The Microbial Diversity in Relation to Postharvest Quality and Decay: Organic vs. Conventional Pear Fruit

(1) Background: Organic food produced in environmentally friendly farming systems has become increasingly popular. (2) Methods: We used a DNA metabarcoding approach to investigate the differences in the microbial community between organic and conventional ‘Huangguan’ pear fruit; and (3) Results: Compared to a conventional orchard, the fruit firmness in the organic orchard had significantly lowered after 30 days of shelf-life storage at 25 °C, and the soluble solids content (SSC), titratable acid (TA), and decay index were higher. There were differences in the microbial diversity between organic and conventional orchards pears. After 30 days of storage, Fusarium and Starmerella became the main epiphytic fungi in organic fruits, while Meyerozyma was dominant in conventional fruits. Gluconobacter, Acetobacter, and Komagataeibacter were dominant epiphytic bacteria on pears from both organic and conventional orchards after a 30-day storage period. Bacteroides, Muribaculaceae, and Nesterenkonia were the main endophytic bacteria throughout storage. There was a negative correlation between fruit firmness and decay index. Moreover, the abundance of Acetobacter and Starmerella were positively correlated with fruit firmness, while Muribaculaceae was negatively correlated, implying that these three microorganisms may be associated with the postharvest decay of organic fruit; (4) Conclusions: The difference in postharvest quality and decay in organic and conventional fruits could potentially be attributed to the variation in the microbial community during storage.

[1]  Yudou Cheng,et al.  Mycotoxin Production and the Relationship between Microbial Diversity and Mycotoxins in Pyrus bretschneideri Rehd cv. Huangguan Pear , 2022, Toxins.

[2]  Luqi Huang,et al.  ImageGP: An easy‐to‐use data visualization web server for scientific researchers , 2022, iMeta.

[3]  P. Thonart,et al.  Acetobacter senegalensis isolated from mango fruits: Its polyphasic characterization and adaptation to protect against stressors in the industrial production of vinegar: A review , 2022, Journal of applied microbiology.

[4]  M. Battino,et al.  Organic vs conventional plant-based foods: A review. , 2022, Food chemistry.

[5]  Yudou Cheng,et al.  Dynamic Microbiome Changes Reveal the Effect of 1-Methylcyclopropene Treatment on Reducing Post-harvest Fruit Decay in “Doyenne du Comice” Pear , 2021, Frontiers in Microbiology.

[6]  E. Muzzi,et al.  Does Organic Farming Increase Raspberry Quality, Aroma and Beneficial Bacterial Biodiversity? , 2021, Microorganisms.

[7]  D. Crowder,et al.  Orchard Management and Landscape Context Mediate the Pear Floral Microbiome , 2021, Applied and environmental microbiology.

[8]  Shiri Freilich,et al.  Compositional shifts in the strawberry fruit microbiome in response to near-harvest application of Metschnikowia fructicola, a yeast biocontrol agent , 2021 .

[9]  M. Gullino,et al.  Characterization of Alternaria Species Associated with Heart Rot of Pomegranate Fruit , 2021, Journal of fungi.

[10]  A. Mushunje,et al.  The willingness to consume organic food: A review , 2021, Food and Agricultural Immunology.

[11]  M. Jiang,et al.  Biotechnological applications of the non-conventional yeast Meyerozyma guilliermondii. , 2020, Biotechnology advances.

[12]  Haishun Du,et al.  Variable characteristics of microbial communities on the surface of sweet cherries under different storage conditions , 2020 .

[13]  A. Chakraborty,et al.  Plant microbiome–an account of the factors that shape community composition and diversity , 2020 .

[14]  X. Y. Zhao,et al.  First Report of Fruit Rot on ‘Cuiguan’ Pear Caused by Fusarium proliferatum in China , 2020 .

[15]  F. Nunes,et al.  Effect of agricultural practices, conventional vs organic, on the phytochemical composition of 'Kweli' and 'Tulameen' raspberries (Rubus idaeus L.). , 2020, Food chemistry.

[16]  S Kumar,et al.  Fertilizers and Pesticides: Their Impact on Soil Health and Environment , 2020 .

[17]  E. Hallmann,et al.  The effects of organic and conventional farm management and harvest time on the polyphenol content in different raspberry cultivars. , 2019, Food chemistry.

[18]  Xiaofei Chen,et al.  Occurrence of black leaf spot caused by Alternaria alternata on Korla fragrant pear in Xinjiang of China , 2019, Journal of Plant Pathology.

[19]  G. Berg,et al.  An Apple a Day: Which Bacteria Do We Eat With Organic and Conventional Apples? , 2019, Front. Microbiol..

[20]  R. Harrison,et al.  Genomics Evolutionary History and Diagnostics of the Alternaria alternata Species Group Including Apple and Asian Pear Pathotypes , 2019, bioRxiv.

[21]  G. Berta,et al.  Impact of Beneficial Microorganisms on Strawberry Growth, Fruit Production, Nutritional Quality, and Volatilome , 2018, Front. Plant Sci..

