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Seasonal nonstructural carbohydrate patterns in dewberry (Rubus spp.) roots

Published online by Cambridge University Press:  05 January 2021

Katherine M. Ghantous*
Affiliation:
Research Associate, University of Massachusetts–Amherst Cranberry Station, East Wareham, MA, USA
Hilary A. Sandler
Affiliation:
Extension Associate Professor, University of Massachusetts–Amherst Cranberry Station, East Wareham, MA, USA
*
Author for correspondence: Katherine M. Ghantous, University of Massachusetts–Amherst Cranberry Station, 1 State Bog Road, East Wareham, MA02538. (Email: [email protected])

Abstract

Applying control measures when carbohydrate levels are low can decrease the likelihood of plant survival, but little is known about the carbohydrate cycles of dewberry (Rubus spp.), a problematic weed group on cranberry (Vaccinium macrocarpon Aiton) farms. Weedy Rubus plants were collected from areas adjacent to production beds on commercial cranberry farms in Massachusetts, two locations per year for 2 yr. For each site and year, four entire plants were collected at five phenological stages: budbreak, full leaf expansion, flowering, fruit maturity, and after onset of dormancy. Root sections were analyzed for total nonstructural carbohydrates (TNC; starch, sucrose, fructose, and glucose). Overall trends for all sites and years showed TNC were lowest at full leaf expansion or flowering; when sampled at dormancy, TNC concentrations were greater than or equal to those measured at budbreak. Starch, a carbohydrate form associated with long-term storage, had low levels at budbreak, leaf expansion, and/or flowering with a significant increase at fruit maturity and the onset of dormancy, ending at levels higher than those found at budbreak. The concentration of soluble sugars, carbohydrate forms readily usable by plants, was highest at budbreak compared with the other four phenological samplings. Overall, our findings supported the hypothesis that TNC levels within the roots of weedy Rubus plants can be predicted based on different phenological growth stages in Massachusetts. However, recommendations for timing management practices cannot be based on TNC cycles alone; other factors such as temporal proximity to dormancy may also impact Rubus plants recovery, and further research is warranted. Late-season damage should allow less time for plants to replenish carbohydrate reserves (before the onset of dormancy), thereby likely enhancing the effectiveness of weed management tactics over time. Future studies should consider tracking the relationship between environmental conditions, phenological stages, and carbohydrate trends.

Type
Research Article
Copyright
© The Author(s), 2021. Published by Cambridge University Press on behalf of the Weed Science Society of America

