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Research Articles

Investigating the Effect of Farm Management, Soil, and Climate on Hop Diastatic Potential

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Pages 389-400 | Received 28 Jan 2021, Accepted 03 Sep 2021, Published online: 19 Oct 2021
 

Abstract

To investigate potential sources for field-to-field variation in hop diastatic power, three varieties of hops (Mosaic®, Simcoe®, and Strata®) from harvest year 2019 were collected from different fields managed by a single hop grower throughout the hop growing region within Oregon’s Willamette Valley. Fields for this study were selected based on soil type and weather patterns, and eleven fields were identified for sampling (3 Mosaic®, 3 Strata®, and 5 Simcoe®). Farm management data on fertilization rates and pesticide applications were collected by the grower (Coleman Agriculture). Using USGS soil maps, five individual sites within each field were identified for soil sampling, and hop bines near those sites were GPS tagged and hand harvested when they were at similar maturities. After harvest, the hops were analyzed for enzymatic activity using an HPLC method. The relationships between hop enzymatic activity and the farm management, soil, and weather data yielded associations with soil texture, growing degree day accumulation, fertilization practice, and pesticide application. The data also suggest a potential link between hop diastatic power and downy mildew (Pseudoperonospora humuli) or powdery mildew (Podosphaera macularis) infection. The links between hop diastatic power and agronomic variables will allow farmers to minimize hop creep potential in the hop field thereby potentially mitigating the effects that brewers see in the cellar.

Acknowledgements

The authors wish to acknowledge the Coleman Agriculture and OSU terroir team for their contributions to this work, it would not have been possible without many hands: Liz Coleman, John Coleman, Ellie Coleman, Bill Cahill, and Haley Nelson (Coleman Agriculture); Shaun Townsend (Oregon State University); and Betsy Verhoeven (Oregon State University Extension Service). We would also like to thank the OSU undergraduate Shellhammer laboratory members, Drake Graham and Silas Shanafelt, for their assistance with harvesting samples and other research logistics.

Additional information

Funding

This work was made possible by financial support from Coleman Agriculture.

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