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Bars van tafeldruiwe met spesiale verwysing na Queen of the VineyardMeynhardt, J. T. (Johann Theron) 12 1900 (has links)
Thesis (MScAgric)--Stellenbosch University, 1956. / ENGLISH ABSTRACT: no abstract available / AFRIKAANSE OPSOMMING: geen opsomming
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Characterisation of Rhizoctonia in cropping systems in the Western Cape ProvinceTewoldemedhin, Yared Tesfai 03 1900 (has links)
Thesis (MScAgric (Plant Pathology))--University of Stellenbosch, 2005. / The genus Rhizoctonia includes important soilborne plant pathogens that can cause
severe economic losses on a wide range of crops including cereal, canola, pasture and grain
legume crops. Limited information is available on specific anastomosis groups (AGs), nuclear
status, pathogenicity and cross-pathogenicity of Rhizoctonia isolates associated with each of
these crops in the Western Cape province. Therefore, these aspects were investigated in this
study, since information in this regard is crucial for the development of Rhizoctonia disease
management practices.
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Mycotoxin levels in subsistence farming systems in South AfricaNcube, Edson 03 1900 (has links)
Thesis (MScAgric (Plant Pathology)--Stellenbosch University, 2008.
Includes bibliography.summary,list of figures and appendices. / ENGLISH ABSTRACT:
Fusarium spp. and Aspergillus spp. are toxin-producing fungi associated with maize and
groundnut. Fusarium verticillioides produces fumonisins in maize, and Aspergillus flavus
produces aflatoxins in maize and groundnut kernels. Both toxins are responsible for
carcinogenesis in humans and animals. Contamination of maize and groundnut with
mycotoxins is often most severe in rural areas where subsistence farmers are unaware of their
existence and follow agricultural practices that might contribute to their production. A
questionnaire was, therefore, compiled to investigate agricultural decisions in rural areas that
may influence mycotoxin contamination of crops. During 2006 and 2007, maize and
groundnut samples were collected in the Eastern Cape, KwaZulu-Natal (KZN), Limpopo, and
Mpumalanga provinces. Mycotoxin levels were quantified using the ELISA technique, and
the incidence of Fusarium spp. in maize grain was determined by plating maize kernels out on
Fusarium selective medium. Fumonisin-producing Fusarium spp. were also quantified using
real-time PCR (TaqMan). The incidence of A. flavus and A. parasiticus in groundnut was
determined by plating out kernels on potato dextrose agar. Fumonisin contamination levels in
maize samples ranged from 0-21.8 parts per million (ppm) and aflatoxin levels ranged from 0-
49 parts per billion (ppb), depending on the region where samples were collected. Aflatoxin
levels in groundnut ranged from 0-160.1 ppb. Fusarium verticillioides was the most common
Fusarium sp. in maize followed by F. subglutinans and F. proliferatum, respectively.
Regression analyses showed a positive correlation between fumonisin-producing Fusarium
species when determined by real-time PCR and fumonisin concentration (r2=0.866).
Regression analyses further showed a highly significant positive correlation between A. flavus
and aflatoxin contamination (r2=0.10235). Samples from northern KZN contained levels of
mycotoxins that were far in excess of the maximum levels set by the Food and Drug
Administration in the USA. In South Africa there are currently no regulations with regard to
the maximum allowable levels of fumonisin in human food. The high incidence of mycotoxin
contamination of human food in subsistence farming systems indicates the need for awareness
programmes and further research. / AFRIKAANSE OPSOMMING:
Fusarium spp. en Aspergillus spp. is toksien-produserende fungi wat met mielies en
grondbone geassosieer word. Fusarium verticillioides produseer fumonisiene in mielies,
terwyl, A. flavus aflatoksiene in mielies en grondbone produseer. Beide toksiene is
karsinogenies vir mens en dier. Die vlakke van toksien-kontaminasie is meestal die ergste in
landelike gebiede waar bestaansboere onbewus is daarvan. Landboupraktyke wat deur die
boere toegepas word vererger dikwels die probleem. ‘n Vraelys is saamgestel om vas te stel
watter landboupraktyke in landelike gebiede toegepas word, en hoe dit toksien-kontaminasie
in mielies en grondbone beinvloed. In die 2006 en 2007 seisoene is mielie- en
grondboonmonsters in Kwa-Zulu-Natal (KZN), die Oos Kaap, Limpopo en die Mpumalanga
provinsie versamel. Toksien-vlakke is gekwantifiseer deur gebruik te maak van die ELISA
tegniek. Die insidensie van Fusarium spp. in mielies was bepaal deur pitte op Fusariumselektiewe
agar uit te plaat. Fumonisien-produserende Fusarium spp. was ook gekwantifiseer
deur van kwantitatiewe PCR (TaqMan) gebruik te maak. Die voorkoms van A. flavus en A.
parasiticus is bepaal deurdat mielie- en grondboonpitte op aartappel dekstrose agar uit te
plaat. Fumonisien-vlakke in die mieliemonsters het gewissel van 0-21.8 dele per miljoen
(dpm), terwyl aflatoksienvlakke gewissel het van 0-49 dele per biljoen (dpb), afhangende van
die omgewing waar monsters versamel is. Aflatoksien vlakke in die grondboonmonsters het
gewissel van 0-160.1 dpb. Fusarium verticillioides is die meeste vanuit mielies geisoleer,
gevolg deur F. subglutinans en F. proliferatum. Regressie analises het ‘n positiewe korrelasie
tussen fumonisien konsentrasie en fumonisien-produserende spp. aangedui waar daar gebruik
gemaak is van die kwantitatiewe PCR (r2= 0.866). Regressie analises het ‘n hoogs
betekenisvolle positiewe korrelasie getoon tussen A. flavus en aflatoksien kontaminasie
(r2=0.10). Monsters van noordelike KZN het toksienvlakke bevat ver bokant die maksimum
toelaatbare vlakke is soos bepaal deur die Food en Drug Administrasie in die Verenigde State
van Amerika. Daar is tans geen regulasies in Suid Afrika wat die maksimum toelaatbare
vlakke van fumonisiene in voedsel vir menslike gebruik bepaal nie. Die hoë voorkoms van
mikotoksien-kontaminasie in bestaansboer-sisteme, dui die belangrikheid van verdere
navorsing en bewusmakings-progamme aan.
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Characterisation of mites and peniciccium species associated with apple core rot diseasesVan der Walt, Lene 03 1900 (has links)
Thesis (MSc (Plant Pathology))--University of Stellenbosch, 2009. / ENGLISH ABSTRACT: Dry core rot (DCR) and wet core rot (WCR) are among some of the most important postharvest
diseases of apples in South Africa. Mouldy core (MC) is also a symptom associated with
the core region of apples, but it is not of economical importance since apple tissue surrounding
the core region is not affected as is the case with DCR and WCR. The incidence of core rots in
harvested fruits can be as high as 12%, but in general ranges from 3 to 8%. Infections and losses
can also occur during fruit handling in pack houses and during storage. Additionally, yield losses
also occur prior to harvest within orchards due to premature fruit drop of core rot affected fruits.
The incidence of core rot diseases in apples differ among apple cultivars, with most Red
Delicious varieties being susceptible to the development of core rots, whereas core rots have
rarely been reported in other cultivars such as Granny Smith.
The etiology and epidemiology of WCR and DCR are poorly understood. Although many
fungal genera have been associated with the diseases, small-spored Alternaria species are mainly
associated with DCR, whereas Penicillium species including P. roquefortii, P. expansum and P.
funiculosum have mainly been associated with WCR. Dry core rot infections have long been
known to occur pre-harvest, whereas WCR is primarily known as a post-harvest disease where
infections take place during fruit handling in pack houses. Recently, Tarsonemus mites have also
been indicated as being a potential role player in the etiology of core rot diseases. The mites
have been hypothesised to carry pathogen spores into the core region of apples, and they may
also possibly cause small wounds that facilitate pathogen entry.
In South Africa, apple growers have recently reported WCR as being present prior to
harvest, which has not been reported previously. Therefore, the first aim of the study was to
investigate the incidence, as well as the causal agent/s of pre-harvest WCR. The incidence of
WCR ranged from 0% to 1.7% in eleven orchards, and was in general lower than that of DCR
(0.4% to 6%). Isolation studies from eight internal positions in WCR apples showed that
Penicillium was the predominant fungal genus in most of the positions, including the lesion area.
Morphological and molecular characterisation of Penicillium isolates from WCR showed that P.
