TY  - JOUR
AU  - Tomić, Andrija
AU  - Trkulja, Vojislav
AU  - Matić, Slavica
AU  - Trkulja, Nenad
AU  - Iličić, Renata
AU  - Scortichini, Marco
AU  - Popović Milovanović, Tatjana
PY  - 2024
UR  - https://enauka.gov.rs/handle/123456789/897621
UR  - https://plantarum.izbis.bg.ac.rs/handle/123456789/1233
AB  - Pyrenophora teres is a pathogen causing a net blotch disease in cultivated barley, which is present worldwide
and can thus significantly reduce barley yields. This fungus also infects wild barley and other plants of the Hordeum
genus, as well as barley grass, wheat, oats and plants from various genera, including Agropyron, Bromus, Elymus, Hordelymus and Stipa. Based on the symptoms it causes on the infected barley plants, the pathogen can be divided into two
forms: P. teres f. teres, which causes net-like symptoms, and P. teres f. maculata, which causes blotchy symptoms. Infected seeds, stubble and plant debris, and volunteer and weed plants represent primary sources of pathogen inoculum.
During the growing season, the pathogen enters a sexual stage, developing pseudothecia with asci and ascospores. This
is followed by an asexual stage, during which conidiophores with conidia are formed. The conidial (anamorphic) stage is
much more common, whereby conidia is a source of inoculum for secondary infection during the barley growing season.
The first symptoms appear at the end of winter and the beginning of spring, often during the tilling phase. The most
characteristic symptoms form on barley leaves. Frequently, symptoms of the net form can be mistaken for other diseases
occurring on barley, making molecular analysis essential for accurate detection of P. teres, its forms, mating types and
hybrids. Current net blotch control measures are based on the combined application of cultural, chemical and biological
control methods and the selection of resistant varieties.
PB  - Czech Academy of Agricultural Sciences
T2  - Plant Protection Science
T1  - Net blotch (Pyrenophora teres Drechsler): An increasingly significant threat to barley production
EP  - 30
IS  - 1
SP  - 1
VL  - 60
DO  - 10.17221/122/2023-PPS
ER  - 

@article{
author = "Tomić, Andrija and Trkulja, Vojislav and Matić, Slavica and Trkulja, Nenad and Iličić, Renata and Scortichini, Marco and Popović Milovanović, Tatjana",
year = "2024",
abstract = "Pyrenophora teres is a pathogen causing a net blotch disease in cultivated barley, which is present worldwide
and can thus significantly reduce barley yields. This fungus also infects wild barley and other plants of the Hordeum
genus, as well as barley grass, wheat, oats and plants from various genera, including Agropyron, Bromus, Elymus, Hordelymus and Stipa. Based on the symptoms it causes on the infected barley plants, the pathogen can be divided into two
forms: P. teres f. teres, which causes net-like symptoms, and P. teres f. maculata, which causes blotchy symptoms. Infected seeds, stubble and plant debris, and volunteer and weed plants represent primary sources of pathogen inoculum.
During the growing season, the pathogen enters a sexual stage, developing pseudothecia with asci and ascospores. This
is followed by an asexual stage, during which conidiophores with conidia are formed. The conidial (anamorphic) stage is
much more common, whereby conidia is a source of inoculum for secondary infection during the barley growing season.
The first symptoms appear at the end of winter and the beginning of spring, often during the tilling phase. The most
characteristic symptoms form on barley leaves. Frequently, symptoms of the net form can be mistaken for other diseases
occurring on barley, making molecular analysis essential for accurate detection of P. teres, its forms, mating types and
hybrids. Current net blotch control measures are based on the combined application of cultural, chemical and biological
control methods and the selection of resistant varieties.",
publisher = "Czech Academy of Agricultural Sciences",
journal = "Plant Protection Science",
title = "Net blotch (Pyrenophora teres Drechsler): An increasingly significant threat to barley production",
pages = "30-1",
number = "1",
volume = "60",
doi = "10.17221/122/2023-PPS"
}

Tomić, A., Trkulja, V., Matić, S., Trkulja, N., Iličić, R., Scortichini, M.,& Popović Milovanović, T.. (2024). Net blotch (Pyrenophora teres Drechsler): An increasingly significant threat to barley production. in Plant Protection Science
Czech Academy of Agricultural Sciences., 60(1), 1-30.
https://doi.org/10.17221/122/2023-PPS

Tomić A, Trkulja V, Matić S, Trkulja N, Iličić R, Scortichini M, Popović Milovanović T. Net blotch (Pyrenophora teres Drechsler): An increasingly significant threat to barley production. in Plant Protection Science. 2024;60(1):1-30.
doi:10.17221/122/2023-PPS .

