Low oxygen storage modulates invertase activity to attenuate cold-induced sweetening and loss of process quality in potato (Solanum tuberosum L.)

•Low O2 storage affected respiratory acclimation responses during cold sweetening.•Cold sweetening was attenuated by low O2, but the effect was cultivar dependent.•Low O2 modulated starch catabolism and invertase activity to reduce cold sweetening.•Low O2 revealed differences in LTS-metabolism of su...

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Veröffentlicht in:	Postharvest biology and technology 2016-11, Vol.121, p.106-117
Hauptverfasser:	Herman, Derek J., Knowles, Lisa O., Knowles, N. Richard
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Sprache:	eng
Schlagworte:	acclimation beta-fructofuranosidase cell respiration Cold-induced sweetening Controlled atmosphere storage cultivars dormancy Invertase oxygen phenotype phosphorylase potatoes Process quality Reducing sugars Solanum tuberosum Solanum tuberosum L sprouting starch storage time sucrose temperature tubers
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description	•Low O2 storage affected respiratory acclimation responses during cold sweetening.•Cold sweetening was attenuated by low O2, but the effect was cultivar dependent.•Low O2 modulated starch catabolism and invertase activity to reduce cold sweetening.•Low O2 revealed differences in LTS-metabolism of susceptible and resistant cultivars. Russet Burbank and Innovator are mid- to late-season frozen-processing cultivars with inherently different dormancy periods and susceptibilities to low temperature-induced sweetening (LTS). In contrast to Russet Burbank, which is highly prone to accumulation of reducing sugars (Glc+Fru) when stored below 8–9°C, Innovator tubers exhibit moderate resistance to LTS and retain process quality longer at lower temperatures (4–6°C). However, Innovator’s LTS resistance is not robust and often varies across production regions. Here we show that low O2 storage modulates LTS to reveal metabolic differences intrinsic to these cultivars. Changes in tuber respiration, process quality, reducing sugars, sucrose, starch phosphorylase and invertase activities were compared at 4 and 8°C in 2.5 and 21kPa O2 over a 212-d storage period. Tuber respiration declined rapidly as O2 level decreased from 21 to 2.5kPa during acclimation at 8°C. Respiration rates then fell further as the temperature was lowered from 8 to 4°C, but this response was greatly muted for tubers at 2.5 versus 21kPa O2. Tubers at 21kPa O2 completed their cold-induced respiratory acclimation response (RAR) within 7 d compared with 13 d at 2.5kPa O2, and the RAR was much greater for tubers at 2.5kPa O2. While reducing sugars increased most rapidly in tubers over the first 30 d at 4°C, Innovator tubers had lower invertase activity and sweetened less than Russet Burbank tubers, characterizing its LTS-resistant phenotype. Low O2 greatly attenuated these initial LTS responses for both cultivars; however, the effect was only temporary in Innovator. LTS resumed in Innovator tubers from 93 to 212 d with reducing sugar levels increasing to equal that of Russet Burbank tubers stored at 4°C and 21kPa O2. Activities of α-1,4 glucan phosphorylase (SP) were higher in Russet Burbank than Innovator and increased progressively over the storage period regardless of temperature and oxygen concentration. Innovator tubers stored at 2.5kPa O2 had higher SP activities from 30 to 153 d at 4 and 8°C compared with tubers stored at 21kPa O2, which correlated well with increased sucrose buildup and earlier spr
doi_str_mv	10.1016/j.postharvbio.2016.07.017