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ramulosum prov. nom. was the main species isolated from lesions, as well as other isolation
positions. However, this species was also the main species isolated from DCR, MC and
asymptomatic apples. Penicillium expansum was only isolated at low frequencies from WCR
and DCR apples. Other Pencillium species that were occasionally isolated included P. glabrum,
P. chloroloma, P. chermisinum and a putative new species with closest affinity to P. dendriticum
(P. species aff. dendriticum) on a DNA nucleotide sequence basis. Pathogenicity and virulence
studies using three different inoculation methods showed that P. expansum was the most virulent
species, followed by P. species aff. dendriticum. The P. ramulosum prov. nom. isolates varied in
their virulence, but were all considered to have low virulence.
The role of Tarsonemus mites in the etiology and epidemiology of core rot diseases is
poorly understood, and therefore the second aim of the study was to investigate some of these
aspects. The specific aims of the study were to (1) investigate the ecology of Tarsonemus mites
in Red Delicious and Granny Smith orchards during different apple developmental stages, (2)
determine if there is a significant association of Tarsonemus mites with diseased (WCR and
DCR) fruits and (3) determine if potential core rot pathogenic fungi are associated with the
mites. Tarsonemus mites were found in all of the investigated apple developmental stages (buds,
blossoms, 4cm diameter fruit, mature fruit and mummies), having the highest incidence in
mummies and mature fruits from Red Delicious and Granny Smith orchards. In Red Delicious
fruits the Tarsonemus mites were found within the core and/or calyx tube, whereas in Granny
Smith fruits the mites were restricted to the calyx tube. In Red Delicious fruits there was a
significant association between dry core rot as well as total core rot (wet- and dry-core rot) with
the presence of mites in the core, as well as total mites (mites in core and calyx tubes). Fungal
isolation studies from the Tarsonemus mites showed that they carried potential core rot fungal
pathogens within the genera Penicillium and Alternaria. The Penicillium species isolated from
the mites included two of the most virulent WCR species, P. expansum and P. species aff.
dendriticum. / AFRIKAANSE OPSOMMING: Droë kernvrot and nat kernvrot is van die belangrikste na-oes siektes van appels in Suid-
Afrika. Beskimmelde kern word ook met die kern van appels geassosieer, maar hierdie toestand
is egter nie van ekonomiese belang nie, aangesien die weefsel rondom die kern nie geaffekteer
word soos in die geval van nat- en droë kernvrot nie. Die voorkoms van kernvrot in vrugte na
oes, kan vlakke van tot 12% bereik, maar oor die algemeen is die voorkoms tussen 3 en 8%.
Infeksie en verliese kan ook voorkom gedurende die hantering en verpakking van vrugte in
pakhuise en gedurende storing. Addisionele verliese in opbrengs kan ook voor-oes voorkom in
boorde. Dit is te wyte aan voortydige vrugval van appels wat besmet is met kernvrot. Die
voorkoms van kernvrot by appels verskil tussen kultivars. Meeste van die “Red Delicious”
variëteite is vatbaar vir die ontwikkeling van kernvrot. Die toestand is egter skaars by ander
kultivars soos Granny Smith.
Die etiologie en epidemiologie van nat- en droë kernvrot word nie goed verstaan nie. ‘n
Groot aantal swamgenera is al met kernvrot geassosieer. Klein-spoor Alternaria spesies word
hoofsaaklik met droë kernvrot geassosieer en Penicillium spesies, insluitende P. roquefortii, P.
expansum en P. funiculosum, word meestal met nat kernvrot geassosieer. Dit is lank reeds
bekend dat droë kernvrot as voor-oes siekte kan voorkom, maar nat kernvrot is algemeen bekend
as na-oes siekte waar infeksie tydens vrughantering en verpakking plaasvind. Daar is onlangs
aangedui dat Tarsonemus myte potensiële rolspelers in die etiologie van kernvrot is. Hipoteties
is die myte in staat om spore van die patogene in die kern van die appels in te dra, asook om
klein wonde te veroorsaak wat infeksie deur patogene vergemaklik.
In Suid-Afrika is nat kernvrot wat voor-oes in die boorde ontstaan onlangs deur boere
aangemeld; hierdie toestand is nog nie op ‘n vorige geleentheid aangemeld nie. Die eerste
doelwit van hierdie studie was dus om die voorkoms en veroorsakende organisme/s van voor-oes
nat kernvrot te ondersoek. Die voorkoms van nat kernvrot was tussen 0 en 1.7% in elf boorde en
was oor die algemeen laer as die voorkoms van droë kernvrot (0.4 tot 6%). Isolasiestudies uit agt
interne posisies van nat kernvrot appels het getoon dat Penicillium die dominante swamgenus in
die meeste posisies was, insluitend die letsels. Morfologiese en molekulêre karakterisering van
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Penicillium isolate uit nat kernvrot letsels het aangedui dat P. ramulosum prov. nom. die spesie is
wat die meeste geïsoleer is vanuit die letsels, asook ander isolasie posisies. Dié spesie was egter
ook die mees algemene spesie wat uit nat- en droë kernvrot, asimptomatiese appels en appels wat
slegs swamgroei in die kern gehad het, geïsoleer is. Penicillium expansum was ook in lae getalle
uit nat- en droë kernvrotletsels geïsoleer. Ander Penicillium spesies wat ook soms geïsoleer is,
sluit P. glabrum, P. chloroloma, P. chermisinum, asook ‘n moontlik nuwe spesie wat op DNA
volgorde basis die naaste aan P. dendriticum (P. spesie aff. dendriticum) is. Studies wat
patogenesiteit en virulensie van die isolate ondersoek het, is ook uitgevoer deur gebruik te maak
van drie verskillende inokulasie metodes. Die studies het aangedui dat P. expansum die mees
virulente spesie is, gevolg deur P. spesie aff. dendriticum. Die P. ramulosum prov. nom. isolate
het variasie in virulensie getoon maar is oor die algemeen aanvaar om minder virulent te wees.
Die rol van Tarsonemus myte in die etiologie en epidemiologie van kernvrot word nie
goed verstaan nie en dus was die tweede doelwit van die studie om sommige van dié aspekte te
ondersoek. Die spesifieke doelwitte was (1) om die ekologie van die Tarsonemus myte in “Red
Delicious” en Granny Smith boorde tydens verskillende ontwikkelingstadiums van die appels te
ondersoek, (2) om te bepaal of daar ‘n betekenisvolle assosiasie van Tarsonemus myte met siek
(nat- en droë kernvrot) vrugte bestaan en (3) om te bepaal of potensiële kernvrot patogeniese
swamme geassosieer is met die myte. Tarsonemus myte is gevind in al die ontwikkelingstadiums
(knoppies, bloeisels, 4 sentimeter deursnee vrugte, volwasse vrugte en mummies) van appels wat
ondersoek is. Die hoogste voorkoms van myte was in die mummies en volwasse vrugte van “Red
Delicious”, asook Granny Smith kultivars gevind. In “Red Delicious” vrugte is myte in die kern
en/of kaliksbuis gevind, maar in die Granny Smith vrugte was die myte tot die kaliksbuis beperk.
In “Red Delicious” vrugte was daar ‘n betekenisvolle assosiasie tussen droë kernvrot, asook
totale kernvrot (nat en droë kernvrot) met die teenwoordigheid van myte in die kern, asook totale
myte (myte in die kern en kaliksbuis). Swam isolasiestudies vanaf die Tarsonemus myte het
aangetoon dat potensiële kernvrot swampatogene in die genera Penicillium en Alternaria wel by
die myte teenwoordig was. Die Penicillium spesies wat vanaf die myte geïsoleer is het twee van
die mees virulente nat kernvrot spesies ingesluit, nl. P. expansum en P. spesie aff. dendriticum.
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The use of adjuvants to improve fungicide spray deposition on grapevine foliageVan Zyl, Sybrand Abraham 03 1900 (has links)
Thesis (MScAgric (Plant Pathology))--Stellenbosch University, 2009. / ENGLISH ABSTRACT: Sufficient fungicide deposition on the target site is an essential requirement for effective chemical management of fruit- and foliar diseases such as grey mould of grapevines. Control failure is often attributed to insufficient quantitative deposition on susceptible grapevine tissue. However, in high disease pressure situations control failure might also be attributed to poor qualitative deposition. The primary objective of spray technology is to optimise deposition, of which the plant surface is a critical component in the spray application process, specifically in the retention of spray droplets. Adjuvant technology is reported to improve the wettability and spread of droplets by surface-acting-agents on the target surface and thereby improve deposition and retention of the fungicide active ingredient. However, this relatively new spray technology on viticulture and horticultural crops, and possible effects of adjuvants on epicuticular wax affecting plant disease development, needs to be investigated. Moreover, the development of useful prescriptions for adjuvants by determining water volumes and adjuvant dosages is required for different pesticide tank mixes. The aims of this study were, firstly to determine the effect of selected adjuvants on quantitative and qualitative spray deposition on grapevine leaves and subsequent biological efficacy of a fungicide, and secondly to evaluate selected adjuvants under field conditions and determine the effects of adjuvant dosage and spray volume on deposition.