Tomić, Andrija, Trkulja, Vojislav, Matić, Slavica, Trkulja, Nenad, Iličić, Renata, Scortichini, Marco, Popović Milovanović, Tatjana, "Net blotch (Pyrenophora teres Drechsler): An increasingly significant threat to barley production" in Plant Protection Science, 60, no. 1 (2024):1-30,
https://doi.org/10.17221/122/2023-PPS . .

TY  - CHAP
AU  - Trkulja, Vojislav
AU  - Tomić, Andrija
AU  - Popović Milovanović, Tatjana
AU  - Iličić, Renata
PY  - 2023
UR  - https://plantarum.izbis.bg.ac.rs/handle/123456789/1212
AB  - Uticaji klimatskih promjena na štetne organizme su složeni iz razloga što i drugi faktori koji utiču na njih nisu konstantni već se mijenjaju. I pored toga, klimatske promjene mogu na slične ili različite načine uticati na razne prouzrokovače biljnih bolesti i štetočine, u zavisnosti kojoj grupi organizama oni pripadaju: gljivama, bakterijama, virusima, insektima, nematodama i slično. Кod fitopatogenih gljiva ovi uticaji mogu se ispoljiti u pogledu: promjene biologije; brže evolucije zbog dužeg godišnjeg doba; pojave novih rasa ili veće agresivnosti postojećih vrsta zbog rekombinacije gena; mijenjanja geografske rasprostranjenosti, bilo prema sjevernoj hemisferi ili na područja sa višom nadmorskom visinom; introdukcije karantinskih i invazivnih vrsta, kao i širenja u nova područja u odnosu na područje porijekla; veću produkciju mikotoksina i dr. Za viruse i bakterije koji se prenose vektorima od posebnog značaja je uticaj klimatskih promjena na prisustvo, širenje i brojnost vektora.
Pozitivan uticaj klimatskih promjena na različite štetočine biljaka može se ispoljiti u vidu: promjene biologije i pojave većeg broja generacija; povećane brojnosti i plodnosti; boljeg prezimljavanja; proširenog kruga domaćina; introdukcije karantinskih i invazivnih vrsta; širenja u nova područja i drugo. Pozitivni uticaji klimatskih promjena na štetne organizme najčešće su sa negativnim efektom na razvoj poljoprivrede i proizvodnju hrane, razvoj šumarstva, biodiverzitet i životnu sredinu – zbog mogućnosti nastanka većih ekonomskih šteta, kao i većih potreba za primjenom pesticida. Кlimatske promjene, takođe, mogu uticati i na biljke domaćine, pri čemu je od posebnog značaja njihov gubitak prirodne osnove otpornosti.
Iako je došlo do napretka u praćenju i razumijevanju klimatskih promjena, ostaju potrebe za mnogim naučnim, tehničkim i institucionalnim rješenjima za precizno planiranje, prilagođavanje i ublažavanje efekata klimatskih promjena na prouzrokovače biljnih bolesti i štetočine, kao i biljke domaćine i njihove interakcije.
PB  - Akademija nauka i umjetnosti Republike Srpske, Banja Luka
T2  - Trbić G., Popov T., Mirjanić D. Upravljanje prirodnim resursima u eri klimatskih promjena
T1  - Uticaj klimatskih promjena na pojavu bolesti štetočina poljoprivrednih biljaka i šumskog drveća
EP  - 517
SP  - 477
DO  - 10,7251/EORU2308477T
ER  - 

