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Optimum temperatures for colour development in apples

Thesis (MScAgric (Horticulture))--University of Stellenbosch, 2010. / ENGLISH ABSTRACT: Peel colour is an important quality factor in the production of bi-coloured apple fruit. Most markets set minimum requirements for red colour coverage. Fruit that do not meet these requirements are downgraded and has a major impact on the profitability of apple production
in South Africa. South African apple production areas are amongst the warmest in the world.
Since anthocyanin accumulation requires induction at low temperature and synthesis require
mild temperatures, experiments were conducted to investigate optimum day and night temperatures for red colour development throughout fruit development for red and bi-coloured apple cultivars grown in South Africa. We found that redder strains of bi-coloured apple cultivars did not appear to owe their enhanced pigmentation to higher temperature optima for anthocyanin synthesis. The optimum day temperatures for red colour development in the
different cultivars seemed to differ between seasons, but not between production areas. In
general, red colour in the cultivars evaluated developed maximally between 17 ºC and 25 ºC.
The optimum day temperature for red colour development remained constant throughout fruit
development for most cultivars, but increased roughly from 14 ºC to 22 ºC in ‘Cripps’ Pink’
between January and April. The extent of red colour development increased during fruit development in all the cultivars assessed. We were unable to determine optimum induction temperatures for red colour development. ‘Royal Gala’ from Ceres seemed to benefit from
induction at 4 ºC while red colour in ‘Fuji’ decreased with decreasing temperature.
To explain the presence of anthocyanins in immature apple fruit, we tested the hypothesis
that anthocyanins protect the peel from photoinhibition and photooxidative damage during
conditions of increased light stress. First we established that the rate of colour change in
response to a passing cold front appears to be sufficient to provide photoprotection during a
cold snap. Also in agreement with the hypothesis, ‘Cripps Pink’ peel incurred significantly
more photoinhibition at low temperature (16 ºC) compared to mild (24 and 32 ºC) and high (40
ºC) temperature under high irradiance with visible light. Recovery rate was temperaturedependent,
being the slowest at low temperature and increasing with temperature. The photoapparatus in ‘Cripps Pink’ peel appears to be particularly sensitive to light stress at low temperature throughout the season, with significant photoinhibition occurring even at
moderate temperature (24 ºC). The sensitivity of the apple peel to photoinhibition increased throughout the season at lower irradiance levels, but remained the same at higher irradiance.
In our final experiment, fruit were exposed to high irradiance at low and mild temperature before exposure to high temperature in combination with high irradiance. This was done to test the hypothesis that photoinhibition incurred during cold snaps predisposes peel to photothermal damage when temperature increases again after the cold snap. Unfortunately, due to the severity of the stress incurred in response to high temperature treatment, the
results were inconclusive. / AFRIKAANSE OPSOMMING: Vrugkleur is ‘n belangrike kwaliteitsfaktor in die produksie van tweekleurappels. Die meeste markte stel minimum vereistes vir rooi kleurbedekking. Vrugte wat nie aan hierdie vereistes voldoen nie, word afgegradeer. Suid-Afrika se appel produksie areas word beskou as van die warmste ter wêreld. Antosianien akkumulasie benodig induksie by lae temperature gevolg
deur sintese in lig by matige temperature. Gevolglik het swak rooi kleurontwikkeling onder
plaaslike toestande ‘n groot impak op die winsgewendheid van appelproduksie in Suid-Afrika.
Eksperimente is uitgevoer om die optimum dag- en nagtemperature vir rooi kleurontwikkeling tydens vrugontwikkeling vir die rooi en tweekleur appel kultivars wat in Suid-Afrika geproduseer word te bepaal. Ons het gevind dat die verhoogde pigmentasie van rooier
seleksies van tweekleurappel kultivars nie aan ‘n hoër temperatuur optimum vir antosianiensintese toegeskryf kan word nie. Die optimum dag temperature vir rooi kleurontwikkeling vir die onderskeie kultivars verskil klaarblyklik tussen seisoene, maar nie tussen produksie areas nie. Oor die algemeen het kleurontwikkeling maksimaal plaasgevind tussen 17 ºC en 25 ºC. Die optimum dagtemperatuur vir rooi kleurontwikkeling het konstant
gebly tydens vrugontwikkeling, buiten vir ‘Cripps’ Pink’ waar dit toegeneem het van ongeveer
14 ºC tot 22 ºC vanaf Januarie tot April. Die mate van rooi kleurontwikkeling het in al die
kultivars toegeneem deur die loop van vrugontwikkeling . Ons kon nie daarin slaag om optimum induksie temperature vir rooi kleurontwikkeling vas te stel nie. Rooi kleurontwikkeling
van ‘Royal Gala’ uit Ceres is moontlik bevorder deur induksie by 4 ºC, terwyl ‘Fuji’ se rooi
kleur afgeneem het met ‘n verlaging in induksie temperatuur.
Ten einde die teenwoordigheid van antosianien in onvolwasse appelvruggies te verduidelik,
het ons die hipotese getoets dat antosianien die vrugskil beskerm teen fotoinhibisie en fotooksidatiewe beskadiging gedurende tydperke van verhoogde ligstres. Eerstens het ons
bevestig dat die tempo van kleurontwikkeling in reaksie op ‘n koue front waarskynlik vinnig
genoeg is om fotobeskerming te verleen. Vervolgens is gevind dat ‘Cripps’ Pink’ vrugskil
aansienlik meer fotoinhibisie ervaar het by lae temperatuur (16 ºC) in vergelyking met matige
(24 ºC en 32 ºC) en hoë (40 ºC) temperatuur onder hoë irradiasie met sigbare lig. Die hersteltempo was temperatuur-afhanklik; dit was die stadigste by lae temperatuur en het toegeneem met ‘n toename in temperatuur. Die foto-apparaat in ‘Cripps’ Pink’ vrugskil blyk
besonder sensitief te wees vir ligstres by lae temperatuur regdeur die groeiseisoen met
aansienlike fotoinhibisie by selfs matige temperatuur (24 ºC). Die sensitiwiteit van die vrugskil
vir fotoinhibisie het toegeneem deur die groeiseisoen by laer ligvlakke, maar het dieselfde
gebly by hoër vlakke van irradiasie. Laastens is vrugte blootgestel aan hoë irradiasie by lae en matige temperatuur voordat dit vervolgens blootgestel is aan hoë temperatuur in kombinasie met hoë irradiasie. Dit was om die hipotese te toets dat fotoinhibisie wat
opgedoen word gedurende ‘n onverwagte koue periode, die skil meer vatbaar maak vir fototermiese
skade sodra die temperatuur weer styg na die koue periode verby is. Ongelukkig het
die hoë temperatuur stres al die behandelings tot so ‘n mate geaffekteer dat dit onmoontlik
was om enige gevolgtrekkings vanuit ons resultate te maak.

Identiferoai:union.ndltd.org:netd.ac.za/oai:union.ndltd.org:sun/oai:scholar.sun.ac.za:10019.1/5164
Date23 November 2010
CreatorsGouws, Anton
ContributorsSteyn, W. J., University of Stellenbosch. Faculty of Agrisciences. Dept. of Horticultural Science.
PublisherStellenbosch : University of Stellenbosch
Source SetsSouth African National ETD Portal
LanguageEnglish
Detected LanguageUnknown
TypeThesis
Format94 p. : ill.
RightsUniversity of Stellenbosch

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