Leaves were sprayed under similar laboratory conditions to pre-run-off with 1 mL of a mixture of fenhexamid (Teldor® 500 SC, Bayer) at recommended dose, a fluorescent pigment (SARDI Fluorescent Pigment, 400 g/L EC; South Australian Research and Development Institute) at 0.2 L/100 L, as well as 15 selected commercial adjuvants to manipulate the deposition quality of a given quantity of deposited spray. Spray deposition on leaves was illuminated under black light (UV-A light in the 365 nm region) and visualised under a stereo microscope (Nikon SMZ800) at 10× magnification. Photos of sprayed leaf surfaces were taken with a digital camera (Nikon DMX 1200). Digital images were quantitatively and qualitatively analysed with Image-Pro Discovery version 6.2 for Windows (Media Cybernetics) software, to determine spray deposition. The sprayed leaves were inoculated with 5 mg dry airborne conidia of Botrytis cinerea in a spore settling tower and
incubated for 24 h at high relative humidity (≥ 93%). Leaf discs were isolated onto Petri dishes with paraquat-amended water agar and rated 11 days later for development of B. cinerea from isolated leaf discs. B. cinerea incidence on the upper and lower surfaces of water sprayed leaves averaged 90.4% and 95.8%, respectively. Despite full spray cover of leaves, applications with fenhexamid alone did not completely prevent infection and resulted in 34.6% and 40.8% B. cinerea incidence on the upper and lower surfaces of leaves, respectively. Through the addition of certain adjuvants, B. cinerea incidences were significantly lower (2.9-17.1% and 10.0-30.8%, respectively), while some adjuvants did not differ from the fungicide-only treatment, even though they might have improved spray deposition. The effects of Hydrosilicote and Solitaire alone and in combination with fenhexamid on germinating Botrytis conidia on leaf surfaces were studied in a histopathology study using epifluorescence microscopy. Distinct differences were observed in conidium mortality, germination and germ tube lengths between adjuvants alone and in combination with the fungicide, which might be attributed to indirect effects of the adjuvant mode of action on B. cinerea. The laboratory study clearly demonstrated the potential of adjuvants to improve the bio-efficacy of a fungicide directly through improved deposition on grapevine leaf surfaces.
For the vineyard evaluations, the same fluorometry, photomicrography and digital image analysis protocol were used to assess quantitative and qualitative spray deposits under varying adjuvant dosage and volume applications. The Furness visual droplet-rating technique was initially included to determine optimum spray volume with a STIHL SR400 motorised backpack mistblower by assessment of pigment deposition on Chardonnay leaves under illuminated black light. Both assessment protocols showed that quantitative spray deposition increased with increasing spray volume applications of 40 L/ha to 750 L/ha, but decreased at 900 L/ha, possibly due to run-off. The addition of selected adjuvants at recommended dosage and at 600 L/ha demonstrated the potential of adjuvants to increase quantitative and qualitative deposition significantly on upper and lower leaf surfaces. Agral 90, BB5, Nu-film-P, and Solitaire significantly improved deposition on upper and lower leaf surfaces compared with the fenhexamid only and water sprayed control. Break-thru S 240 and Villa 51 did not improve quantitative deposition, although remarkably better qualitative deposition was obtained. An adjuvant dosage effect (within the registered dosage range) was evident, especially those retained on the upper leaf surfaces. Agral 90 and Nu-film-P affected significant improvement of spray deposition at the higher, but not at the lower dosage tested. Solitaire improved deposition at the lower dosage tested, whereas reduced deposition at the
higher dosage was attributed to excessive spray run-off. No significant improvement of spray deposition was observed for both dosages tested with Villa 51. Spray mixtures with adjuvants Agral 90 and Solitaire yielded similar deposition values at 600 L/ha compared with the fenhexamid only control at 900 L/ha, but reduced deposition at the higher spray volume, possibly due to spray run-off. This study clearly demonstrated the potential of adjuvants to improve quantitative and qualitative deposition, but highlights the necessity to match adjuvant dosages and application volumes on the spray target to achieve maximum spray deposition. / AFRIKAANSE OPSOMMING: Effektiewe beheer van vrug- en blaarsiektes soos vaalvrot op wingerde benodig voldoende deponering van die swamdoder op die teikenoppervlak. Verlies aan beheer word gewoonlik aan onvoldoende kwantitatiewe deponering op vatbare wingerddele toegeskryf. Onder ‟n hoë siektedruk kan mislukte beheer ook moontlik toegeskryf word aan swak kwalitatiewe deponering. Die primêre doelwit van spuittegnologie is om deponering te optimaliseer met die plantoppervlak as ‟n belangrike komponent in die spuittoedieningsproses, spesifiek in die retensie van spuitdruppels. Byvoemiddel tegnologie het bewys dat oppervlak-aktiewe-agente verbeterde benatting en verspreiding van druppels op die teiken oppervlakte tot gevolg kan hê, en verder ook die deponering en retensie van die aktiewe fungisied bestanddele kan verbeter. Hierdie relatiewe nuwe spuittegnologie op wingerd- en hortologiese verbouing, asook die moontlike effekte van byvoegmiddels op epikutikulêre waks om siekte ontwikkeling te beïnvloed, moet ondersoek word. Verder word nuttige aanbevelings benodig vir byvoegmiddel toedienings by verskillende spuitvolumes en dosisse van die betrokke spuitmengsel. Die doelwit van hierdie studie was, eerstens om die effek van sekere byvoegmiddels op kwantitatiewe en kwalitatiewe spuitbedekking van wingerdblare te bepaal en dan te vergelyk met die biologiese effektiwiteit van ‟n fungisied, en tweedens om van die byvoegmiddels onder veldtoestande te evalueer, asook die effek van byvoegmiddel dosisse en spuitvolumes te bepaal.
Blare is onder dieselfde laboratorium toestande tot net voor-afloop met 1 mL van ‟n spuitmengsel, bestaande uit fenhexamied (Teldor® 500 SC, Bayer) teen die aanbevole dosis, ‟n fluoreserende pigment (400 g/L EC; Suid Australiese Navorsing en Ontwikkeling Instituut) teen 0.2 L/100 L, sowel as 15 geselekteerde kommersiële byvoegmiddels gespuit om die kwalitatiewe deponering, vir ‟n gegewe kwantiteit van spuitdeponering, te manipuleer. Die fluoreserende pigment is op die blaaroppervlak belig met ‟n swart lig (UV-A ligbron in die 365 nm golflengte) en deponering is onder ‟n stereo mikroskoop (Nikon SMZ800) teen 10× vergroting waargeneem. Die gespuite blaaroppervlaktes is op die manier met ‟n digitale kamera afgeneem (Nikon DMX 1200), waarna die digitale foto‟s kwantitatief
en kwalitatief deur die gebruik van „Image-Pro Discovery version 6.2 for Windows (Media Cybernetics)‟ sagteware geanaliseer is om spuitbedekking te bepaal. Na elke blaarspuit is die blare met 5 mg droë konidia van B. cinerea in ‟n inokulasietoring geïnokuleer en daarna vir 24 h onder hoë relatiewe humiditeit (≥ 93%) geïnkubeer. ‟n Aantal skyfies vanuit elke blaar is op Petri bakkies met paraquat medium geïsoleer en 11 dae later is die persentasie van B. cinerea ontkieming bepaal. Die gemiddelde voorkoms van B. cinerea op die blare wat slegs met water gespuit is, was 90.4% op die boonste en 95.8% op die onderste blaaroppervlaktes. Spuitbehandelings met slegs fenhexamied, ongeag goeie blaarspuitbedekking, kon nie die B. cinerea infeksie ten volle voorkom nie, en infeksie van gemiddeld 34.6% en 40.8% is onderskeidelik op die boonste- en op die onderste blaaroppervlaktes waargeneem. Met die byvoeging van sekere byvoegmiddels het die voorkoms van B. cinerea betekenisvol verminder (2.9-17.1% en 10.0-30.8%, onderskeidelik), terwyl ander byvoegmiddels nie van die fenhexamied behandeling verskil het nie, hoewel hierdie middels meestal wel spuitdeponering verbeter het. Die effek van slegs Hydrosilicote en Solitaire, en in kombinasie met fenhexamied op ontkiemende Botrytis conidia, is bestudeer in ‟n histopatologiese studie deur middel van die gebruik van epifluoresensie mikroskopie op die blaaroppervlak. Duidelike verskille in die aantal dooie konidia, ontkiemingpersentasies en kiembuislengtes is tussen die byvoegmiddels en in kombinasie met fenhexamied waargeneem, waar sommige waarnemings moontlik aan die indirekte effek van die byvoegmiddel op B. cinerea toegeskryf kan word. Hierdie laboratoriumstudie wys duidelik dat byvoegmiddels oor goeie potensiaal beskik om die bio-effektiwiteit van die fungisied te verbeter deur die direkte verbetering van deponering op die wingerdblaaroppervlak.