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Footnotes

Associate Editor: Nathan S. Boyd, Gulf Coast Research and Education Center

References

Ahn, BK, Kim, KC, Kim, DH, Lee, JH (2011) Effects of soil water potential on the moisture injury of Rubus coreanus Miq. and soil properties. Korean J Soil Sci Fertil 44:168175 CrossRefGoogle Scholar
Alvarado-Raya, HE, Darnell, RL, Williamson, JG (2007) Root to shoot relations in an annual raspberry (Rubus idaeus L.) production system. HortScience 42:15591562 CrossRefGoogle Scholar
Bhowmik, PC (1994) Biology and control of common milkweed (Asclepias syriaca). Rev Weed Sci 6:227250 Google Scholar
Bhowmik, PC (1997) Weed biology: importance to weed management. Weed Sci 45:349356 CrossRefGoogle Scholar
Botelho, MR, Vanden Heuvel, JE (2005) High dissolved oxygen concentration of floodwater reduces carbohydrate concentration of cranberry uprights during flooding. HortScience 40:569573 CrossRefGoogle Scholar
Boulanger-Pelletier, J, Lapointe, L (2017) Fertilization stimulates root production in cloudberry rhizomes transplanted in a cutover peatland. Can J Plant Sci 97:10461056 Google Scholar
Burley, JWA (1961) Carbohydrate translocation in raspberry and soybean. Plant Physiol 36:820824 CrossRefGoogle ScholarPubMed
Cralle, HT, Bovey, RW (1996) Total nonstructural carbohydrates and regrowth in honey mesquite (Prosopis glandulosa) following hand defoliation or clopyralid treatment. Weed Sci 44:566569 CrossRefGoogle Scholar
Cyr, DR, Dumbroff, EB, Bewley, JD (1990) Seasonal dynamics of carbohydrate and nitrogenous components in the roots of perennial weeds. Plant Cell Environ 13:359365 CrossRefGoogle Scholar
Demoranville, IE (1986) Weeds of Massachusetts Cranberry Bogs. Part 2. East Wareham, MA: University of Massachusetts. P 24Google Scholar
Else, MJ, Sandler, HA, Schluter, S (1995) Weed mapping as a component of integrated pest management in cranberry production. HortTechnology 5:302305 CrossRefGoogle Scholar
Fernandez, GE, Pritts, MP (1994) Growth, carbon acquisition, and source-sink relationships in ‘Titan’ red raspberry. J Am Soc Hort Sci 119:11631168 CrossRefGoogle Scholar
Gaucher, C, Gougeon, S, Mauffette, Y, Messier, C (2005) Seasonal variation in biomass and carbohydrate partitioning of understory sugar maple (Acer saccharum) and yellow birch (Betula alleghaniensis) seedlings. Tree Physiol 25:93100 CrossRefGoogle ScholarPubMed
Ghantous, KM, Sandler, HA (2016) Effect of timing and frequency of hand-held flame torches on dewberry control. Weed Technol 30:751757 CrossRefGoogle Scholar
Gleason, HA, Cronquist, A (1991) Manual of Vascular Plants of Northeastern United States and Adjacent Canada. 2nd ed. Bronx, NY: New York Botanical Garden. 910 p CrossRefGoogle Scholar
Glenn, S, Kalnay, P, Phillips, WH (1997) Long-Term control of perennial broadleaf weeds and triazine-resistant common lambsquarters (Chenopodium album) in no-till corn (Zea mays). Weed Technol 11:436443 CrossRefGoogle Scholar
Gordon, M (2009) Cape Cod Cranberry Growers’ Association, Bog Renovation Final Report. https://scholarworks.umass.edu/cranberry_research_repts/25. Accessed: November 2, 2020Google Scholar
Hagidimitriou, M, Roper, TR (1994) Seasonal changes in nonstructural carbohydrates in cranberry. J Am Soc Hort Sci 119:10291033 CrossRefGoogle Scholar
Horak, MJ, Wax, LM (1991) Growth and development of bigroot morningglory (Ipomoea pandurata). Weed Technol 5:805810 CrossRefGoogle Scholar
Hudgeons, JL, Knutson, AE, Heinz, KM, DeLoach, CJ, Dudley, TL, Rattison, RR, Kiniry, JR (2007) Defoliation by introduced Diorhabda elongata leaf beetles (Coleoptera: Chrysomelidae) reduces carbohydrate reserves and regrowth of Tamarix (Tamaricaceae). Biol Control 43:213221 CrossRefGoogle Scholar
Jatinder, K, Percival, D, Hainstock, LJ, Privé, JP (2012). Seasonal growth dynamics and carbon allocation of the wild blueberry plant (Vaccinium angustifolium Ait.). Can J Plant Sci 92:11451154 Google Scholar
Jensen, KIN, Hall, IV (1979) The biology of Canadian weeds. 36. Rubus hispidus L. Can J Plant Sci 59:769776 CrossRefGoogle Scholar
Kandiah, S (1979) Turnover of carbohydrates in relation to growth in apple trees. I. Seasonal variation of growth and carbohydrate reserves. Ann Bot 44:175183 CrossRefGoogle Scholar
Katovich, EJS, Becker, RL, Sheaffer, CC (1998) Seasonal fluctuations of carbohydrate levels in roots and crowns of purple loosestrife (Lythrum salicaria). Weed Sci 46:540544 CrossRefGoogle Scholar