[22]  Youming Shen,et al.  Compositional shifts in the surface fungal communities of apple fruits during cold storage , 2018, Postharvest Biology and Technology.

[23]  P. Jacques,et al.  Lipopeptide biodiversity in antifungal Bacillus strains isolated from Algeria , 2018, Archives of Microbiology.

[24]  Xiangyu Gu,et al.  Control of postharvest blue mold decay in pears by Meyerozyma guilliermondii and it’s effects on the protein expression profile of pears , 2018 .

[25]  Ji Tian,et al.  Effects of apple fruit fermentation (AFF) solution on growth and fruit quality of apple trees , 2018, Brazilian Journal of Botany.

[26]  S. Shohaimi,et al.  Genetic diversity and pathogenicity of Fusarium species associated with fruit rot disease in banana across Peninsular Malaysia , 2017, Journal of applied microbiology.

[27]  L. Cocolin,et al.  Starmerella bacillaris in winemaking: opportunities and risks , 2017 .

[28]  F. De Filippis,et al.  Different Amplicon Targets for Sequencing-Based Studies of Fungal Diversity , 2017, Applied and Environmental Microbiology.

[29]  V. Seufert,et al.  What is this thing called organic? – How organic farming is codified in regulations , 2017 .

[30]  G. Munkvold Fusarium Species and Their Associated Mycotoxins. , 2017, Methods in molecular biology.

[31]  A. Glenn,et al.  A Novel Population of Fusarium fujikuroi Isolated from Southeastern U.S. Winegrapes Reveals the Need to Re-Evaluate the Species’ Fumonisin Production , 2016, Toxins.

[32]  S. Pascale,et al.  “Physiological quality” of organically grown vegetables , 2016 .

[33]  M. Finckh,et al.  Plant Diseases and Management Approaches in Organic Farming Systems. , 2016, Annual review of phytopathology.

[34]  Şeyma Arıkan,et al.  Effects of Plant Growth Promoting Rhizobacteria (PGPR) on Growth, Yield and Fruit Quality of Sour Cherry (Prunus cerasus L.) , 2016, Erwerbs-Obstbau.

[35]  Paul J. McMurdie,et al.  DADA2: High resolution sample inference from Illumina amplicon data , 2016, Nature Methods.

[36]  Duolong Di,et al.  The Bioactive Secondary Metabolites from Talaromyces species , 2016, Natural Products and Bioprospecting.

[37]  E. Baraldi,et al.  Activities of Aureobasidium pullulans cell filtrates against Monilinia laxa of peaches. , 2015, Microbiological research.

[38]  G. Berg Beyond borders: investigating microbiome interactivity and diversity for advanced biocontrol technologies , 2015, Microbial biotechnology.

[39]  Alejandro Hernández,et al.  Study of microbiological quality of controlled atmosphere packaged 'Ambrunés' sweet cherries and subsequent shelf-life. , 2013, International journal of food microbiology.

[40]  P. Crous,et al.  Alternaria redefined , 2013, Studies in mycology.

[41]  Guan Jun The Key Technologies of Commercial Handling and Storage of Postharvest Huangguan Pear , 2013 .

[42]  M. Camacho,et al.  Comparative fruit quality parameters of several Japanese plum varieties in two newly established orchards, organic and conventionally managed , 2012 .

[43]  L. Cocolin,et al.  Diversity of Candida zemplinina strains from grapes and Italian wines. , 2012, Food microbiology.

[44]  R. Saftner,et al.  Organically versus conventionally grown produce: common production inputs, nutritional quality, and nitrogen delivery between the two systems. , 2011, Journal of agricultural and food chemistry.

[45]  D. Gasparatos,et al.  Apple tree growth and overall fruit quality under organic and conventional orchard management , 2009 .

[46]  R. Fluhr,et al.  Mechanisms Modulating Postharvest Pathogen Colonization of Decaying Fruits , 2009 .

[47]  E. Rembiałkowska Quality of plant products from organic agriculture , 2007 .

[48]  Y. Bi,et al.  Occurrence and Latent Infection of Alternaria Rot of Pingguoli Pear (Pyrus bretschneideri Rehd. cv. Pingguoli) Fruits in Gansu, China , 2007 .

[49]  B. Heijne,et al.  Analysis of summer epidemic progress of apple scab at different apple production systems in the Netherlands and hungary. , 2005, Phytopathology.

[50]  Leo Breiman,et al.  Random Forests , 2001, Machine Learning.

[51]  R. N. Okigbo,et al.  Mycoflora of tuber surface of white yam (Dioscorea rotundata poir) and postharvest control of pathogens with Bacillus subtilis , 2004, Mycopathologia.

[52]  M. Carbonaro,et al.  Modulation of antioxidant compounds in organic vs conventional fruit (peach, Prunus persica L., and pear, Pyrus communis L.). , 2002, Journal of agricultural and food chemistry.

[53]  R. Lawrence,et al.  How sustainable agriculture can address the environmental and human health harms of industrial agriculture. , 2002, Environmental health perspectives.

[54]  P. Abeele,et al.  Acetic acid bacteria as causal agents of browning and rot of apples and pears , 1981 .