Dieselfde fluorometrie, fotomikrografie en digitale foto-analise protokol is in ‟n wingerd evaluasie om die kwantitatiewe en kwalitatiewe spuitdeponering van verskillende byvoegmidel dosisse and spuitvolumes te bepaal, gebruik. Die Furness visuele druppel meting tegniek is aanvanklik ingesluit om die optimale spuit volume met ‟n „STIHL SR400 motorised backpack mistblower‟ te bepaal deur visuele meetings van gedeponeerde pigment op Chardonnay blare onder ‟n swart ligbron. Beide protokolle wys dat kwantitatiewe spuitbedekking met ‟n toename in spuit volumes 40 L/ha tot 750 L/ha verbeter het, maar afgeneem het teen 900 L/ha, moontlik as gevolg van druppel-afloop. Die byvoeging van ‟n byvoegmiddel teen die aanbevole dosis en 600 L/ha wys uitstekende potensiaal om kwantitatiewe en kwalitatiewe deponering betekenisvol op boonste en onderste blaaroppervlaktes te verbeter. Agral 90, BB5, Nu-film-P, en Solitaire het deponering
betekenisvol op boonste en onderste blare in vergelyking met die fenhexamied alleen en die water kontrole verbeter. Break-thru S 240 en Villa 51 het nie kwantitatiewe deponering verbeter nie, alhoewel verbeterde kwalitatiewe bedekking met hierdie produkte waargeneem is. ‟n Byvoegmiddel dosis effek (binne die registreerde dosis reeks) was duidelik waarneembaar, veral vir druppel retensie op die boonste oppervlak van blare. Agral 90 and Nu-film-P verbeter die spuit deponering betekenisvol met die hoër getoetste dosis, maar nie teen die lae dosis nie. Solitaire verbeter egter die deponering teen die laer dosis, maar minder deponering teen ‟n hoër dosis kan moontlik toegeskryf word aan oormatige druppel-afloop. In die geval van Villa 51 was geen betekenisvolle verbetering van spuitdeponering vir beide die behandelingsdosisse waargeneem nie. Spuitmengsels met byvoegmiddels, Agral 90 en Solitaire, het soortgelyke deponerings gelewer teen 600 L/ha in vergelyking met die fenhexamied kontrole teen 900 L/ha, maar deponering neem af teen hoër spuitvolumes met byvoegmiddels moontlik as gevolg van druppel-afloop. Hierdie studie wys duidelik die uitstekende potensiaal van Byvoegmiddels om kwantitatiewe en kwalitatiewe deponering te verbeter, maar beklemtoon die noodsaaklikheid van die korrekte gebruik van byvoegmiddel dosis en volume om die maksimum spuitdeponering op die teiken te verkry.
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Characterisation of pathogens associated with trunk diseases of grapevinesVan Niekerk, Jan Marthinus 04 1900 (has links)
Thesis (MScAgric )--Stellenbosch University, 2004. / ENGLISH ABSTRACT: In an attempt to combat some of the pathogens that are associated with trunk diseases and
disorders of grapevines, research in this thesis focused on the taxonomy and pathological aspects
of Coniellai/Pilidiella, Botryosphaeria and Phomopsis spp.
Previously, conidial pigmentation was used to separate Pilidiella from Coniella.
Recently, however, the two genera have been regarded as synonymous, with the older name,
Coniella, having priority. The most important species in the Coniellai/Pilidiella complex of
grapevines is C. diplodiella (Speg.) Petr. & Syd., the causal organism of white rot of grapevines.
Previous studies found it difficult to distinguish between C. diplodiella and C. fragariae
(Oudem.) B. Sutton, which is known to occur in soil and caused leaf diseases of Fragaria and
Eucalyptus. Both these species have previously been reported from South Africa. None of the
reports on C. diplodiella could be scientifically substantiated; therefore it is still a quarantine
organism. However, this status has been questioned. Based on sequence analyses of the internal
transcribed spacer region (ITS 1, ITS 2), 5.8S gene, large subunit (LSU) and elongation factor 1-
α gene (EF l- α) from the type species of Pilidiella and Coniella, Coniella was separated from
Pilidiella, with the majority of taxa residing in Pilidiella. Pilidiella is characterised by species
with hyaline to pale brown conidia (avg. length: width >1.5), with Coniella having dark brown
conidia (avg. length: width ≤1.5). Pilidiella diplodiella, previously C. diplodiella, causal
organism of white rot of grapevines, was shown to be an older name for C. petrakii. This fungus
is present in South Africa and is therefore no longer of quarantine importance. Based on
analyses of the histone (H3) gene sequences of isolates in the P. diplodiella species complex, P.
diplodiella was separated from a newly described species, P. diplodiopsis. A new species, P.
eucalyptorum, is proposed for isolates formerly treated as C. fragariae, associated with leaf
spots of Eucalyptus spp. This species clustered basal to Pilidiella, and may represent yet a third
genus within this complex. Pilidiella destruens was newly described as anamorph of
Schizoparme destruens, which is associated with twig dieback of Eucalyptus spp. in Hawaii.
The genus Botryosphaeria Ces. & De Not. are known to be cosmopolitan, with broad host
ranges and geographical distributions. Several saprotrophic species have been reported from
grapevines, while others are severe pathogens of this host. These species include B. dothidea
(Moug.: Fr.) Ces. & De Not., B. parva Pennycook & Samuels, B. obtusa (Schwein.) Shoemaker,
B. stevensii Shoemaker, B. lutea A.J.L. Phillips and B. ribis Grossenb. & Duggar. Species
reported from South Africa as grapevine pathogens are B. obtusa, B. dothidea, B. ribis and B.
vitis (Schulzer) Sacco. In the present study, morphological, DNA sequence data (ITS 1, 5.8S, ITS
2 and EFI-α) and pathological data were used to distinguish 11 Botryosphaeria spp. associated
with grapevines from South Africa and other parts of the world. Botryosphaeria australis, B.
lutea, B. obtusa, B. parva, B. rhodina and a Diplodia sp. were confirmed from grapevines in
South Africa, while Diplodia porosum, Fusicoccum viticlavatum and F. vitifusiforme were
described as new species. Although isolates of B. dothidea and B. stevensii were confirmed from
grapevines in Portugal, neither of these species, nor B. ribis, were isolated in this study. All
grapevine isolates from Portugal, formerly presumed to be B. rib is, are identified as B. parva
based on EF1-α sequence data. Artificial inoculations on grapevine shoots showed that B.
australis, B. parva, B. ribis and B. stevensii are more virulent than the other species studied. The
Diplodia sp. collected from grapevine canes was identified as morphologically similar, but
phylogenetically distinct from D. sarmentorum, while D. sarmentorum was confirmed as
anamorph of Otthia spiraeae, the type species of the genus Otthia (Botryosphaeriaceae). A
culture identified as O. spiraeae clustered within Botryosphaeria, and is thus regarded as a
probable synonym. These findings confirm earlier suggestions that the generic concept of
Botryosphaeria should be expanded to include genera with septate ascospores and Diplodia
anamorphs.
The genus Phomopsis (Sacc.) Bubak contains many species that are plant pathogenic or
saprotrophic. Ten species are known from grapevines. However, only two have been confirmed
as being pathogenic, namely P. viticola (Sacc.) Sacc., causal organism of Phomopsis cane and
leaf spot and P. vitimegaspora Kuo & Leu (teleomorph Diaporthe kyushuensis Kajitani &
Kanem.), causal organism of swelling arm disease of grapevines. P. amygdali (Delacr.) 1.1.
