TY  - JOUR
AU  - Bulajić, Aleksandra
AU  - Vučurović, A
AU  - Stanković, Ivana
AU  - Ristić, Danijela
AU  - Berenji, Janoš
AU  - Krstić, Branka
PY  - 2010
UR  - https://plantarum.izbis.bg.ac.rs/handle/123456789/1090
AB  - As there is a growing frequency of viral plant diseases in epidemic proportions, the possibilities for successful control are constantly being explored. Despite the fact that integral and simultaneous employment of numerous control measures may contribute to the decreasing amount of yield losses, especially concerning non-persistently aphid-transmitted viruses, these measures are often not efficient enough. Research into the basis of resistance to viral infection and principles of its inheritance, introduction of sources of resistance in susceptible genotypes, by conventional or genetic manipulations, are very intensive for cucurbit crops, especially pumpkins. Pumpkin crops are being endangered by a great number of different viruses, among which the Zucchini yellow mosaic virus, (ZYMV), Watermelon mosaic virus (WMV) and Cucumber mosaic virus (CMV) are present every year in Serbia, frequently causing epidemics. The majority of pumpkin cultivars are not resistant or tolerant to viral infections, but sources of resistance have been identified in various related species. So far, the identified sources of resistance to the ZYMV are found in Cucurbita moschata and Citrullus lanatus var. lanatus genotypes and consist of one or several major dominant genes of resistance. It is a similar case with WMV, although the sources of dominant major genes are identified in C. lanatus and C. colocynthis. The sources of resistance to CMV in the form of one dominant gene have been identified in the genotype C. moschata, although the introduction of this gene by conventional means proved to be very difficult. Besides the aforementioned, substantial efforts are being made in developing genotypes with multiple resistance against several viruses and even other pathogens, as well as genotypes with resistance to the most significant plant aphid species, through mechanisms of antixenosis or antibiosis. The other way of obtaining resistant genotypes includes genetic manipulation. Genetically modified resistant pumpkins have been among the first successfully developed crops. Genotypes with pathogen derived resistance can already be found in commercially grown pumpkins in some parts of the world, and they have been developed by introducing the coat protein gene of one, two or all three viruses which are the most frequent, ZYMV, WMV and CMV. Yet, this approach to the control of pumpkin viral diseases is related to possible negative consequences, mostly through the already detected gene transfer to wild plants and development of resistant transgenic weeds of unpredictable impact on the environment. Improved host plant genetic resistance to viral infections or biological vectors, developed by conventional or genetic engineering methods, represents the most dynamic and prominent field of research. It is economically and ecologically the most justified approach to the control of pumpkin and other plant diseases caused by viruses non-persistently transmitted by aphids.
PB  - Institute of Pesticides and Environmental Protection, Belgrade & Plant Protection Society of Serbia, Belgrade
T2  - Pesticides and Phytomedicine/Pesticidi i fitomedicina
T1  - Novel approaches to implementation of pumpkin resistance in control of viral diseases
EP  - 211
IS  - 3
SP  - 201
VL  - 25
DO  - 10.2298/PIF1003201B
ER  - 

@article{
author = "Bulajić, Aleksandra and Vučurović, A and Stanković, Ivana and Ristić, Danijela and Berenji, Janoš and Krstić, Branka",
year = "2010",
abstract = "As there is a growing frequency of viral plant diseases in epidemic proportions, the possibilities for successful control are constantly being explored. Despite the fact that integral and simultaneous employment of numerous control measures may contribute to the decreasing amount of yield losses, especially concerning non-persistently aphid-transmitted viruses, these measures are often not efficient enough. Research into the basis of resistance to viral infection and principles of its inheritance, introduction of sources of resistance in susceptible genotypes, by conventional or genetic manipulations, are very intensive for cucurbit crops, especially pumpkins. Pumpkin crops are being endangered by a great number of different viruses, among which the Zucchini yellow mosaic virus, (ZYMV), Watermelon mosaic virus (WMV) and Cucumber mosaic virus (CMV) are present every year in Serbia, frequently causing epidemics. The majority of pumpkin cultivars are not resistant or tolerant to viral infections, but sources of resistance have been identified in various related species. So far, the identified sources of resistance to the ZYMV are found in Cucurbita moschata and Citrullus lanatus var. lanatus genotypes and consist of one or several major dominant genes of resistance. It is a similar case with WMV, although the sources of dominant major genes are identified in C. lanatus and C. colocynthis. The sources of resistance to CMV in the form of one dominant gene have been identified in the genotype C. moschata, although the introduction of this gene by conventional means proved to be very difficult. Besides the aforementioned, substantial efforts are being made in developing genotypes with multiple resistance against several viruses and even other pathogens, as well as genotypes with resistance to the most significant plant aphid species, through mechanisms of antixenosis or antibiosis. The other way of obtaining resistant genotypes includes genetic manipulation. Genetically modified resistant pumpkins have been among the first successfully developed crops. Genotypes with pathogen derived resistance can already be found in commercially grown pumpkins in some parts of the world, and they have been developed by introducing the coat protein gene of one, two or all three viruses which are the most frequent, ZYMV, WMV and CMV. Yet, this approach to the control of pumpkin viral diseases is related to possible negative consequences, mostly through the already detected gene transfer to wild plants and development of resistant transgenic weeds of unpredictable impact on the environment. Improved host plant genetic resistance to viral infections or biological vectors, developed by conventional or genetic engineering methods, represents the most dynamic and prominent field of research. It is economically and ecologically the most justified approach to the control of pumpkin and other plant diseases caused by viruses non-persistently transmitted by aphids.",
publisher = "Institute of Pesticides and Environmental Protection, Belgrade & Plant Protection Society of Serbia, Belgrade",
journal = "Pesticides and Phytomedicine/Pesticidi i fitomedicina",
title = "Novel approaches to implementation of pumpkin resistance in control of viral diseases",
pages = "211-201",
number = "3",
volume = "25",
doi = "10.2298/PIF1003201B"
}