@inbook{
author = "Trkulja, Vojislav and Tomić, Andrija and Popović Milovanović, Tatjana and Iličić, Renata",
year = "2023",
abstract = "Uticaji klimatskih promjena na štetne organizme su složeni iz razloga što i drugi faktori koji utiču na njih nisu konstantni već se mijenjaju. I pored toga, klimatske promjene mogu na slične ili različite načine uticati na razne prouzrokovače biljnih bolesti i štetočine, u zavisnosti kojoj grupi organizama oni pripadaju: gljivama, bakterijama, virusima, insektima, nematodama i slično. Кod fitopatogenih gljiva ovi uticaji mogu se ispoljiti u pogledu: promjene biologije; brže evolucije zbog dužeg godišnjeg doba; pojave novih rasa ili veće agresivnosti postojećih vrsta zbog rekombinacije gena; mijenjanja geografske rasprostranjenosti, bilo prema sjevernoj hemisferi ili na područja sa višom nadmorskom visinom; introdukcije karantinskih i invazivnih vrsta, kao i širenja u nova područja u odnosu na područje porijekla; veću produkciju mikotoksina i dr. Za viruse i bakterije koji se prenose vektorima od posebnog značaja je uticaj klimatskih promjena na prisustvo, širenje i brojnost vektora.
Pozitivan uticaj klimatskih promjena na različite štetočine biljaka može se ispoljiti u vidu: promjene biologije i pojave većeg broja generacija; povećane brojnosti i plodnosti; boljeg prezimljavanja; proširenog kruga domaćina; introdukcije karantinskih i invazivnih vrsta; širenja u nova područja i drugo. Pozitivni uticaji klimatskih promjena na štetne organizme najčešće su sa negativnim efektom na razvoj poljoprivrede i proizvodnju hrane, razvoj šumarstva, biodiverzitet i životnu sredinu – zbog mogućnosti nastanka većih ekonomskih šteta, kao i većih potreba za primjenom pesticida. Кlimatske promjene, takođe, mogu uticati i na biljke domaćine, pri čemu je od posebnog značaja njihov gubitak prirodne osnove otpornosti.
Iako je došlo do napretka u praćenju i razumijevanju klimatskih promjena, ostaju potrebe za mnogim naučnim, tehničkim i institucionalnim rješenjima za precizno planiranje, prilagođavanje i ublažavanje efekata klimatskih promjena na prouzrokovače biljnih bolesti i štetočine, kao i biljke domaćine i njihove interakcije.",
publisher = "Akademija nauka i umjetnosti Republike Srpske, Banja Luka",
journal = "Trbić G., Popov T., Mirjanić D. Upravljanje prirodnim resursima u eri klimatskih promjena",
booktitle = "Uticaj klimatskih promjena na pojavu bolesti štetočina poljoprivrednih biljaka i šumskog drveća",
pages = "517-477",
doi = "10,7251/EORU2308477T"
}

Trkulja, V., Tomić, A., Popović Milovanović, T.,& Iličić, R.. (2023). Uticaj klimatskih promjena na pojavu bolesti štetočina poljoprivrednih biljaka i šumskog drveća. in Trbić G., Popov T., Mirjanić D. Upravljanje prirodnim resursima u eri klimatskih promjena
Akademija nauka i umjetnosti Republike Srpske, Banja Luka., 477-517.
https://doi.org/10,7251/EORU2308477T

Trkulja V, Tomić A, Popović Milovanović T, Iličić R. Uticaj klimatskih promjena na pojavu bolesti štetočina poljoprivrednih biljaka i šumskog drveća. in Trbić G., Popov T., Mirjanić D. Upravljanje prirodnim resursima u eri klimatskih promjena. 2023;:477-517.
doi:10,7251/EORU2308477T .

Trkulja, Vojislav, Tomić, Andrija, Popović Milovanović, Tatjana, Iličić, Renata, "Uticaj klimatskih promjena na pojavu bolesti štetočina poljoprivrednih biljaka i šumskog drveća" in Trbić G., Popov T., Mirjanić D. Upravljanje prirodnim resursima u eri klimatskih promjena (2023):477-517,
https://doi.org/10,7251/EORU2308477T . .

TY  - JOUR
AU  - Trkulja, Vojislav
AU  - Tomić, Andrija
AU  - Matić, Slavica
AU  - Trkulja, Nenad
AU  - Iličić, Renata
AU  - Popović Milovanović, Tatjana
PY  - 2023
UR  - https://plantarum.izbis.bg.ac.rs/handle/123456789/857
AB  - In this paper, a comprehensive overview of the ‘Candidatus Liberibacter solanacearum’ presence in Europe was provided. The analyzed findings revealed that, since the first appearance of this pathogen in Finland and Spain in 2008, it has spread to 13 new European countries. Therefore, ‘Ca. L. solanacearum’ has spread very quickly across the European continent, as evident from the emergence of new host plants within the Apiaceae, Urticaceae, and Polygonaceae families, as well as new haplotypes of this pathogen. Thus far, 5 of the 15 ‘Ca. L. solanacearum’ haplotypes determined across the globe have been confirmed in Europe (haplotypes C, D, E, U, and H). Fully competent ‘Ca. L. solanacearum’ vectors include Bactericera cockerelli, Trioza apicalis, and B. trigonica; however, only T. apicalis and B. trigonica are presently established in Europe and are very important for plants from the Apiaceae family in particular. Moreover, psyllid species such as B. tremblayi, T. urticae, and T. anthrisci have also been confirmed positive for ‘Ca. L. solanacearum’. Constant monitoring of its spread in the field (in both symptomatic and asymptomatic plants), use of sensitive molecular diagnostic techniques, and application of timely management strategies are, therefore, of utmost importance for the control of this destructive pathogen.
PB  - MDPI
T2  - Microorganisms
T1  - An Overview of the Emergence of Plant Pathogen ‘Candidatus Liberibacter solanacearum’ in Europe
SP  - 1699
VL  - 11
DO  - 10.3390/microorganisms11071699
ER  - 