Tuset & M.T. Portilla, a known pathogen from Prunus sp., was shown to be a possible pathogen
of grapevines in a previous study. D. perjuncta Niessl. causes bleaching of dormant canes only
and is therefore of little importance as a grapevine pathogen. Recently a number of Phomopsis
isolates were obtained from grapevines in the Western Cape province of South Africa. Isolations
were made from Phomopsis-like symptoms, pruning wounds and asymptomatic nursery plants.
These isolates showed great variation in morphology and cultural characteristics. Earlier
taxonomic treatments of Phomopsis, based species identification on host specificity, cultural
characteristics and morphology. Recent studies have indicated that these characteristics can no
longer be used to distinguish species of Phomopsis due to wide host ranges and morphological
plasticity of some species. The use of anamorph/teleomorph relationships in species
identification is also untenable, since Diaporthe teleomorphs have only been described for
approximately 20% of the known Phomopsis species. In this study morphological data, DNA
sequences (ITS-I, 5.8S, ITS-2) and pathogenicity data were combined to distinguish Phomopsis
spp. from grapevines. Fifteen species of Phomopsis were delineated by phylogenetic analysis of
ITS sequence data. Diaporthe helianthi, a sunflower pathogen, was reported from grapevines for
the first time, with a further six, unknown species also distinguished. Three different clades
contained isolates previously identified as D. perjuncta. Based on type studies, it appeared that
the name D. viticola was available for collections from Portugal and Germany, a new species, D.
australafricana, was proposed for South African and Australian isolates, formerly treated as D.
perjuncta or D. viticola. An epitype specimen and culture were designated for D. perjuncta.
This species was distinguished from D. viticola and D. australafricana based on morphology and
DNA phylogeny. Artificial inoculations of green grapevine shoots indicated that, of the species
tested, P. amygdali, a known pathogen of peaches in the USA, and P. viticola were the most
virulent. / AFRIKAANSE OPSOMMING: In 'n poging om sommige patogene geassosieer met stamsiektes en syndrome, te beveg,
het die navorsing in die tesis gefokus op die taksonomie en patologiese aspekte van
ConiellaiPilidiella, Botryosphaeria en Phomopsis spp
Voorheen is konidium pigmentasie gebruik om Pilidiella (hialien tot ligbruin konidia) van
Coniella (donkerbruin konidia) te skei. Onlangs is hierdie twee genera egter as sinoniem beskou
met die ouer naam, Coniella, wat voorkeur gekry het. Die belangrikste spesies in die
ConiellaiPilidiella kompleks van wingerd is C. diplodiella (Speg.) Petr. & Syd., die
veroorsakende organisme van witvrot van wingerd. Vorige studies het dit moeilik gevind om te
onderskei tussen C. diplodiella en C. fragariae (Oudem.) B. Sutton, wat bekend is dat dit in
grond voorkom en ook blaarsiektes van Fragaria en Eucalyptus veroorsaak. Beide hierdie
spesies is tevore in Suid-Afrika aangemeld. Geen van die aanmeldings van C. diplodiella is
egter wetenskaplik bewys nie en daarom is dit steeds 'n kwarantyn organisme. Hierdie
kwarantyn status is egter bevraagteken. Op grond van DNS volgordes van die interne
getranskribeerde spasieerder area ("ITS 1", "ITS2"), die 5.8S rRNS geen, die groot ribosomale
subeenheid ("LSU") en die verlengingsfaktor 1-α geen ("EF-lα") van die tipe spesies van
Pilidiella en Coniella, is Coniella van Pilidiella geskei, met die meerderheid van die taxa wat
binne Pilidiella resorteer. Pilidiella word gekarakteriseer deur spesies met hialien tot ligbruin
konidia (gem. lengte: breedte > 1.5), in teenstelling met die donkerbruin konidia van Coniella
(gem. lengte: breedte ≤ 1.5). Daar is verder bewys dat Pilidiella diplodiella, voorheen C.
diplodiella, veroorsakende organisme van witvrot van wingerd, die ouer naam van C. petrakii is.
Hierdie swam is teenwoordig in Suid-Afrika en P. diplodiella is dus nie meer van kwarantyn
belang nie. Op grond van analises van die histoon (H3) volgordes van spesies in die P.
diplodiella spesies kompleks, is P. diplodiella geskei van 'n nuut beskryfde spesie, P.
diplodiopsis. 'n Nuwe spesie, P. eucalyptorum, is ook voorgestel vir isolate voorheen beskou as
C. fragariae, geassosieer met blaarvlek van Eucalyptus spp. Hierdie spesie het basaal van
Pilidiella gegroepeer en mag moontlik nog 'n derde genus binne hierdie kompleks
verteenwoordig. Pilidiella destruens is nuut as anamorf van Schizoparme destruens beskryf, wat
geassosieer word met loot terugsterwing van Eucalyptus spp. in Hawaii.
Die genus Botryosphaeria Ces. & De Not. is bekend as kosmopolitaans met 'n wye
gasheerreeks en geografiese verspreiding. Verskeie saprofitiese spesies is aangemeld vanaf
wingerd, terwyl ander ernstige patogene van hierdie gasheer is. Laasgenoemde spesies sluit in B.
dothidea (Moug.: Fr.) Ces. & De Not., B. parva Pennycook & Samuels, B. obtusa (Schwein.)
Shoemaker, B. stevensii Shoemaker, B. lutea A.1.L. Phillips en B. ribis Grossenb. & Duggar.
Spesies aangemeld in Suid-Afrika as wingerdpatogene, is B. obtusa, B. dothidea, B. ribis en B.
vitis (Schulzer) Sacco In hierdie studie is morfologiese, DNS volgorde data ("ITSl", "ITS2",
5.8S en "EF-Iα") en plantpatologiese data gebruik om II Botryosphaeria spesies, geassosieer
met wingerde in Suid-Afrika en verskeie ander werelddele, te onderskei. Botryosphaeria
australis, B. lutea, B. obtusa, B. parva, B. rhodina en 'n Diplodia sp. is bevestig van wingerde in
Suid-Afrika, terwyl Diplodia porosum, Fusicoccum viticlavatum en F. vitifusiforme as nuwe
spesies beskryf is. AIhoewel isolate van B. dothidea en B. stevensii bevestig is van wingerde in
Portugal, is geen van hierdie spesies en ook nie B. ribis geïsoleer nie. AIle isolate vanaf wingerd
in Portugal, voorheen beskou as B. rib is, is as B. parva op grond van hul "EF-lα" volgordes
geïdentifiseer. Uit kunsmatige isolasies gemaak op wingerdlote is die gevolgtrekking gemaak
dat B. australis, B. parva, B. ribis en B. stevensii meer virulent is as die ander spesies wat
bestudeer is. Die Diplodia sp. versamel vanaf wingerdlote is geïdentifiseer as morfologies
eenders, maar filogeneties verskillend van D. sarmentorum, terwyl D. sarmentorum bevestig is
as die anamorf van Otthia spiraeae, die tipe spesie van die genus Otthia (Botryosphaeriaceae).
'n Kultuur wat as 0. spiraeae geïdentifiseer is, het binne Botryosphaeria gegroepeer, en word
dus as 'n moontlike sinoniem beskou. Hierdie bevindinge bevestig vroeëre voorstelle dat die
generiese konsep van Botryosphaeria uitgebrei behoort te word om genera met gesepteerde
askospore en Diplodia anamorwe in te sluit.
Die genus Phomopsis (Sacc.) Bubak bevat verskeie spesies wat as of plantpatogenies, of
saprofities, beskryf is. Tien spesies is bekend op wingerd. Slegs twee is as patogenies bevestig,
naamlik P. viticola (Sacc.) Sacc., veroorsakende organisme van loot-en-blaarvlek ("streepvlek")
en P. vitimegaspora Kuo & Leu (teleomorf Diaporthe kyushuensis Kajitani & Kanem.),
veroorsakende organisme van geswelde arm van wingerd. In 'n vroeëre studie is bevind dat P.
amygdali (Delacr.) 1.1. Tuset & M.T. Portilla, 'n bekende patogeen van Prunus sp., moontlik ook
'n patogeen van wingerd mag wees. D. perjuncta Niessl. veroorsaak egter net verbleiking van
dormante lote en is dus van min belang as 'n wingerd patogeen. Gedurende die afgelope twee
jaar is verskeie Phomopsis isolate van wingerde in die Wes-Kaap provinsie van Suid-Afrika
verkry. Isolasies is gemaak van Phomopsis-agtige simptome, snoeiwonde en asimptomatiese
kwekeryplante. Die isolate verkry uit hierdie materiaal het groot variasie ten opsigte van
morfologie en kultuureienskappe getoon. Vroeëre taksonomiese verhandelings van Phomopsis
het spesies-identifikasie op gasheerspesifisiteit, kultuureienskappe en morfologie gebasseer.