Bulajić, A., Vučurović, A., Stanković, I., Ristić, D., Berenji, J.,& Krstić, B.. (2010). Novel approaches to implementation of pumpkin resistance in control of viral diseases. in Pesticides and Phytomedicine/Pesticidi i fitomedicina
Institute of Pesticides and Environmental Protection, Belgrade & Plant Protection Society of Serbia, Belgrade., 25(3), 201-211.
https://doi.org/10.2298/PIF1003201B

Bulajić A, Vučurović A, Stanković I, Ristić D, Berenji J, Krstić B. Novel approaches to implementation of pumpkin resistance in control of viral diseases. in Pesticides and Phytomedicine/Pesticidi i fitomedicina. 2010;25(3):201-211.
doi:10.2298/PIF1003201B .

Bulajić, Aleksandra, Vučurović, A, Stanković, Ivana, Ristić, Danijela, Berenji, Janoš, Krstić, Branka, "Novel approaches to implementation of pumpkin resistance in control of viral diseases" in Pesticides and Phytomedicine/Pesticidi i fitomedicina, 25, no. 3 (2010):201-211,
https://doi.org/10.2298/PIF1003201B . .

TY  - JOUR
AU  - Vučurović, Ana
AU  - Bulajić, Aleksandra
AU  - Stanković, Ivana
AU  - Ristić, Danijela
AU  - Berenji, Janoš
AU  - Krstić, Branka
PY  - 2010
UR  - https://plantarum.izbis.bg.ac.rs/handle/123456789/1122
AB  - Virus mozaika lubenice (Watermelon mosaic virus, WMV) široko je rasprostranjen u usevima vrežastih kultura, mada se najčešće javlja na Mediteranu i regionima sa umerenom klimom. U Srbiji, WMV je detektovan u pojedinačnim i mešanim infekcijama sa virusom žutog mozaika cukinija (Zucchini yellow mosaic virus, ZYMV) i virusom mozaika krastavca (Cucumber mosaic virus, CMV) u usevima tikava i bundeva gajenim na otvorenom polju. Od virusa tikava, WMV je često prevalentan virus, kako po broju lokaliteta u kojima je dokazan, tako i po učestalosti u samom usevu. Iz ukupno 12 komercijalnih useva na osam lokaliteta, 2009. godine sakupljeno je 583 biljaka Cucurbita pepo cvs. Olinka, Beogradska tikvica i Tosca (cukini forma), kao i C. maxima i C. moschata, sa simptomima virusnih zaraza, koje su analizirane na prisustvo šest najznačajnijih virusa tikava primenom DAS-ELISA metode. WMV je detektovan na manjem broju lokaliteta i u manjoj učestalosti u poređenju sa prethodne dve vegetacije. U pojedinačnim infekcijama, WMV je detektovan u 11% testiranih biljaka u tri useva, a u mešanim sa ZYMV u 9,9% testiranih biljaka u pet useva i sa CMV u 0,2% testiranih biljaka u jednom usevu. Deo gena za protein omotača virusa i deo 3' neprepisujućeg regiona dva odabrana izolata WMV poreklom iz različitih lokaliteta i biljaka domaćina umnožen je primenom RT-PCR metode, sekvencioniran i upoređen sa sekvencama dostupnim u GenBank bazi podataka. Dobijen je PCR produkt očekivane veličine od 1017 bp. Sekvence izolata 137-08 (Acc. No. GQ259958) i 159-08 (GU144020) pokazale su 94-99% nukleotidne identičnosti sa izolatima WMV iz drugih delova sveta. Sekvence ova dva izolata razlikovala su se jedna od druge samo u dva nukleotidna mesta što nije imalo za posledicu aminokiselinske supstitucije. Filogenetske analize 57 izolata, na osnovu 750 bp sekvence gena za protein omotača, nisu ukazale na korelaciju sa geografskim poreklom izolata, a pokazala su grupisanje izolata u tri molekularne grupe sojeva. Izolati WMV iz Srbije pripadaju grupi I, grupi koja obuhvata najrasprostranjenije izolate ovog virusa u svetu.
PB  - Institute of Pesticides and Environmental Protection, Belgrade & Plant Protection Society of Serbia, Belgrade
T2  - Pesticides and Phytomedicine/Pesticidi i fitomedicina
T1  - Frequency and molecular characterization of watermelon mosaic virus from Serbia
EP  - 230
IS  - 3
SP  - 213
VL  - 25
DO  - 10.2298/PIF1003213V
ER  - 