@article{
author = "Trkulja, Vojislav and Tomić, Andrija and Matić, Slavica and Trkulja, Nenad and Iličić, Renata and Popović Milovanović, Tatjana",
year = "2023",
abstract = "In this paper, a comprehensive overview of the ‘Candidatus Liberibacter solanacearum’ presence in Europe was provided. The analyzed findings revealed that, since the first appearance of this pathogen in Finland and Spain in 2008, it has spread to 13 new European countries. Therefore, ‘Ca. L. solanacearum’ has spread very quickly across the European continent, as evident from the emergence of new host plants within the Apiaceae, Urticaceae, and Polygonaceae families, as well as new haplotypes of this pathogen. Thus far, 5 of the 15 ‘Ca. L. solanacearum’ haplotypes determined across the globe have been confirmed in Europe (haplotypes C, D, E, U, and H). Fully competent ‘Ca. L. solanacearum’ vectors include Bactericera cockerelli, Trioza apicalis, and B. trigonica; however, only T. apicalis and B. trigonica are presently established in Europe and are very important for plants from the Apiaceae family in particular. Moreover, psyllid species such as B. tremblayi, T. urticae, and T. anthrisci have also been confirmed positive for ‘Ca. L. solanacearum’. Constant monitoring of its spread in the field (in both symptomatic and asymptomatic plants), use of sensitive molecular diagnostic techniques, and application of timely management strategies are, therefore, of utmost importance for the control of this destructive pathogen.",
publisher = "MDPI",
journal = "Microorganisms",
title = "An Overview of the Emergence of Plant Pathogen ‘Candidatus Liberibacter solanacearum’ in Europe",
pages = "1699",
volume = "11",
doi = "10.3390/microorganisms11071699"
}

Trkulja, V., Tomić, A., Matić, S., Trkulja, N., Iličić, R.,& Popović Milovanović, T.. (2023). An Overview of the Emergence of Plant Pathogen ‘Candidatus Liberibacter solanacearum’ in Europe. in Microorganisms
MDPI., 11, 1699.
https://doi.org/10.3390/microorganisms11071699

Trkulja V, Tomić A, Matić S, Trkulja N, Iličić R, Popović Milovanović T. An Overview of the Emergence of Plant Pathogen ‘Candidatus Liberibacter solanacearum’ in Europe. in Microorganisms. 2023;11:1699.
doi:10.3390/microorganisms11071699 .

Trkulja, Vojislav, Tomić, Andrija, Matić, Slavica, Trkulja, Nenad, Iličić, Renata, Popović Milovanović, Tatjana, "An Overview of the Emergence of Plant Pathogen ‘Candidatus Liberibacter solanacearum’ in Europe" in Microorganisms, 11 (2023):1699,
https://doi.org/10.3390/microorganisms11071699 . .