Onlangse studies het egter getoon dat, weens wye gasheerreekse en morfologiese plastisiteit van
somnuge spesies, hierdie eienskappe me meer gebruik kan word om Phomopsis spesies te
identifiseer nie. Die gebruik van anamorflteleomorf verwantskappe in die identifikasie van
Phomopsis spesies ook onbruikbaar omdat Diaporthe teleomorwe vir slegs ongeveer 20% van
die bekende Phomopsis spesies beskryf is. Die huidige studie het dus morfologiese data, DNS
volgordes ("ITS 1", 5.8S, "ITS2") en patogenisiteitsdata gekombineer ten einde Phomopsis spp.
vanaf wingerd te identifiseer. Vyftien Phomopsis spesies is deur die filogenetiese analise van die
interne getranskribeerde spasieerder area ("ITS") volgordes geskei. Diaporthe helianthi, 'n
bekende patogeen van sonneblomme, is vir die eerste maal op wingerd aangeteken, terwyl 'n
verdere ses, tans onbekende spesies van Phomopsis ook geidentifiseer is. Drie verskillende
groepe het isolate bevat wat voorheen as D. perjuncta geidentifiseer is. Gebasseer op studies van
tipes, het dit voorgekom dat die naam D. viticola beskikbaar is vir isolate uit Portugal en
Duitsland. 'n Nuwe spesie, D. australafricana, is voorgestel vir Suid-Afrikaanse en Australiese
isolate wat voorheen behandel is as D. perjuncta of D. viticola. 'n Epitipe monster en kultuur is
vir D. perjuncta benoem. Hierdie spesie is van D. viticola en D. australafricana onderskei op
grond van morfologie en DNS filogenie. Kunsmatige inokulasies van groen wingerdlote het
getoon dat P. amygdali, bekende perske patogeen, en P. viticola die mees virulent was.
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n Studie van Botrytis cinerea met verwysing na die effek van swaeldioksiedtoedienings, verskillende tye na bespuiting van druiwekorrels met konidia, op die intensiteit van vaalvrotCombrink, J. C. (Jacob Coenraad), 1918- 12 1900 (has links)
Thesis (MScAgric)--Stellenbosch University, 1972. / ENGLISH ABSTRACT: no abstract available
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Biochemiese veranderinge in druiwemos veroorsaak deur Botrytis cinerea en Rhizopus nigricansHofmann, Gerhard 12 1900 (has links)
Thesis (MScAgric)--Stellenbosch University, 1964. / ENGLISH ABSTRACT: no abstract available / AFRIKAANSE OPSOMMING: geen opsomming
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Incidence and epidemiology of apple core rot in the Western Cape of South AfricaBasson, Elaine 12 1900 (has links)
Thesis (MScAgric)--Stellenbosch University, 2012. / ENGLISH ABSTRACT: This study looked at the incidence, etiology and epidemiology of core rot of apples in orchards situated in the Western Cape, South Africa. Core rot is a post-harvest disease, with three symptoms, namely mouldy core (MC), dry core rot (DCR) and wet core rot (WCR). These symptoms are caused by various pathogenic fungi, including Alternaria and Penicillium. Although MC is not economically important, DCR and WCR are, as they affect the flesh of the fruit. Core rot occurs worldwide in susceptible apple cultivars such as ‘Starking’ and ‘Red Delicious’. These cultivars have a wider, open calyx tube which results in an open core area. In South Africa, core rot of apples are important post-harvest diseases and losses of between 5 and 12% occur in apple cultivars.
An in depth literature search was done on core rot including literature on each core rot symptom, the genuses Alternaria and Penicillium, molecular identification and techniques, disease incidence and its economic importance, various inoculum sources, pathogenicity of core rot organisms and integrated management of core rot. This study included two research chapters, with seven objectives, namely, to 1, determine the incidence of core rot in apples from commercial orchards both pre- and post-harvest; 2, to identify the causal organisms associated with core rot symptoms; 3, to identify potential sources of inoculum of core rot pathogens and determine whether there is synergism between Alternaria and Tarsonemus mites associated with core rot; and 4, to determine whether the fungicide Bellis®, used a full bloom application, can be used to manage core rot in South Africa; 5, to identify the species of Alternaria and Penicillium sampled from core rot symptomatic fruit and inoculum sources (air, apple mummies and mites), using morphological and molecular methods; 6, to compare Penicillium species isolated from pre- and post-harvest WCR symptomatic fruit, using molecular species identification methods and 7, to compare and to select the most reliable pathogenicity test for use in future research.
The total decay incidence for Ceres is considerably higher than the previous losses indicated in literature. Pre-harvest core rot, which was confirmed by previous studies, had a higher incidence of each core rot symptom than previously indicated. The two most frequently isolated causal organisms were Alternaria and Penicillium. Other organisms isolated and then identified from the symptoms were Fusarium, Cladosporium, Epicoccum, Ulocladium, Stemphylium, Phoma, Botryosphaeria, Botrytis, Trichoderma, Verticillium, Paecilomyces and Gliocladium.
Three inoculum sources, air, mummies and mites, were regarded as potential sources of infection for core rot. During this study the sources of infection were verified and core rot causing organisms were isolated from these sources. Alternaria was isolated from air inoculum samples, but was not found on the other two sources. This dismissed the hypothesis that there was a possible synergism between Alternaria and Tarsonemus mites. Penicillium species were isolated from all three sources, more frequently from the mummies and mites. Bellis® was applied three times during the bloom period. The subsequent results showed a significant difference between the control and Bellis® treated treatments with the treated fruit having a significant higher incidence than the controlled fruit. No control was observed with this result and managing core rot with only Bellis® is not advisable.
Alternaria species were identified using the following genetic loci, ITS, OPA1-3, 2-1 and 10-2 as well as endoPG. Isolates from pre- and post-harvest symptoms and air inoculum were identified using each of the genetic loci. Alternaria arborescens was one of the species that was identified. The other isolates obtained were A. alternata, A. tenuissima, A. gaisen, A. dumosa, A. turkisafria and A. perangusta. Separating combined species was not possible. Another molecular technique, ISSR, was used to identify Alternaria species. This technique, after multiple re-runs, did not give consistent results and species could not be identified. Penicillium species were identified using the genetic loci ITS for isolates collected from pre- and post-harvest symptoms and inoculum sources. Thirteen clades were identified, including the species P. ramulosum, P. sp. (aff. cecidicola), P. sp (aff. dendriticum), P. expansum, P. paneum, P. solitum, P. crustosum , P. brevicompactum, P. novae-zeelandiae, P. glabrum and P. rugulosum. Penicillium expansum and P. ramulosum had the highest distribution between the isolates. Pre- and post-harvest WCR isolates were identified using the partial beta-tubulin PCR-RFLP method, and comparing different banding-patterns. The species identified using this method were P. expansum, P. ramulosum, P. sp. (aff. cecidicola), P. sp (aff. dendriticum), P. rugulosum, P. chermesinum and P. glabrum. Penicillium ramulosum and P. expansum had the highest incidence with P. ramulosum occurring more frequently pre-harvest than post-harvest and P. expansum occurring more frequently post-harvest.
Five methods, previously published, were compared to select the most reliable pathogenicity test. The methods included surface wounding of an apple with colonised toothpicks, surface wound inoculated with a pipette, inoculation of an open mesoderm core cavity, deep and non-wounding of apple fruit with colonised toothpicks. The surface wounding with a colonised toothpick gave the most reliable results and can be used in industry as a pathogenicity test for Alternaria in apples.
