Maxwell H. Gluck Equine Research Center, Department of Veterinary Science, University of Kentucky, Lexington, Kentucky, USA.
Center for Tropical and Emerging Global Diseases, University of Georgia, Athens, Georgia, USA.
mSphere. 2024 Jun 25;9(6):e0011124. doi: 10.1128/msphere.00111-24. Epub 2024 May 29.
Asexual replication in the apicomplexan involves two main developmental stages: the motile extracellular merozoite and the sessile intracellular schizont. Merozoites invade host cells and transform into schizonts that undergo replication via endopolygeny to form multiple (64) daughter merozoites that are invasive to new host cells. Given that the capabilities of the merozoite vary significantly from the schizont, the patterns of transcript levels throughout the asexual lifecycle were determined and compared in this study. RNA-Seq data were generated from extracellular merozoites and four intracellular schizont development time points. Of the 6,938 genes annotated in the genome, 6,784 were identified in the transcriptome. Of these, 4,111 genes exhibited significant differential expression between the merozoite and at least one schizont development time point. Transcript levels were significantly higher for 2,338 genes in the merozoite and 1,773 genes in the schizont stages. Included in this list were genes encoding the secretory pathogenesis determinants (SPDs), which encompass the surface antigen and SAG-related sequence (SAG/SRS) and the secretory organelle proteins of the invasive zoite stage (micronemes, rhoptries, and dense granules). As anticipated, many of the SPD gene transcripts were abundant in merozoites. However, several SPD transcripts were elevated in intracellular schizonts, suggesting roles unrelated to host cell invasion and the initial establishment of the intracellular niche. The hypothetical genes that are potentially unique to the genus are of particular interest. Their conserved expression patterns are instructive for future investigations into the possible functions of these putative -unique genes.
The genus is an expansive clade within the Apicomplexa, with the species being an important cause of neurological disease in horses. Research to decipher the biology of and its host-pathogen interactions can be enhanced by gene expression data. This study has identified conserved apicomplexan orthologs in , putative -unique genes, and gene transcripts abundant in the merozoite and schizont stages. Importantly, we have identified distinct clusters of genes with transcript levels peaking during different intracellular schizont development time points, reflecting active gene expression changes across endopolygeny. Each cluster also has subsets of transcripts with unknown functions, and investigation of these seemingly -unique transcripts will provide insights into the interesting biology of this parasite genus.
顶复门生物的无性繁殖包括两个主要的发育阶段:运动的细胞外裂殖子和静止的细胞内裂殖体。裂殖子侵入宿主细胞并转化为裂殖体,通过内共生进行复制,形成多个(64)侵袭新宿主细胞的子裂殖子。鉴于裂殖子的能力与裂殖体有很大的不同,本研究中确定并比较了无性生命周期中整个转录水平的模式。从细胞外裂殖子和四个细胞内裂殖体发育时间点生成了 RNA-Seq 数据。在 基因组中注释的 6938 个基因中,转录组中鉴定出 6784 个基因。其中,4111 个基因在裂殖子和至少一个裂殖体发育时间点之间表现出显著的差异表达。裂殖子中 2338 个基因和裂殖体阶段 1773 个基因的转录水平显著升高。包括分泌发病决定因素(SPD)的基因,这些基因包含表面抗原和 SAG 相关序列(SAG/SRS)以及侵袭zoite 阶段的分泌细胞器蛋白(微线体、棒状体和致密颗粒)。正如预期的那样,许多 SPD 基因转录本在裂殖子中丰富。然而,一些 SPD 转录本在细胞内裂殖体中升高,这表明它们与宿主细胞侵袭和细胞内小生境的初始建立无关。可能是属特有的假设基因特别有趣。它们保守的表达模式为进一步研究这些假定的独特基因的可能功能提供了线索。
属是顶复门中的一个广泛分支,其中 是马神经系统疾病的重要原因。为了解 的生物学及其与宿主的相互作用而进行的研究可以通过基因表达数据得到增强。本研究鉴定了 中的保守顶复门直系同源物、假定的独特基因以及裂殖子和裂殖体阶段丰度高的基因转录本。重要的是,我们确定了不同的基因簇,其转录本水平在不同的细胞内裂殖体发育时间点达到峰值,反映了内共生过程中基因表达的活跃变化。每个簇也有一部分具有未知功能的转录本,对这些看似独特的转录本的研究将深入了解这种寄生虫属的有趣生物学。