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Richard</creator><creatorcontrib>Herman, Derek J. ; Knowles, Lisa O. ; Knowles, N. Richard</creatorcontrib><description>•Low O2 storage affected respiratory acclimation responses during cold sweetening.•Cold sweetening was attenuated by low O2, but the effect was cultivar dependent.•Low O2 modulated starch catabolism and invertase activity to reduce cold sweetening.•Low O2 revealed differences in LTS-metabolism of susceptible and resistant cultivars. Russet Burbank and Innovator are mid- to late-season frozen-processing cultivars with inherently different dormancy periods and susceptibilities to low temperature-induced sweetening (LTS). In contrast to Russet Burbank, which is highly prone to accumulation of reducing sugars (Glc+Fru) when stored below 8–9°C, Innovator tubers exhibit moderate resistance to LTS and retain process quality longer at lower temperatures (4–6°C). However, Innovator’s LTS resistance is not robust and often varies across production regions. Here we show that low O2 storage modulates LTS to reveal metabolic differences intrinsic to these cultivars. Changes in tuber respiration, process quality, reducing sugars, sucrose, starch phosphorylase and invertase activities were compared at 4 and 8°C in 2.5 and 21kPa O2 over a 212-d storage period. Tuber respiration declined rapidly as O2 level decreased from 21 to 2.5kPa during acclimation at 8°C. Respiration rates then fell further as the temperature was lowered from 8 to 4°C, but this response was greatly muted for tubers at 2.5 versus 21kPa O2. Tubers at 21kPa O2 completed their cold-induced respiratory acclimation response (RAR) within 7 d compared with 13 d at 2.5kPa O2, and the RAR was much greater for tubers at 2.5kPa O2. While reducing sugars increased most rapidly in tubers over the first 30 d at 4°C, Innovator tubers had lower invertase activity and sweetened less than Russet Burbank tubers, characterizing its LTS-resistant phenotype. Low O2 greatly attenuated these initial LTS responses for both cultivars; however, the effect was only temporary in Innovator. LTS resumed in Innovator tubers from 93 to 212 d with reducing sugar levels increasing to equal that of Russet Burbank tubers stored at 4°C and 21kPa O2. Activities of α-1,4 glucan phosphorylase (SP) were higher in Russet Burbank than Innovator and increased progressively over the storage period regardless of temperature and oxygen concentration. Innovator tubers stored at 2.5kPa O2 had higher SP activities from 30 to 153 d at 4 and 8°C compared with tubers stored at 21kPa O2, which correlated well with increased sucrose buildup and earlier sprouting. 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Richard</creatorcontrib><title>Low oxygen storage modulates invertase activity to attenuate cold-induced sweetening and loss of process quality in potato (Solanum tuberosum L.)</title><title>Postharvest biology and technology</title><description>•Low O2 storage affected respiratory acclimation responses during cold sweetening.•Cold sweetening was attenuated by low O2, but the effect was cultivar dependent.•Low O2 modulated starch catabolism and invertase activity to reduce cold sweetening.•Low O2 revealed differences in LTS-metabolism of susceptible and resistant cultivars. Russet Burbank and Innovator are mid- to late-season frozen-processing cultivars with inherently different dormancy periods and susceptibilities to low temperature-induced sweetening (LTS). In contrast to Russet Burbank, which is highly prone to accumulation of reducing sugars (Glc+Fru) when stored below 8–9°C, Innovator tubers exhibit moderate resistance to LTS and retain process quality longer at lower temperatures (4–6°C). However, Innovator’s LTS resistance is not robust and often varies across production regions. Here we show that low O2 storage modulates LTS to reveal metabolic differences intrinsic to these cultivars. Changes in tuber respiration, process quality, reducing sugars, sucrose, starch phosphorylase and invertase activities were compared at 4 and 8°C in 2.5 and 21kPa O2 over a 212-d storage period. Tuber respiration declined rapidly as O2 level decreased from 21 to 2.5kPa during acclimation at 8°C. Respiration rates then fell further as the temperature was lowered from 8 to 4°C, but this response was greatly muted for tubers at 2.5 versus 21kPa O2. Tubers at 21kPa O2 completed