This study contributed to our understanding on the incidence and etiology of core rot in the Western Cape as well as in identifying inoculum sources from where infection can take place in the orchard. The results for the fungicide trial were not as anticipated and more research is required on selecting fungicides for the control of core rot in South African orchards. Although molecular techniques reduce the time in identifying fungal species, it is costly and mistakes can occur due to contamination. Identification of species can be incorrect when using a Genbank as the sequence information may be incorrect. Molecular techniques, though a good tool in identifying species, should be combined with morphological characteristics to ensure more accurate results. / AFRIKAANSE OPSOMMING: Hierdie studie het gekyk na die insidensie, etiologie en epidemiologie van kernvrot in appels vanuit boorde in die Wes-Kaap, Suid-Afrika. Kernvrot is ‘n na-oes iekte, met drie simptome, naamlik beskimmelde kern, droë kernvrot en nat kernvrot. Hierdie simptome word veroorsaak deur verskillende patogeniese swamme, insluitend Alternaria en Penicillium. Alhoewel beskimmelde kern nie ekonomies belangrik is nie, is droë en nat kernvrot wel belangrik, omdat hulle die vrug se vlees affekteer. Kernvrot kom wêreldwyd voor in vatbare kultivars soos ‘Starking’ en ‘Red Delicious’. Hierdie kultivars het ‘n wye, oop kelkbuis wat ‘n oop kern area veroorsaak. In Suid-Afrika is kernvrot van appels ‘n belangrike na-oes siekte en verliese tussen 5 en 12% kom voor in appel kultivars.
‘n In diepte literatuurstudie is gedoen omtrent kernvrot, insluitend literatuur omtrent elke kernvrot simptoom, die genera Alternaria en Penicillium, molekulêre identifikasie en tegnieke, siekte insidensie en sy ekonomiese impakte, verskillende inokulum bronne, patogenisiteit van kernvrot organismes en die geïntegreerde bestuur van kernvrot. Hierdie studie sluit in twee navorsings hoofstukke met sewe doelwitte, naamlik om 1, te bepaal wat die insidensie van kernvrot in appels is vanuit kommersiële boorde vir beide voor en na-oes; 2, om veroorsakende organismses wat met kernvrot simptome geassosieër is te identifiseer; 3, om potensiële inokulum bronne van kernvrot patogene te identifiseer en te bepaal of daar ‘n sinergisme tussen Alternaria en Tarsonemus myte, wat geassosieër is met kernvrot, is; 4, om te bepaal of die fungisied Bellis®, gebruik as ‘n volblom toediening, gebruik kan word om kernvrot in Suid-Afrika te beheer; 5, om die Alternaria en Penicillium spesies wat uit simptomatiese kernvrot vrugte en inokulum bronne geïsoleer is te identifiseer; 6, om Penicillium spesies, wat uit voor en na-oes nat kernvrot simptome geïsoleer is, te vergelyk deur gebruik te maak van molekulêre spesies identifiserings metodes en 7, om die betroubaarste patogenisiteits toets te vergelyk en selekteer vir toekomstige gebruik.
Die totale bederfde insidensie vir Ceres is heelwat hoër as die vorige verliese wat aangedui is in literatuur. Vooroes kernvrot, wat deur vorige studies bevestig is, het ‘n hoër insidensie vir elke kernvrot simptoom gehad as wat voorheen aangedui is. Die twee geïsoleerde veroorsakende organismes wat die meeste voorgekom het was Alternaria en Penicillium. Ander organismes wat geïsoleer en geïdentifiseer is vanuit die simptome was Fusarium, Cladosporium, Epicoccum, Ulocladium, Stemphylium, Phoma, Botryosphaeria, Botrytis, Trichoderma, Verticillium, Paecilomyces en Gliocladium. Drie inokulum bronne, lug, gemummifiseerde vrugte en myte, is geag as potensiële bronne van infeksie vir kernvrot. Gedurende hierdie studie is hierdie bronne bevestig en kernvrot veroorsakende organismes is uit die bronne geïsoleer. Alternaria is geïsoleer vanuit die lug inokulum monsters, maar is nie geïsoleer vanuit die ander twee bronne nie. Dus die hipotese dat daar ‘n sinergisme tussen Alternaria en Tarsonemus myte is, is verwerp. Penicillium spesies is geïsoleer vanuit al drie bronne, maar meer gereeld vanuit die gemummifiseerde vrugte en die myte. Bellis® is drie keer gedurende die bot toegedien. Die daaropvolgende resultate het ‘n betekenisvolle verskil tussen die kontrole en Bellis® beheerde behandelings getoon, met die behandelde vrugte wat ‘n betekenisvolle hoër insidensie gehad het as die kontrole vrugte. Geen beheer is waargeneem nie en beheer van kernvrot met net Bellis® word nie aanbeveel nie.
Alternaria spesies is geïdentifiseer deur die volgende genetise lokusse, ITS, OPA1-3, 2-1 en 10-1, asook endoPG. Isolate van voor en na-oes simptome en lug inokulum is geïdentifiseer deur elk van die genetiese lokusse. Alternaria arborescens is een van die spesies wat geïdentifiseer is. Ander isolate wat verkry is, was A. alternata, A. tenuissima, A. gaisen, A. dumosa, A. turkisafria and A. perangusta. Om gekombineerde spesies te skei was nie moontlik nie. ‘n Ander molekulêre tegniek, ISSR, was gebruik om Alternaria spesies te identifiseer. Hierdie tegniek, na menigte probeerslae, het nie konsekwente resultate gegee nie en spesies kon nie hiermee geïdentifiseer word nie. Penicillium spesies, versamel vanuit voor en na-oes simptome en inokulum bronne, is geïdentifiseer deur die genetiese lokus ITS. Dertien ‘clades’ is geïdentifiseer, insluitend die spesies P. ramulosum, P. sp. (aff. cecidicola), P. sp (aff. dendriticum), P. expansum, P. paneum, P. solitum, P. crustosum , P. brevicompactum, P. novae-zeelandiae, P. glabrum en P. rugulosum. Penicillium expansum en P. ramulosum het die hoogste distribusie tussen die isolate. Voor en na-oes nat kernvrot isolate is geïdentifiseer deur die deels beta-tubulin PCR-RFLP metode, en verskillende band patrone te vergelyk. Die spesies geïdentifiseer deur hierdie metode is P. expansum, P. ramulosum, P. sp. (aff. cecidicola), P. sp (aff. dendriticum), P. rugulosum, P. chermesinum en P. glabrum. Penicillium ramulosum en P. expansum het die hoogste insidensie gehad met P. ramulosum wat meer dikwels vooroes voorkom en P. expansum wat meer dikwels na-oes voorkom.
Vyf metodes, wat voorheen gepubliseer is, is vergelyk om die betroubaarste patogenisiteits toets te selekteer. Die metodes sluit in die oppervlak wond van ‘n appel met ‘n gekoloniseerde tandestokkie, oppervlak wond geïnokuleer met ‘n pipette, inokulasie van ‘n oop mesoderm kern area, diep besering en nie-besering van die appel met gekoloniseerde tandestokkies. Die oppervlak besering met ‘n gekoloniseerde tandestokkie het die betroubaarste resultate gegee en kan in die industrie gebruik word as ‘n patogenisiteits toets vir Alternaria in appels.
Hierdie studie het bygedra tot ons kennis van die insidensie en etiologie van kernvrot in die Wes-Kaap sowel as die identifisering van die inokulum bronne, van waar die infeksie in die boord kan plaasvind. Die resultate vir die fungisied proef was nie wat ons verwag het nie en meer navorsing word benodig om fungisiede te selekteer vir die beheer van kernvrot in Suid-Afrikaanse boorde. Alhoewel molekulêre tegnieke die tyd verminder om ‘n swam spesie te identifiseer, is dit wel duur en foute kan voorkom as gevolg van kontaminasie. Identifikasie van spesies kan verkeerd wees indien Genbank gebruik is, omdat die informasie daar nie altyd korrek is nie. Molekulêre tegnieke, alhoewel ‘n goeie manier om spesies te identifiseer, moet gekombineer word met morfologiese karakter eienskappe om akurate resultate te verseker.
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The role of arthropods in the dispersal of trunk disease pathogens associated with Petri disease and EscaMoyo, Providence 03 1900 (has links)
Thesis (MScAgric)--Stellenbosch University, 2013. / ENGLISH ABSTRACT: Petri disease and esca are devastating grapevine trunk diseases and compromise the
sustainability of viticulture world-wide. Despite being extensively studied, knowledge of
inoculum sources and mechanisms of spread of the causal pathogens is limited. Arthropods
have been suspected to play a role in the spread of Petri disease and esca pathogens.
