Mehra L K, MacLean D D, Savelle A T, Scherm H
Department of Plant Pathology, University of Georgia, Athens 30602.
Department of Horticulture, University of Georgia, Tifton 31793.
Plant Dis. 2013 Feb;97(2):213-221. doi: 10.1094/PDIS-03-12-0307-RE.
Postharvest decay, incited by various fungal pathogens, is a major concern in most blueberry production areas of the United States. Because the risk of infection is increased by fruit bruising, which in turn is increased by machine-harvesting, it has been difficult to harvest fruit from the early-maturing but soft-textured southern highbush blueberries (SHB) mechanically for the fresh market. This could change fundamentally with the recent development of SHB genotypes with crisp-textured ("crispy") berries, i.e., fruit with qualitatively firmer flesh and/or more resistant skin. Four replicate row sections of two or three SHB genotypes having crispy fruit and three with conventional fruit were either hand- or machine-harvested at a commercial blueberry farm in northern Florida in April 2009 and May 2010. Harvested fruit were sorted, packed, and placed in cold storage (2°C) for up to 3 weeks. Average counts of aerobic bacteria, total yeasts and molds, coliforms, and Escherichia coli on fruit samples before the cold storage period were below commercial tolerance levels in most cases. In both years, natural disease incidence after cold storage was lowest for hand-harvested crispy fruit and highest for machine-harvested conventional fruit. Interestingly, machine-harvested crispy fruit had the same or lower disease incidence as hand-harvested conventional fruit. Across all treatments, natural postharvest disease incidence was inversely related to fruit firmness, with firmness values >220 g/mm associated with low disease. In separate experiments, samples from the 0-day cold storage period were inoculated at the stem end with Alternaria alternata, Botrytis cinerea, or Colletotrichum acutatum, and disease incidence was assessed after 7 days in a cold room followed by 60 to 72 h at room temperature. In response to artificial inoculation, less disease developed on crispy berries. No significant effect of harvest method was observed, except for A. alternata inoculation in 2009, when hand-harvested fruit developed a lower level of disease than machine-harvested fruit. Taken together, this study suggests that mechanical harvesting of SHB cultivars with crisp-textured berries is feasible from a postharvest pathology perspective.
由多种真菌病原体引发的采后腐烂是美国大多数蓝莓产区的一个主要问题。由于果实擦伤会增加感染风险,而机械采收又会加剧果实擦伤,因此对于早熟但质地柔软的南方高丛蓝莓(SHB)来说,很难通过机械采收来供应新鲜市场。不过,随着最近具有脆质地(“酥脆”)浆果的SHB基因型的培育成功,这种情况可能会从根本上改变,即果实具有质地更坚实的果肉和/或更具抗性的果皮。2009年4月和2010年5月,在佛罗里达州北部的一个商业蓝莓农场,对两到三种具有脆果的SHB基因型以及三种具有常规果实的SHB基因型的四个重复行段进行了手工采收或机械采收。采收后的果实经过分拣、包装,然后置于冷藏库(2°C)中长达3周。在大多数情况下,冷藏期前果实样本上的需氧菌、总酵母菌和霉菌、大肠菌群以及大肠杆菌的平均计数均低于商业容忍水平。在这两年中,冷藏后的自然发病率在手工采收的脆果中最低,在机械采收的常规果实中最高。有趣的是,机械采收的脆果发病率与手工采收的常规果实相同或更低。在所有处理中,采后自然发病率与果实硬度呈负相关,硬度值>220 g/mm的果实发病率较低。在单独的实验中,将冷藏0天的果实样本在果梗端接种链格孢、灰霉病菌或尖孢炭疽菌,在冷藏室放置7天后,再在室温下放置60至72小时,然后评估发病率。在人工接种的情况下,脆浆果上的病害发展较少。除了2009年接种链格孢时,手工采收果实的病害程度低于机械采收果实外,未观察到采收方法的显著影响。综合来看,这项研究表明,从采后病理学角度来看,对具有脆质地浆果的SHB品种进行机械采收是可行的。