their cold-induced respiratory acclimation response (RAR) within 7 d compared with 13 d at 2.5kPa O2, and the RAR was much greater for tubers at 2.5kPa O2. While reducing sugars increased most rapidly in tubers over the first 30 d at 4°C, Innovator tubers had lower invertase activity and sweetened less than Russet Burbank tubers, characterizing its LTS-resistant phenotype. Low O2 greatly attenuated these initial LTS responses for both cultivars; however, the effect was only temporary in Innovator. LTS resumed in Innovator tubers from 93 to 212 d with reducing sugar levels increasing to equal that of Russet Burbank tubers stored at 4°C and 21kPa O2. Activities of α-1,4 glucan phosphorylase (SP) were higher in Russet Burbank than Innovator and increased progressively over the storage period regardless of temperature and oxygen concentration. Innovator tubers stored at 2.5kPa O2 had higher SP activities from 30 to 153 d at 4 and 8°C compared with tubers stored at 21kPa O2, which correlated well with increased sucrose buildup and earlier sprouting. The low O2-mediated inhibition of LTS was largely a consequence of reduced invertase activities.</description><subject>acclimation</subject><subject>beta-fructofuranosidase</subject><subject>cell respiration</subject><subject>Cold-induced sweetening</subject><subject>Controlled atmosphere storage</subject><subject>cultivars</subject><subject>dormancy</subject><subject>Invertase</subject><subject>oxygen</subject><subject>phenotype</subject><subject>phosphorylase</subject><subject>potatoes</subject><subject>Process quality</subject><subject>Reducing sugars</subject><subject>Solanum tuberosum</subject><subject>Solanum tuberosum L</subject><subject>sprouting</subject><subject>starch</subject><subject>storage time</subject><subject>sucrose</subject><subject>temperature</subject><subject>tubers</subject><issn>0925-5214</issn><issn>1873-2356</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2016</creationdate><recordtype>article</recordtype><recordid>eNqNUcFu2zAMFYoVaJb2H9Rbd7Ar2pblHIdg6wYE2GHtWVBkOlXgSIkkp8tn9I_HIDv0uBMfyMeHRz7G7kGUIKB93Jb7kPKrice1C2VFrVKoUoC6YjPoVF1UtWw_sZlYVLKQFTQ37HNKWyGElLKbsfdVeOPhz2mDnqccotkg34V-Gk3GxJ0_YswmITc2u6PLJ54DNzmjn4jAbRj7wvl-stjz9IZIA-c33PiejyElHga-j8EiwcNkxrOA83wfsiGdh99hNH7a8TytMYZEaFV-uWXXgxkT3v2rc_by_dvz8kex-vX0c_l1VdhGQS5ggFbaoVmbTnR2raC22PWmle1QS4CqEQMxlKyaTiCAhIXsepBtpZqO-qqes4eLLhk8TJiy3rlkcSRLGKakK_pRoxpV10RdXKiWXKaIg95HtzPxpEHocwx6qz_EoM8xaKE0xUC7y8su0i1Hh1En69DTw1xEm3Uf3H-o_AW3dZmx</recordid><startdate>201611</startdate><enddate>201611</enddate><creator>Herman, Derek J.</creator><creator>Knowles, Lisa O.</creator><creator>Knowles, N. Richard</creator><general>Elsevier B.V</general><scope>AAYXX</scope><scope>CITATION</scope><scope>7S9</scope><scope>L.6</scope></search><sort><creationdate>201611</creationdate><title>Low oxygen storage modulates invertase activity to attenuate cold-induced sweetening and loss of process quality in potato (Solanum tuberosum L.)</title><author>Herman, Derek J. ; Knowles, Lisa O. ; Knowles, N. Richard</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c471t-1f165cf4ba808cb713ce8da656f3511240ff16752480e1151958d156274816773</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2016</creationdate><topic>acclimation</topic><topic>beta-fructofuranosidase</topic><topic>cell respiration</topic><topic>Cold-induced sweetening</topic><topic>Controlled atmosphere storage</topic><topic>cultivars</topic><topic>dormancy</topic><topic>Invertase</topic><topic>oxygen</topic><topic>phenotype</topic><topic>phosphorylase</topic><topic>potatoes</topic><topic>Process quality</topic><topic>Reducing sugars</topic><topic>Solanum tuberosum</topic><topic>Solanum tuberosum L</topic><topic>sprouting</topic><topic>starch</topic><topic>storage time</topic><topic>sucrose</topic><topic>temperature</topic><topic>tubers</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Herman, Derek J.</creatorcontrib><creatorcontrib>Knowles, Lisa O.