Your search keyword '"Low, Eng-Ti Leslie"' showing total 3 results

1. Loss of Karma transposon methylation underlies the mantled somaclonal variant of oil palm

Author

Ong-Abdullah, Meilina, Ordway, Jared M., Jiang, Nan, Ooi, Siew-Eng, Kok, Sau-Yee, Sarpan, Norashikin, Azimi, Nuraziyan, Hashim, Ahmad Tarmizi, Ishak, Zamzuri, Rosli, Samsul Kamal, Malike, Fadila Ahmad, Bakar, Nor Azwani Abu, Marjuni, Marhalil, Abdullah, Norziha, Yaakub, Zulkifli, Amiruddin, Mohd Din, Nookiah, Rajanaidu, Singh, Rajinder, Low, Eng-Ti Leslie, Chan, Kuang-Lim, Azizi, Norazah, Smith, Steven W., Bacher, Blaire, Budiman, Muhammad A., Van Brunt, Andrew, Wischmeyer, Corey, Beil, Melissa, Hogan, Michael, Lakey, Nathan, Lim, Chin-Ching, Arulandoo, Xaviar, Wong, Choo-Kien, Choo, Chin-Nee, Wong, Wei-Chee, Kwan, Yen-Yen, Alwee, Sharifah Shahrul Rabiah Syed, Sambanthamurthi, Ravigadevi, and Martienssen, Robert A.

Published

2015

2. The oil palm SHELL gene controls oil yield and encodes a homologue of SEEDSTICK

Author

Singh, Rajinder, Low, Eng-Ti Leslie, Ooi, Leslie Cheng-Li, Ong-Abdullah, Meilina, Ting, Ngoot-Chin, Nagappan, Jayanthi, and Nookiah, Rajanaidu

Subjects

Plant breeding -- Methods -- Genetic aspects -- Analysis, Arabidopsis -- Genetic aspects -- Methods -- Analysis, Oil palm -- Genetic aspects -- Production data, Homology (Biology) -- Analysis -- Genetic aspects -- Methods, Environmental issues, Science and technology, Zoology and wildlife conservation

Abstract

Genetic mapping and whole-genome sequencing studies identify the SHELL gene (a homologue of Arabidopsis SEEDSTICK) as responsible for the three different fruit forms in oil palm (Elaeis guineesis); this has important economic implications for modulating SHELL activity to breed desired fruit forms and enhance oil yields. Oil palm genome reveals history of cultivation Two papers published in this issue of Nature deal with the genetics of two variants of one of the most important crops in use today -- the African oil palm Elaeis guineensis and its South American cousin Elaeis oleifera. Palm oil accounts for almost half the edible oil consumed worldwide and is also a biofuel, although not without controversy, as in many areas palm oil monoculture has replaced valuable natural forest. Analyses of the 1.8-gigabase genome sequence of E. guineensis and draft sequence of E. oleifera provide insights into oil biosynthesis genes and their regulators, and a record of genome evolution. A key event in the domestication and breeding of the oil palm was loss of the thick, coconut-like shell. The second of the two papers identifies mutations the SHELL gene that specify the different fruit forms found in the oil palm and shows that SHELL gene mutations that originated in pre-colonial Africa are responsible for the single gene hybrid vigour and high yields attained by the oil palm. A key event in the domestication and breeding of the oil palm Elaeis guineensis was loss of the thick coconut-like shell surrounding the kernel. Modern E. guineensis has three fruit forms, dura (thick-shelled), pisifera (shell-less) and tenera (thin-shelled), a hybrid between dura and pisifera.sup.1,2,3,4. The pisifera palm is usually female-sterile. The tenera palm yields far more oil than dura, and is the basis for commercial palm oil production in all of southeast Asia.sup.5. Here we describe the mapping and identification of the SHELL gene responsible for the different fruit forms. Using homozygosity mapping by sequencing, we found two independent mutations in the DNA-binding domain of a homologue of the MADS-box gene SEEDSTICK (STK, also known as AGAMOUS-LIKE 11), which controls ovule identity and seed development in Arabidopsis. The SHELL gene is responsible for the tenera phenotype in both cultivated and wild palms from sub-Saharan Africa, and our findings provide a genetic explanation for the single gene hybrid vigour (or heterosis) attributed to SHELL, via heterodimerization. This gene mutation explains the single most important economic trait in oil palm, and has implications for the competing interests of global edible oil production, biofuels and rainforest conservation.sup.6., Author(s): Rajinder Singh [sup.1] , Eng-Ti Leslie Low [sup.1] , Leslie Cheng-Li Ooi [sup.1] , Meilina Ong-Abdullah [sup.1] , Ngoot-Chin Ting [sup.1] , Jayanthi Nagappan [sup.1] , Rajanaidu Nookiah [sup.1] [...]

