Professor Patrick Maxwell, from the Institute of Medical Research at the University of Cambridge in the U. K., comments on the research results via video Thursday. Courtesy of BGI•Research

Researchers from BGI•Research and research teams from China, Germany, Italy, Singapore, Spain, Sweden and the U.K. have completed the single-cell transcriptome of long-tailed macaque (cynomolgus) monkeys, BGI Group announced Thursday at the National Gene Bank in Dapeng New District.

This breakthrough, which could lead to scientific advancement in the treatment of human diseases, was published in the scientific journal Nature on Wednesday. By using BGI’s independently developed DNBelab C4 single-cell library platform, researchers from BGI, Jilin University, Guangzhou Institutes of Biomedicine and Health, Chinese Academy of Sciences and 32 other international institutions completed the single-cell transcriptome of 45 tissues and organs from long-tailed macaque (cynomolgus) monkeys, obtaining a total of 1.14 million single-cell data and identifying 113 major cell types.

“Single-cell research is transforming our understanding of tissue and organ functions at a cellular level, which informs how diseases develop and how they can be treated,” said Liu Longqi from BGI•Research, one of the corresponding authors of the paper.

“Having a whole-body organ single-cell map of the adult macaque will significantly improve the ability to pinpoint how to develop potential treatments for human diseases with greater precision,” Liu said.

By mapping the macaque transcriptome at the single-cell level, scientists now have a database or single-cell library that can be used for developing methods for human disease diagnosis and treatment, assessment of clinical drug efficacy, analysis of cell evolution among species and analysis of advanced cognitive functions of the brain.

“By understanding cell types and their characteristics, scientists will be able to predict the impact of disease treatments on specific cell structures and thus develop more targeted approaches for single-gene or complex genetic diseases,” said co-corresponding author Xu Xun, director of BGI•Research.

Single-cell mapping allowed the team to identify the cell types that may contribute to human disease or make individuals more susceptible to the disease. For example, in COVID-19, the biggest manifestation is pneumonia because SARS-CoV-2 infects a small group of cells in the lungs. However, the single-cell mapping of macaque also identified certain cells in other tissues that can become infected. This can help doctors understand where to look for signs of COVID-19.

Single-cell mapping can also help identify which cells metabolize calories from fat, allowing researchers to comprehend underlying contributors to obesity. Likewise, this process could help identify which cells regulate neuronal circuits in the brain, leading to potential treatments for neurological diseases.

“This study fills the gap of the single-cell map of nonhuman primates and is a rich data resource that will serve as a very important reference for future species evolution, brain science, drug evaluation and screening, and preclinical research studies,” said another co-corresponding author Miguel A. Esteban from Jilin University and the Guangzhou Institutes of Biomedicine and Health, Chinese Academy of Sciences.