RESUMO
A total of two lineages of Mycobacterium tuberculosis var. africanum (Maf), L5 and L6, which are members of the Mycobacterium tuberculosis complex (MTBC), are responsible for causing tuberculosis in West Africa. Regions of difference (RDs) are usually used for delineation of MTBC. With increased data availability, single nucleotide polymorphisms (SNPs) promise to provide better resolution. Publicly available 380 Maf samples were analyzed for identification of "core-cluster-specific-SNPs," while additional 270 samples were used for validation. RD-based methods were used for lineage-assignment, wherein 31 samples remained unidentified. The genetic diversity of Maf was estimated based on genome-wide SNPs using phylogeny and population genomics approaches. Lineage-based clustering (L5 and L6) was observed in the whole genome phylogeny with distinct sub-clusters. Population stratification using both model-based and de novo approaches supported the same observations. L6 was further delineated into three sub-lineages (L6.1-L6.3), whereas L5 was grouped as L5.1 and L5.2 based on the occurrence of RD711. L5.1 and L5.2 were further divided into two (L5.1.1 and L5.1.2) and four (L5.2.1-L5.2.4) sub-clusters, respectively. Unassigned samples could be assigned to definite lineages/sub-lineages based on clustering observed in phylogeny along with high-confidence posterior membership scores obtained during population stratification. Based on the (sub)-clusters delineated, "core-cluster-specific-SNPs" were derived. Synonymous SNPs (137 in L5 and 128 in L6) were identified as biomarkers and used for validation. Few of the cluster-specific missense variants in L5 and L6 belong to the central carbohydrate metabolism pathway which include His6Tyr (Rv0946c), Glu255Ala (Rv1131), Ala309Gly (Rv2454c), Val425Ala and Ser112Ala (Rv1127c), Gly198Ala (Rv3293) and Ile137Val (Rv0363c), Thr421Ala (Rv0896), Arg442His (Rv1248c), Thr218Ile (Rv1122), and Ser381Leu (Rv1449c), hinting at the differential growth attenuation. Genes harboring multiple (sub)-lineage-specific "core-cluster" SNPs such as Lys117Asn, Val447Met, and Ala455Val (Rv0066c; icd2) present across L6, L6.1, and L5, respectively, hinting at the association of these SNPs with selective advantage or host-adaptation. Cluster-specific SNPs serve as additional markers along with RD-regions for Maf delineation. The identified SNPs have the potential to provide insights into the genotype-phenotype correlation and clues for endemicity of Maf in the African population.
RESUMO
Fungal keratitis is a serious, potentially sight-threatening corneal infection that is more prevalent in the tropical parts of the world including India, and A. flavus and Fusarium solani are the predominant etiological agents. The surface of fungal conidia is covered by hydrophobin family proteins, effectively masking the conidial antigens from immune cells. In this study, we report that the outer cell wall layer of A. flavus conidia contain Rod A as well as other hydrophobins, which could be extracted by formic acid. Analysis of these surface proteins by mass spectrometry showed the presence of rodlet forming hydrophobins and other membrane and antigenic proteins. Our analysis revealed that Rod A existed as two proteoforms on the conidial surface. These proteoforms were separated using polyacrylamide gel electrophoresis and the amino acid sequence of these proteoforms was determined by high resolution mass spectrometry. PCR analysis of the mRNA encoding the Rod A showed the retention of intron one, which results in the formation of a truncated proteoform two. This is the first report in which the presence of RodA and its proteoforms and their mechanism of formation has been demonstrated in the corneal pathogenic fungus A. flavus. SIGNIFICANCE: A. flavus is a common fungal pathogen in tropical countries playing a predominant role in causing mycotic keratitis in humans. Surface of fungal conidia is immunologically inert primarily due to the hydrophobin family proteins forming a rodlet layer and masking the conidia from immune cells. In this study we demonstrated the existence two proteoforms of RodA/hydrophobin A and intron retention is shown to be responsible for the formation of one of the proteoforms. In addition, the spore surface proteins of A.flavus corneal isolates and saprophyte are distinctly different, which indicate the spore surface protein profile is ecotype specific. This is the first report showing the presence of two proteoforms of RodA on A.flavus conidial surface and demonstration of the mechanism of formation of the proteoforms.