@article{
author = "Vučurović, Ana and Bulajić, Aleksandra and Stanković, Ivana and Ristić, Danijela and Berenji, Janoš and Krstić, Branka",
year = "2010",
abstract = "Virus mozaika lubenice (Watermelon mosaic virus, WMV) široko je rasprostranjen u usevima vrežastih kultura, mada se najčešće javlja na Mediteranu i regionima sa umerenom klimom. U Srbiji, WMV je detektovan u pojedinačnim i mešanim infekcijama sa virusom žutog mozaika cukinija (Zucchini yellow mosaic virus, ZYMV) i virusom mozaika krastavca (Cucumber mosaic virus, CMV) u usevima tikava i bundeva gajenim na otvorenom polju. Od virusa tikava, WMV je često prevalentan virus, kako po broju lokaliteta u kojima je dokazan, tako i po učestalosti u samom usevu. Iz ukupno 12 komercijalnih useva na osam lokaliteta, 2009. godine sakupljeno je 583 biljaka Cucurbita pepo cvs. Olinka, Beogradska tikvica i Tosca (cukini forma), kao i C. maxima i C. moschata, sa simptomima virusnih zaraza, koje su analizirane na prisustvo šest najznačajnijih virusa tikava primenom DAS-ELISA metode. WMV je detektovan na manjem broju lokaliteta i u manjoj učestalosti u poređenju sa prethodne dve vegetacije. U pojedinačnim infekcijama, WMV je detektovan u 11% testiranih biljaka u tri useva, a u mešanim sa ZYMV u 9,9% testiranih biljaka u pet useva i sa CMV u 0,2% testiranih biljaka u jednom usevu. Deo gena za protein omotača virusa i deo 3' neprepisujućeg regiona dva odabrana izolata WMV poreklom iz različitih lokaliteta i biljaka domaćina umnožen je primenom RT-PCR metode, sekvencioniran i upoređen sa sekvencama dostupnim u GenBank bazi podataka. Dobijen je PCR produkt očekivane veličine od 1017 bp. Sekvence izolata 137-08 (Acc. No. GQ259958) i 159-08 (GU144020) pokazale su 94-99% nukleotidne identičnosti sa izolatima WMV iz drugih delova sveta. Sekvence ova dva izolata razlikovala su se jedna od druge samo u dva nukleotidna mesta što nije imalo za posledicu aminokiselinske supstitucije. Filogenetske analize 57 izolata, na osnovu 750 bp sekvence gena za protein omotača, nisu ukazale na korelaciju sa geografskim poreklom izolata, a pokazala su grupisanje izolata u tri molekularne grupe sojeva. Izolati WMV iz Srbije pripadaju grupi I, grupi koja obuhvata najrasprostranjenije izolate ovog virusa u svetu.",
publisher = "Institute of Pesticides and Environmental Protection, Belgrade & Plant Protection Society of Serbia, Belgrade",
journal = "Pesticides and Phytomedicine/Pesticidi i fitomedicina",
title = "Frequency and molecular characterization of watermelon mosaic virus from Serbia",
pages = "230-213",
number = "3",
volume = "25",
doi = "10.2298/PIF1003213V"
}

Vučurović, A., Bulajić, A., Stanković, I., Ristić, D., Berenji, J.,& Krstić, B.. (2010). Frequency and molecular characterization of watermelon mosaic virus from Serbia. in Pesticides and Phytomedicine/Pesticidi i fitomedicina
Institute of Pesticides and Environmental Protection, Belgrade & Plant Protection Society of Serbia, Belgrade., 25(3), 213-230.
https://doi.org/10.2298/PIF1003213V

Vučurović A, Bulajić A, Stanković I, Ristić D, Berenji J, Krstić B. Frequency and molecular characterization of watermelon mosaic virus from Serbia. in Pesticides and Phytomedicine/Pesticidi i fitomedicina. 2010;25(3):213-230.
doi:10.2298/PIF1003213V .

Vučurović, Ana, Bulajić, Aleksandra, Stanković, Ivana, Ristić, Danijela, Berenji, Janoš, Krstić, Branka, "Frequency and molecular characterization of watermelon mosaic virus from Serbia" in Pesticides and Phytomedicine/Pesticidi i fitomedicina, 25, no. 3 (2010):213-230,
https://doi.org/10.2298/PIF1003213V . .