Kaurin, A, Junttila, O, Hansen, J (1981) Seasonal changes in frost hardiness in cloudberry (Rubus chamaemorus) in relation to carbohydrate content with special reference to sucrose. Physiol Plant 52:310314 CrossRefGoogle Scholar
Kaurin, A, Stushnoff, C, Junttila, O (1982) Vegetative growth and frost hardiness of cloudberry (Rubus chamaemorus) as affected by temperature and photoperiod. Physiol Plant 55:7681 CrossRefGoogle Scholar
Kays, JS, Canham, CD (1991) Effects of time and frequency of cutting on hardwood root reserves and sprout growth. For Sci 37:524539 Google Scholar
Kozlowski, TT (1992) Carbohydrate sources and sinks in woody plants. Bot Rev 58:107222 CrossRefGoogle Scholar
Loescher, WH, McCamant, T, Keller, JD (1990) Carbohydrate reserves, translocation, and storage in woody plant roots. HortScience 25:274281 CrossRefGoogle Scholar
Monerri, C, Fortunato-Almeida, A, Molina, RV, Nebauer, SG, García-Luis, A, Guardiola, JL (2011) Relation of carbohydrate reserves with the forthcoming crop, flower formation and photosynthetic rate, in the alternate bearing ‘Salustiana’ sweet orange (Citrus sinensis L.). Sci Hort 129:7178 CrossRefGoogle Scholar
Nkurunziza, L, Streibig, JC (2011) Carbohydrate dynamics in roots and rhizomes of Cirsium arvense and Tussilago farfara . Weed Res 51:461468 CrossRefGoogle Scholar
Palonen, P (1999) Relationship of seasonal changes in carbohydrates and cold hardiness in canes and buds of three red raspberry cultivars. J Am Soc Hort Sci 124:507513 CrossRefGoogle Scholar
Price, EAC, Gamble, R, Williams, GG, Marshall, C (2001) Seasonal patterns of partitioning and remobilization of 14C in the invasive rhizomatous perennial Japanese knotweed (Fallopia japonica (Houtt.) Ronse Decraene). Evol Ecol 15:125 CrossRefGoogle Scholar
Richburg, JA (2005) Timing Treatments to the Phenology of Root Carbohydrate Reserves to Control Wood Invasive Plants. Ph.D dissertation. Amherst, MA: University of Massachusetts. http://www.umass.edu/nebarrensfuels/publications/pdfs/Richburg%20dissertation%20Adobe.pdf. Accessed: November 6, 2020Google Scholar
Roper, TR, Klueh, JS (1996) Movement patterns of carbon from source to sink in cranberry. J Am Soc Hort Sci 121:846847 CrossRefGoogle Scholar
Rydberg, PA (1915) Notes on Rosaceae-X. Rubus hybrids. Bull Torrey Bot Club 42:463479 CrossRefGoogle Scholar
Sandler, HA (2001) Dewberries and Brambles Fact Sheet. East Wareham, MA: UMass-Amherst Cranberry Sta. Ext. Publ. https://ag.umass.edu/sites/ag.umass.edu/files/fact-sheets/pdf/dewberry.pdf. Accessed: June 17, 2020Google Scholar
Sandler, HA (2010) Weed Priority Survey. UMass Cranberry Station Newsletter. http://www.umass.edu/cranberry/downloads/newsletters/mar10.pdf. Accessed: June 17, 2020Google Scholar
Sandler, HA, Dalbec, L, Ghantous, KM (2015) Identification Guide for Weeds in Cranberries. Quebec, Canada: Centre de référence en agriculture et agroalimentaire du Québec (CRAAQ), 295 pGoogle Scholar
Sandler, HA, Ghantous, KM (2018) Weed Management in Cranberry Chart Book: Management Guide for Massachusetts. http://scholarworks.umass.edu/cranchart/262. Accessed: August 21, 2020Google Scholar
Sather, BC, Bradley, KW (2012) Fall herbicide treatments reduce northern dewberry (Rubus flagellaris) stem density in tall fescue pastures and haylands. Forage and Grazinglands 10:17 CrossRefGoogle Scholar
Steele, F, Hodgdon, AR (1963) Hybridization of Rubus hispidus and R. setosus . Rhodora 65:262270 Google Scholar
Tworkoski, T (1992) Developmental and environmental effects on assimilate partitioning in Canada thistle (Cirsium arvense). Weed Sci 40:7985 Google Scholar
[USDA-NRCS] U.S. Department of Agriculture–Natural Resources Conservation Service (2020) SoilWeb. University of California–Davis. https://casoilresource.lawr.ucdavis.edu/gmap. Accessed: July 12, 2020Google Scholar
Ward, JM, Frommer, WB, Tegeder, M, Kuhn, C (1998) Sucrose transport in higher plants. Int Rev Cytol 178:4171 CrossRefGoogle ScholarPubMed
Wargo, PM (1971) Seasonal Changes in the Carbohydrate Levels in Roots of Sugar Maple. Upper Darby, PA: U.S. Department of Agriculture, Forest Service, Northeastern Forest Exeriment Station. 8 p Google Scholar
Wargo, PM (1976) Varaiation of starch content among and within the roots of red and white oak trees. For Sci 22:468471 Google Scholar
Wilson, RG, Kachman, SD, Martin, AR (2006) Seasonal changes in carbohydrates in the root of Canada thistle (Cirsium arvense) and the disruption of these changes by herbicides. Weed Technol. 20:242248 CrossRefGoogle Scholar
Wilson, RG, Martin, AR, Kachman, SD (2001) Seasonal changes in glucose, fructose, sucrose, and fructans in the roots of dandelion. Weed Sci 49:150155 CrossRefGoogle Scholar