</creatorcontrib><creatorcontrib>Knowles, N. Richard</creatorcontrib><collection>CrossRef</collection><collection>AGRICOLA</collection><collection>AGRICOLA - Academic</collection><jtitle>Postharvest biology and technology</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Herman, Derek J.</au><au>Knowles, Lisa O.</au><au>Knowles, N. Richard</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Low oxygen storage modulates invertase activity to attenuate cold-induced sweetening and loss of process quality in potato (Solanum tuberosum L.)</atitle><jtitle>Postharvest biology and technology</jtitle><date>2016-11</date><risdate>2016</risdate><volume>121</volume><spage>106</spage><epage>117</epage><pages>106-117</pages><issn>0925-5214</issn><eissn>1873-2356</eissn><abstract>•Low O2 storage affected respiratory acclimation responses during cold sweetening.•Cold sweetening was attenuated by low O2, but the effect was cultivar dependent.•Low O2 modulated starch catabolism and invertase activity to reduce cold sweetening.•Low O2 revealed differences in LTS-metabolism of susceptible and resistant cultivars. Russet Burbank and Innovator are mid- to late-season frozen-processing cultivars with inherently different dormancy periods and susceptibilities to low temperature-induced sweetening (LTS). In contrast to Russet Burbank, which is highly prone to accumulation of reducing sugars (Glc+Fru) when stored below 8–9°C, Innovator tubers exhibit moderate resistance to LTS and retain process quality longer at lower temperatures (4–6°C). However, Innovator’s LTS resistance is not robust and often varies across production regions. Here we show that low O2 storage modulates LTS to reveal metabolic differences intrinsic to these cultivars. Changes in tuber respiration, process quality, reducing sugars, sucrose, starch phosphorylase and invertase activities were compared at 4 and 8°C in 2.5 and 21kPa O2 over a 212-d storage period. Tuber respiration declined rapidly as O2 level decreased from 21 to 2.5kPa during acclimation at 8°C. Respiration rates then fell further as the temperature was lowered from 8 to 4°C, but this response was greatly muted for tubers at 2.5 versus 21kPa O2. Tubers at 21kPa O2 completed their cold-induced respiratory acclimation response (RAR) within 7 d compared with 13 d at 2.5kPa O2, and the RAR was much greater for tubers at 2.5kPa O2. While reducing sugars increased most rapidly in tubers over the first 30 d at 4°C, Innovator tubers had lower invertase activity and sweetened less than Russet Burbank tubers, characterizing its LTS-resistant phenotype. Low O2 greatly attenuated these initial LTS responses for both cultivars; however, the effect was only temporary in Innovator. LTS resumed in Innovator tubers from 93 to 212 d with reducing sugar levels increasing to equal that of Russet Burbank tubers stored at 4°C and 21kPa O2. Activities of α-1,4 glucan phosphorylase (SP) were higher in Russet Burbank than Innovator and increased progressively over the storage period regardless of temperature and oxygen concentration. Innovator tubers stored at 2.5kPa O2 had higher SP activities from 30 to 153 d at 4 and 8°C compared with tubers stored at 21kPa O2, which correlated well with increased sucrose buildup and earlier sprouting. The low O2-mediated inhibition of LTS was largely a consequence of reduced invertase activities.</abstract><pub>Elsevier B.V</pub><doi>10.1016/j.postharvbio.2016.07.017</doi><tpages>12</tpages><oa>free_for_read</oa></addata></record>
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subjects	acclimation beta-fructofuranosidase cell respiration Cold-induced sweetening Controlled atmosphere storage cultivars dormancy Invertase oxygen phenotype phosphorylase potatoes Process quality Reducing sugars Solanum tuberosum Solanum tuberosum L sprouting starch storage time sucrose temperature tubers
title	Low oxygen storage modulates invertase activity to attenuate cold-induced sweetening and loss of process quality in potato (Solanum tuberosum L.)
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