a low-risk HPV type associated with Multifocal Epithelial Hyperplasia (MEH). It is considered a rare pathology of oral mucosa, more prevalent in certain ethnical groups, such as the Maya from Yucatan in Mexico. As for 2020 only two complete genomes of HPV13 are publicly available in Genbank database (one from Turkey one from the Amazonian). We aimed to obtain the complete genome sequence of HPV13 associated to MEH, obtained from a community in the Mayan area from Mexico. A bank of oral swabs from children with MEH were used. To enrich the sample, a Rolling Cycle Amplification (RCA) method was performed followed by overlapping end-point PCR of 500â¯bp fragments, Sanger sequencing and assembly. Eight open reading frames (ORFs) were annotated (E1, E2, E4, E5, E6, E7, L1 and L2 genes). When compared with the other two previously reported genomes the identity at nucleotide level is high 98.9% and 99.6%, respectively. The phylogenetic tree shows that Yucatan HPV13 is more closely related to HPV13 obtained from the Amazonian. Most changes identified at amino acid level are substitutions derived from nucleotide variations or SNPs in coding regions. Amino-acid changes were observed in E2 and E1 proteins (nâ¯≥â¯8), and in L1, L2, E6 and E5 proteins (nâ¯≤â¯5). E7 protein from Yucatan has 100% identity with the reported from Amazonian and differs (94.1% identity) with the one from Turkey due to 3 substitutions and three missing amino acids. In conclusion, the genome from HPV13 (7831â¯bp, 49â¯nt missing) associated to MEH in the Mayan area from Yucatan was obtained from stored swabs; this is the first effort in Mexico, the second in Latin America, and the third of the world. More research that contributes to the knowledge of the determinants underlying this neglected pathology are urged.
