Genome Engineering for Crop Improvement. Группа авторов
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Название: Genome Engineering for Crop Improvement

Автор: Группа авторов

Издательство: John Wiley & Sons Limited

Жанр: Биология

Серия:

isbn: 9781119672401

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СКАЧАТЬ species such as wheat.

      Maize (Zea mays L.) is a widely grown C4 crop with a high rate of photosynthetic activity leading to high grain and biomass yield potential and most produced grain crop globally. The maize genome is genetically diploid and consists of 10 chromosomes with an estimate size ranging from 2.3 to 2.7 Gb (Schnable et al. 2009). The maize genome consists mostly of a non‐genic, repetitive fraction punctuated by islands of unique, or low‐copy DNA that harbor single genes or small groups of genes. The repetitive elements contribute significantly to the wide range of diversity within the species and include transposable elements, ribosomal DNA, and high‐copy short‐tandem repeats mostly present at the telomeres, centromeres, and heterochromatin knobs (Morgante 2006). It has been reported that approximately, 62 million tonnes maize was produced around the globe during the year 2019 (FAO (Food and Agriculture Organization of The United Nations) Statistics 2019–20). Its myriad end uses and the ease of cultivation over varied environmental and soil conditions has made it a desirable crop worldwide. In addition to human consumption, it is used as feed for livestock, raw materials for chemical and food industries and as biofuel (Pegoraro et al. 2011).

      Cotton is an important crop for the production of fiber, oil and biofuel. In addition, cotton serves as a cash crop for more than 20 million farmers in Asia and Africa. Despite the availability of synthetic alternatives, cotton remains an important source of fiber because of the advantages related to cost of production and unique features offered by cotton lint. Consumption of cotton products in the world is increasing day by day in a lot of places, but world cotton production is stagnant because of biotic and abiotic stresses. To meet the demands of the masses, production of cotton needs to be very high, with good quality. Cotton is also affected by diseases, causing significant losses to industry. Therefore, it became evident to utilize plant‐breeding approaches to tackle threats caused by both biotic and abiotic factors ultimately reducing fiber quality.

      Cotton fiber quality is directly related to boost the economy determining the income of almost 100 million families from more than 100 countries (Guan et al. 2014). Tetraploid cotton retains special features such as larger fiber length and fiber strength to facilitate more spinnable cotton. Cotton fibers contain single‐celled trichomes originating from outer integument cells of the ovular surface. Fiber developmental mechanisms comprising four levels, fiber‐cell initiation, elongation, secondary cell wall biosynthesis and maturation (Manik and Ravikesavan 2009). The overlapping developmental stages have some special features differentiating cellular and physiology. This is due to complexity of cotton fiber transcriptome involving ~18 000 and 36 000 genes in diploid and allotetraploid cotton genomes, respectively (Arpat et al. 2004). Several key fiber‐related genes have been identified creating interest to study their functions and subsequent improvement of enhance fiber quality. Some key genes including E6 (John and Crow 1992), GhExp1 (Harmer et al. 2002), GhSusA1 (Jiang et al. 2012), PIP2s (Li et al. 2013) and GA20ox (Bai et al. 2014) were reported predominantly expressed during fiber initiation, secondary cell wall biosynthesis (Brill et al. 2011), and fiber elongation (Yang СКАЧАТЬ