Researchers at NYU Abu Dhabi’s Center for Genomics and Systems Biology and the UAEU Khalifa Center for Genetic Engineering and Biotechnology, working with other institutions, have developed an improved assembly of the genome for the date palm using long-read sequencing technology. This improvement over the current versions of the genome will help advance further research, and also inform the propagation practices of this essential MENA region food source.

In addition, the researchers have identified the genes and mutations that lead to color change and the levels of major sugars in date palm fruit, including the genes for the enzyme invertase that breaks down sucrose into glucose and fructose. The mapping of these fruit color and sugar genes was conducted using genome-wide association studies (GWAS).  GWAS has been used for mapping important disease genes in humans, and this is the first time it has been applied to date palms.

While date palms (Phoenix dactylifera) are one of the earliest domesticated tree crops in the world and remain a major fruit crop in North Africa and the Middle East, few genomic resources exist. This, combined with long generation times, has limited evolutionary genomic studies of this perennial species.

Researchers report they have produced an improved genome assembly for date palms that is 18 percent larger and more contiguous than existing genome assemblies. This long-read genome sequence assembly, coupled with access to two large, mature date palm orchards in the United Arab Emirates, allowed them to conduct genome-wide association mapping in this species. 

As a result, they successfully mapped the previously-identified sex determination locus and genes for both fruit color and sugar level polymorphisms. Their findings are published in the journal Nature Communications.

“As we face challenges in food security for the future, we will need to continue to study the genome of food crops like date palm to help us in our struggle to provide food security in the world,” said Silver Professor of Biology at New York University and lead scientist on the paper Michael Purugganan. “Our progress in expanding the genome of the date palm is finally unlocking some of the secrets that explain how this tree species has continued to thrive in varied, challenging ecosystems.”

Global Collaboration

The sequencing of the date palm genome and the first GWAS mapping in this fruit tree was an international effort led by NYUAD and KCGEB, and also included researchers in the US, Switzerland, France, UK, Saudi Arabia, and Mexico.

Read the paper: Nature Communications

Article source: NYU Abu Dhabi

Image credit: malubeng / Pixabay