Genomics and Computational Biology, University of Pennsylvania, Philadelphia, PA 19104, USA.
BMC Genomics. 2010 Oct 25;11:603. doi: 10.1186/1471-2164-11-603.
Microarrays are invaluable tools for genome interrogation, SNP detection, and expression analysis, among other applications. Such broad capabilities would be of value to many pathogen research communities, although the development and use of genome-scale microarrays is often a costly undertaking. Therefore, effective methods for reducing unnecessary probes while maintaining or expanding functionality would be relevant to many investigators.
Taking advantage of available genome sequences and annotation for Toxoplasma gondii (a pathogenic parasite responsible for illness in immunocompromised individuals) and Plasmodium falciparum (a related parasite responsible for severe human malaria), we designed a single oligonucleotide microarray capable of supporting a wide range of applications at relatively low cost, including genome-wide expression profiling for Toxoplasma, and single-nucleotide polymorphism (SNP)-based genotyping of both T. gondii and P. falciparum. Expression profiling of the three clonotypic lineages dominating T. gondii populations in North America and Europe provides a first comprehensive view of the parasite transcriptome, revealing that ~49% of all annotated genes are expressed in parasite tachyzoites (the acutely lytic stage responsible for pathogenesis) and 26% of genes are differentially expressed among strains. A novel design utilizing few probes provided high confidence genotyping, used here to resolve recombination points in the clonal progeny of sexual crosses. Recent sequencing of additional T. gondii isolates identifies >620 K new SNPs, including ~11 K that intersect with expression profiling probes, yielding additional markers for genotyping studies, and further validating the utility of a combined expression profiling/genotyping array design. Additional applications facilitating SNP and transcript discovery, alternative statistical methods for quantifying gene expression, etc. are also pursued at pilot scale to inform future array designs.
In addition to providing an initial global view of the T. gondii transcriptome across major lineages and permitting detailed resolution of recombination points in a historical sexual cross, the multifunctional nature of this array also allowed opportunities to exploit probes for purposes beyond their intended use, enhancing analyses. This array is in widespread use by the T. gondii research community, and several aspects of the design strategy are likely to be useful for other pathogens.
微阵列是基因组研究、单核苷酸多态性检测和表达分析等应用中非常有价值的工具。这些广泛的功能对于许多病原体研究社区都将具有重要意义,尽管开发和使用基因组规模的微阵列通常是一项昂贵的工作。因此,对于许多研究人员来说,找到一种既能降低不必要的探针数量,又能保持或扩展功能的有效方法将是非常重要的。
利用已有的基因组序列和对弓形虫(一种导致免疫功能低下个体发病的致病性寄生虫)和疟原虫(一种相关的寄生虫,可导致严重的人类疟疾)的注释,我们设计了一种单核苷酸微阵列,它可以以相对较低的成本支持广泛的应用,包括对弓形虫的全基因组表达谱分析,以及基于单核苷酸多态性(SNP)的弓形虫和疟原虫的基因分型。对北美和欧洲流行的三种克隆型弓形虫群体的表达谱分析,首次全面揭示了寄生虫转录组的全貌,表明~49%的所有注释基因在寄生虫速殖子(负责发病机制的急性裂解阶段)中表达,26%的基因在菌株之间差异表达。一种利用少量探针的新型设计提供了高可信度的基因分型,在这里用于解决有性杂交克隆后代中的重组点。最近对更多弓形虫分离株的测序确定了超过 620000 个新的 SNP,其中约 11000 个与表达谱探针相交,为基因分型研究提供了更多的标记,并进一步验证了组合表达谱/基因分型阵列设计的实用性。还以试点规模开展了其他应用,以促进 SNP 和转录本的发现,用于定量基因表达的替代统计方法等,为未来的阵列设计提供信息。
除了提供主要谱系的弓形虫转录组的全局视图,并允许对历史有性杂交中的重组点进行详细解析外,这种多功能微阵列还为利用探针进行预期用途以外的目的提供了机会,从而增强了分析能力。这种微阵列已被弓形虫研究社区广泛使用,其设计策略的几个方面可能对其他病原体也有用。