However, little information is known about the extent to which arthropods are associated
with these pathogens. This study aimed to determine whether arthropods occurring within or
on declining grapevines, are associated with trunk disease pathogens and to identify
arthropods associated with pruning wounds. The potential of selected arthropods to act as
vectors of trunk disease pathogens was also investigated.
Two vineyards exhibiting grapevine trunk disease infections were sampled weekly
for two years for collection of arthropods. Arthropods were collected using pruning wound
traps, visual searches as well as trunk and cordon traps. Fungal spores from surfaces of
arthropods were collected in water. Samples were subjected to nested PCR using primers
Pm1/Pm2 and Pch1/Pch2 to verify the presence of Phaeoacremonium spp. and
Phaeomoniella chlamydospora, respectively. Water samples were also cultured and
grapevine trunk disease pathogens obtained were identified by sequencing the internal
transcribed spacers 1 and 2 and the 5.8S rRNA gene or the partial beta-tubulin gene. A total
of 10 875 arthropod individuals, belonging to more than 31 families, were collected from
declining grapevines. The most abundant arthropods included millipedes, ants, spiders and
beetles. Portuguese millipedes and cocktail ants were associated with fresh grapevine
pruning wounds. Thirty-three percent of the 5677 water samples analysed, contained
propagules of pathogens associated with Petri disease and esca. Of these, 37 % were
recovered from millipedes, 22 % from cocktail ants, 15 % from spiders and 10 % from
beetles. All the major groups of grapevine trunk diseases were detected on the arthropods. Phaeoacremonium species were detected in 1242 samples while Phaeomoniella
chlamydospora was identified from 855 samples. Other fungi isolated included members of
the Botryosphaeriaceae, Diatrypaceae and Diaporthales.
The potential of grapevine sap as a food source for Portuguese millipedes and
cocktail ants was investigated, in vitro. Millipede individuals were offered a choice between
water and grapevine sap while ants in nests were presented with grapevine sap, tuna and
water and monitored for ingestion of sap. Both taxa preferred grapevine sap over the other food items, indicating close association with pruning wounds. Subsequently, the ability of
both taxa to transmit a DsRed-transformed Phaeomoniella chlamydospora isolate to fresh
pruning wounds of canes in polystyrene strips, floating in water, and potted vines was
tested. Arthropods were exposed to the fungus for 24 hours and transferred to the base of the
plants and canes and were removed after three days. Isolations after a month revealed that
millipedes and ants were capable of transmitting the fungus onto wounds and cause
infection. Millipede faecal pellets were also evaluated as potential sources of inoculum.
Millipedes were fed on Phaeomoniella chlamydospora for 24 hours, surface sterilised and
allowed to defaecate in sterile Petri dishes overnight. Faecal material was collected,
macerated in water and plated onto potato dextrose agar. Propagules of Phaeomoniella
chlamydospora survived passage through the gut of millipedes and were passed out in a
viable state to form colonies of Phaeomoniella chlamydospora.
This study concludes that a wide variety of arthropods can be a source of inoculum
of trunk diseases in vineyards. The results of the dissemination trial provides evidence that
millipedes and ants are able to disseminate and infect vines with Phaeomoniella
chlamydospora. It is therefore, highly likely that other grapevine trunk disease pathogens
are transmitted in the same manner. This knowledge highlights the need for control of
certain arthropods to be taken into consideration when managing grapevine trunk disease
pathogens. / AFRIKAANSE OPSOMMING: Petri siekte en esca is verwoestende wingerd stamsiektes en verhinder die
volhoubaarheid van wingerdproduksie wêreldwyd. Hierdie siektes is al intensief bestudeer,
maar kennis rakende die inokulum bronne en meganismes van verspreiding van die
veroorsakende patogene is beperk. Arthropoda is al vermoed om ‘n rol te speel in die
verspreiding van Petri siekte en esca patogene, maar weinig informasie is bekend oor die
mate waartoe arthropoda geassosieer is met die patogene. Hierdie studie het ten doel gestel
om die arthropoda wat op of in wingerdstokke wat terugsterf voorkom te identifiseer en te
bepaal watter van die arthropoda geassosieer is met stamsiekte patogene. Daar is ook ten
doel gestel om die arthropoda wat geassosieer is met vars snoeiwonde te identifiseer en ook
die moontlike vektor status van die stamsiekte patogene deur arthropoda.
Arthropoda is weekliks vir twee jaar gekollekteer vanaf twee wingerde met
stamsiekte infeksies. Snoeiwond lokvalle, visuele soektogte en stam- en kordon lokvalle
was gebruik om arthropoda te vang. Swamspore van die oppervlak van die arthropoda is
afgewas met water. Van hierdie water monsters is gebruik om dubbelvoudige polimerase
ketting reaksies (PKR) te doen met die inleiers Pm1/Pm2 en Pch1/Pch2 om vir die
teenwoordigheid van Phaeoacremonium spp. en Phaeomoniella chlamydospora
onderskeidelik te toets. Die oorblywende water monster is gekweek op medium om die
swamme teenwoordig te bepaal. Die wingerd stamsiekte patogene is verder geidentifiseer
deur die DNS volgordes te bepaal van die interne getranskribeerde spasies 1 en 2 en die
5.8S rRNS geen of ‘n gedeelte van die beta-tubulien geen. In totaal is 10 875 arthropoda,
wat behoort tot 31 families, gekollekteer vanaf wingerde wat terugsterf. Die mees algemene
arthropoda was duisendpote, miere, spinnekoppe en kewers. Die Portugese duisendpote en
die wipstert mier is geassosieer met vars wingerd snoeiwonde. Van die 5677 water monsters wat geanaliseer is, het 33% propagules van die Petri siekte of esca patogene gehad. Van
hierdie was 37 % afkomstig vanaf duisendpote, 22 % van wipstert miere, 15 % van
spinnekoppe en 10 % van kewers. Al die hoofgroepe van wingerd stampatogene is
opgespoor op die arthropoda. Phaeoacremonium species is opgespoor in 1242 monsters en
Phaeomoniella chlamydospora is gevind in 855 monsters. Ander swamme wat ook geisoleer
is sluit lede van die Botryosphaeriaceae, Diatrypaceae en Diaporthales in.
Die potensiaal van wingerdsap as ‘n bron van voedsel vir Portugese duisendpote en
wipstert miere is in vitro ondersoek. Duisendpoot invidue is ‘n keuse gegee tussen water en wingerd sap terwyl mierneste ‘n keuse gehad het tussen water, wingerd sap en tuna. Die
duisendpote en miere is gemonitor vir die inname van wingerdsap in die teenwoordigheid
van die ander bronne. Beide die duisendpote en miere het wingerdsap verkies wat aandui dat
hulle ‘n noue assosiasie met wingerd snoeiwonde het. Vervolgens is beide taksons getoets
vir hul vermoë om ‘n DsRooi-getransformeerde Phaeomoniella chlamydospora isolaat te
vektor na vars snoeiwonde op lote gemonteer op polistireen stroke wat in water dryf en op
wingerd plante in potte. Die duisendpote en miere is blootgestel aan die swam vir 24 uur en
oorgedra na die basis van die plante en lote en is weer verwyder na drie dae. Na ‘n maand is
isolasies gedoen wat gewys het dat die duisendpote en miere die swam suksesvol kon oordra
na die snoeiwonde en infeksie veroorsaak. Duisendpoot uitwerpsels is geëvalueer vir die
potensiaal as inokulum bron. Duisendpote het gevoed op Phaeomoniella chlamydospora vir
24 uur, daarna oppervlakkig gesteriliseer en toegelaat om oornag uitwerpsels te maak in
steriele Petri bakkies. Uitwerpsels was gekollekteer, fyngemaak in water en op aartappel
dekstrose agar uitgeplaat. Propagules van Phaeomoniella chlamydospora het die
verteringskanaal van die duisendpote oorleef en het tipiese kolonies op die agar gevorm.
Hierdie studie het vasgestel dat ‘n verskeidenheid van arthropoda ‘n bron van
inokulum van stamsiektes in wingerd kan wees. Die resultate van die vektor proewe het
gewys dat duisendpote en miere die vermoë het om Phaeomoniella chlamydospora te
versprei na snoeiwonde wat die swam dan suksesvol geinfekteer het. Dit is daarom hoogs
waarskynlik dat van die ander wingerd stamsiekte patogene ook versprei kan word op
dieselfde manier. Hierdie kennis demonstreer dat die beheer van spesifieke arthropoda in ag
geneem moet word in die bestuur van wingerd stamsiektes. / Winetech, Agricultural Research Council of South Africa and NRF for financial support
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