TY  - JOUR
AU  - Trkulja, Vojislav
AU  - Tomić, Andrija
AU  - Iličić, Renata
AU  - Nožinić, Miloš
AU  - Popović Milovanović, Tatjana
PY  - 2022
UR  - https://plantarum.izbis.bg.ac.rs/handle/123456789/855
AB  - Xylella fastidiosa is xylem-limited bacterium capable of infecting a wide range of host plants, resulting in Pierce’s disease in grapevine, citrus variegated chlorosis, olive quick decline syndrome, peach phony disease, plum leaf scald, alfalfa dwarf, margin necrosis and leaf scorch affecting oleander, coffee, almond, pecan, mulberry, red maple, oak, and other types of cultivated and ornamental plants and forest trees. In the European Union, X. fastidiosa is listed as a quarantine organism. Since its first outbreak in the Apulia region of southern Italy in 2013 where it caused devastating disease on Olea europaea (called olive leaf scorch and quick decline), X. fastidiosa continued to spread and successfully established in some European countries (Corsica and PACA in France, Balearic Islands, Madrid and Comunitat Valenciana in Spain, and Porto in Portugal). The most recent data for Europe indicates that X. fastidiosa is present on 174 hosts, 25 of which were newly identified in 2021 (with further five hosts discovered in other parts of the world in the same year). From the six reported subspecies of X. fastidiosa worldwide, four have been recorded in European countries (fastidiosa, multiplex, pauca, and sandyi). Currently confirmed X. fastidiosa vector species are Philaenus spumarius, Neophilaenus campestris, and Philaenus italosignus, whereby only P. spumarius (which has been identified as the key vector in Apulia, Italy) is also present in Americas. X. fastidiosa control is currently based on pathogen-free propagation plant material, eradication, territory demarcation, and vector control, as well as use of resistant plant cultivars and bactericidal treatments.
PB  - The Korean Society of Plant Pathology
T2  - The Plant Pathology Journal
T1  - Xylella fastidiosa in Europe: From the Introduction to the Current Status
EP  - 571
IS  - 6
SP  - 551
VL  - 38
DO  - 10.5423/PPJ.RW.09.2022.0127
ER  - 

@article{
author = "Trkulja, Vojislav and Tomić, Andrija and Iličić, Renata and Nožinić, Miloš and Popović Milovanović, Tatjana",
year = "2022",
abstract = "Xylella fastidiosa is xylem-limited bacterium capable of infecting a wide range of host plants, resulting in Pierce’s disease in grapevine, citrus variegated chlorosis, olive quick decline syndrome, peach phony disease, plum leaf scald, alfalfa dwarf, margin necrosis and leaf scorch affecting oleander, coffee, almond, pecan, mulberry, red maple, oak, and other types of cultivated and ornamental plants and forest trees. In the European Union, X. fastidiosa is listed as a quarantine organism. Since its first outbreak in the Apulia region of southern Italy in 2013 where it caused devastating disease on Olea europaea (called olive leaf scorch and quick decline), X. fastidiosa continued to spread and successfully established in some European countries (Corsica and PACA in France, Balearic Islands, Madrid and Comunitat Valenciana in Spain, and Porto in Portugal). The most recent data for Europe indicates that X. fastidiosa is present on 174 hosts, 25 of which were newly identified in 2021 (with further five hosts discovered in other parts of the world in the same year). From the six reported subspecies of X. fastidiosa worldwide, four have been recorded in European countries (fastidiosa, multiplex, pauca, and sandyi). Currently confirmed X. fastidiosa vector species are Philaenus spumarius, Neophilaenus campestris, and Philaenus italosignus, whereby only P. spumarius (which has been identified as the key vector in Apulia, Italy) is also present in Americas. X. fastidiosa control is currently based on pathogen-free propagation plant material, eradication, territory demarcation, and vector control, as well as use of resistant plant cultivars and bactericidal treatments.",
publisher = "The Korean Society of Plant Pathology",
journal = "The Plant Pathology Journal",
title = "Xylella fastidiosa in Europe: From the Introduction to the Current Status",
pages = "571-551",
number = "6",
volume = "38",
doi = "10.5423/PPJ.RW.09.2022.0127"
}

Trkulja, V., Tomić, A., Iličić, R., Nožinić, M.,& Popović Milovanović, T.. (2022). Xylella fastidiosa in Europe: From the Introduction to the Current Status. in The Plant Pathology Journal
The Korean Society of Plant Pathology., 38(6), 551-571.
https://doi.org/10.5423/PPJ.RW.09.2022.0127

Trkulja V, Tomić A, Iličić R, Nožinić M, Popović Milovanović T. Xylella fastidiosa in Europe: From the Introduction to the Current Status. in The Plant Pathology Journal. 2022;38(6):551-571.
doi:10.5423/PPJ.RW.09.2022.0127 .

Trkulja, Vojislav, Tomić, Andrija, Iličić, Renata, Nožinić, Miloš, Popović Milovanović, Tatjana, "Xylella fastidiosa in Europe: From the Introduction to the Current Status" in The Plant Pathology Journal, 38, no. 6 (2022):551-571,
https://doi.org/10.5423/PPJ.RW.09.2022.0127 . .