Advances in Genetic Manipulation of Lignocellulose to Reduce BiomassRecalcitrance and Enhance Biofuel Production in Bioenergy Crops

Meysam Madadi
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引用次数: 12

Abstract

Lignocellulose biomass derived from plant cell walls is a rich source of biopolymers for the production of biofuels. Biomass recalcitrance is the noticeable and main features of lignocellulose which can reduces by genetic modification of plant cell wall. The aim of the present review is to provide the reader a new insight for enhancing biomass yield and biofuels production. This can be issued by focusing on major perennial grasses, cereal crops and woody feedstock which have high biomass yield or large biomass residues and also the effects of distinctive cell wall polymers (cellulose, hemicellulose, lignin, and pectin) on the enzymatic saccharification of biomass under different pretreatments. Moreover the present review paper will also major gene candidates which are involved plant cell wall biosynthesis, degradation and modification for improving biomass yield and digestibility in transgenic plants and genetic mutants.
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木质纤维素基因调控在生物能源作物中减少生物抗性和提高生物燃料产量的研究进展
来源于植物细胞壁的木质纤维素生物质是生产生物燃料的生物聚合物的丰富来源。生物量抗逆性是木质纤维素的主要特点,可通过对植物细胞壁进行基因改造来降低其抗逆性。本综述的目的是为读者提供提高生物质产量和生物燃料生产的新见解。这可以通过关注具有高生物质产量或大量生物质残留物的主要多年生草、谷类作物和木质原料以及不同细胞壁聚合物(纤维素、半纤维素、木质素和果胶)在不同预处理下对生物质酶糖化的影响来发布。此外,本文还综述了涉及植物细胞壁生物合成、降解和修饰的候选基因,以提高转基因植物和基因突变体的生物量产量和消化率。
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