Published

2013

3. Oil palm genome sequence reveals divergence of interfertile species in Old and New worlds

Author

Singh, Rajinder, Ong-Abdullah, Meilina, Low, Eng-Ti Leslie, Manaf, Mohamad Arif Abdul, Rosli, Rozana, Nookiah, Rajanaidu, and Ooi, Leslie Cheng-Li

Subjects

Nucleotide sequence -- Analysis -- Comparative analysis -- Genetic aspects, Origin of species -- Comparative analysis -- Analysis -- Genetic aspects, Oil palm -- Genetic aspects -- Comparative analysis -- Analysis, Environmental issues, Science and technology, Zoology and wildlife conservation

Abstract

The genome sequence of the African oil palm, the main source of oil production, is used to predict at least 34,802 genes, including oil biosynthesis genes; comparison with the draft sequence of the South American oil palm reveals that the two species may have diverged in the New World and that segmental duplications of chromosome arms define the palaeotetraploid origin of palm trees. Oil palm genome reveals history of cultivation Two papers published in this issue of Nature deal with the genetics of two variants of one of the most important crops in use today -- the African oil palm Elaeis guineensis and its South American cousin Elaeis oleifera. Palm oil accounts for almost half the edible oil consumed worldwide and is also a biofuel, although not without controversy, as in many areas palm oil monoculture has replaced valuable natural forest. Analyses of the 1.8-gigabase genome sequence of E. guineensis and draft sequence of E. oleifera provide insights into oil biosynthesis genes and their regulators, and a record of genome evolution. A key event in the domestication and breeding of the oil palm was loss of the thick, coconut-like shell. The second of the two papers identifies mutations the SHELL gene that specify the different fruit forms found in the oil palm and shows that SHELL gene mutations that originated in pre-colonial Africa are responsible for the single gene hybrid vigour and high yields attained by the oil palm. Oil palm is the most productive oil-bearing crop. Although it is planted on only 5% of the total world vegetable oil acreage, palm oil accounts for 33% of vegetable oil and 45% of edible oil worldwide, but increased cultivation competes with dwindling rainforest reserves. We report the 1.8-gigabase (Gb) genome sequence of the African oil palm Elaeis guineensis, the predominant source of worldwide oil production. A total of 1.535 Gb of assembled sequence and transcriptome data from 30 tissue types were used to predict at least 34,802 genes, including oil biosynthesis genes and homologues of WRINKLED1 (WRI1), and other transcriptional regulators.sup.1, which are highly expressed in the kernel. We also report the draft sequence of the South American oil palm Elaeis oleifera, which has the same number of chromosomes (2n = 32) and produces fertile interspecific hybrids with E. guineensis.sup.2 but seems to have diverged in the New World. Segmental duplications of chromosome arms define the palaeotetraploid origin of palm trees. The oil palm sequence enables the discovery of genes for important traits as well as somaclonal epigenetic alterations that restrict the use of clones in commercial plantings.sup.3, and should therefore help to achieve sustainability for biofuels and edible oils, reducing the rainforest footprint of this tropical plantation crop., Author(s): Rajinder Singh [sup.1] , Meilina Ong-Abdullah [sup.1] , Eng-Ti Leslie Low [sup.1] , Mohamad Arif Abdul Manaf [sup.1] , Rozana Rosli [sup.1] , Rajanaidu Nookiah [sup.1] , Leslie Cheng-Li [...]

Published

2013