Genomics for Plant and Animal
Leveraging high-quality, cost-effective sequencing to drive sustainability, biodiversity, and conservation.
At Complete Genomics, we are committed to advancing plant and animal genomics through cutting-edge sequencing technology. Our mission is to empower researchers with actionable genomic insights to address global challenges such as food security, biodiversity, and sustainability. Complete Genomics utilizes our innovative DNBSEQ™ technology to provide high-quality, cost-effective whole-genome sequencing and transcriptomics solutions.
Agrigenomics and Crop Improvement
Enhancing Crop Resilience and Productivity
Agri-scientists use DNBSEQ technology to create more resilient crops with improved nutritional content, addressing dietary needs and environmental challenges. By leveraging genomic insights they can accelerate breeding programs and enhance crop health, contributing to sustainable agriculture practices.
Learn how scientists at the Mississippi State University are using transcriptomic approaches to understand plant pathogens.
Animal Health and Breeding
Advancing Animal Science through Genomics
Leveraging advanced DNBSEQ technology, researchers can significantly enhance animal health and breeding programs. By analyzing genetic patterns related to inheritance, immunology, and domestication, they can develop more targeted disease prevention strategies and optimize breeding efficiency.
Learn how DNBSEQ technology is powering predictive breeding programs.
Biodiversity and Conservation
Unlocking Genomic Diversity for Conservation
Complete Genomics supports biodiversity conservation by providing cost-effective whole-genome sequencing solutions. These technologies are crucial for characterizing plant and animal species, informing conservation strategies, and protecting ecosystems.
See how initiatives like the National Tree Genomics program in Australia utilize DNBSEQ technology to drive conservation efforts and plant breeding.
Technology Spotlight: Spatial Transcriptomics
Recent advances in spatial transcriptomics are transforming our understanding of plant and animal biology. This technology allows researchers to study single cells in their spatial context, identifying cell types, reconstructing cell-fate lineages, and revealing cell-to-cell interactions. Spatial transcriptomics holds great promise for advancing critical aspects of plant biology and addressing long-standing challenges in non-model organisms.