Genetics and breeding of white button mushroom, Agaricus bisporus (Lange.) Imbach. - A comprehensive review

Mushroom Research Pub Date : 2019-08-01 DOI:10.36036/MR.28.1.2019.91938

Kamal Shwet, V. Sharma, G. Mamta, B. Anupam, S. Manjit

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引用次数: 2

Abstract

Breeding of white button mushroom ( Agaricus bisporus ) is a complex proposition due to its unusual secondary homothallic sexual behavior. The percentages of bi-, tri- and tetrasporic basidia found in A. bisporus are on an average 81 %, 18 %, and 1 %, respectively. Moreover, contrary to other basidiomycetous fungi, A. bisporus mycelium is multinucleate and lacks clamp connections. Hence, it is not easy to identify non-fertile isolates for hybrid breeding. The only method to identify non-fertile isolates is the fruiting trial. Despite its economic relevance, the breeding effort in white button mushroom was low due to its complicated life cycle and lack of knowledge. The strains of white button mushroom available in the world show high similarity with the strain U-3 and seem that almost all the available strains are derived from one strain U3. During last few decades, serious efforts were made to investigate the life cycle and breeding pattern. In 2007, the Joint Genome Institute, US Department of Energy (DOE), sequenced the whole genome of A. bisporus . The size of the genome sequence was found to be 31 Mb and number of chromosomes was 13 in A. bisporus variety Horst U1. Complete sequence of the mtDNA of A. bisporus was observed to be 135,005 bp and is available with its complete nuclear genome. Recently, authors have developed and released two browning resistant hybrids in this mushroom (NBS-1 and NBS-5) and identified WRKY transcription factors associated with abiotic stress tolerance and nucleotide binding site of disease resistance gene. Present communication reviews the studies undertaken on problems in breeding, life cycle patterns, mating systems, genetic diversity assessment, genome sequencing, classical and molecular breeding, and other genetic improvement approaches in this important crop all through the world along with authors own contribution in this field. This communication also put forward author’s view on the way forward to develop new high yielding, disease resistant and high quality strains.

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双孢蘑菇(Agaricus bisporus)的遗传选育Imbach。-全面检讨

双孢蘑菇(Agaricus bisporus)的繁殖是一个复杂的命题，因为它具有不同寻常的次级同性行为。双孢子草中双孢子、三孢子和四孢子担子的平均比例分别为81%、18%和1%。此外，与其他担子真菌不同，双孢酵母菌丝体是多核的，缺乏钳形连接。因此，鉴定非育性分离株用于杂交育种并不容易。鉴定不育菌株的唯一方法是结果试验。尽管具有经济意义，但由于其复杂的生命周期和缺乏知识，育种努力较低。世界上现有的白纽扣菌菌株与菌株U-3具有很高的相似性，似乎几乎所有的菌株都是由一个菌株U3衍生而来。在过去的几十年里，人们对它们的生命周期和繁殖模式进行了认真的研究。2007年，美国能源部联合基因组研究所(DOE)对双孢菌的全基因组进行了测序。双孢菇品种单孢菌(U1)基因组序列大小为31 Mb，染色体数为13条。双孢螺旋藻mtDNA的完整序列为135,005 bp，具有完整的核基因组。近年来，作者培育并释放了两个抗褐变的菌种NBS-1和NBS-5，并鉴定出与非生物胁迫耐受性和抗病基因核苷酸结合位点相关的WRKY转录因子。本文综述了世界各国对这一重要作物在育种、生命周期模式、交配系统、遗传多样性评估、基因组测序、经典育种和分子育种以及其他遗传改良方法等方面所进行的研究以及作者在这一领域的贡献。本文还对今后培育高产、抗病、优质新品种提出了自己的看法。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Mushroom Research

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