TY  - JOUR
AU  - Davidović, Slobodan
AU  - Marinković, Saša
AU  - Kukobat, Mila
AU  - Mihajlović, Milica
AU  - Tanasić, Vanja
AU  - Hribšek, Irena
AU  - Tanasković, Marija
AU  - Stamenković-Radak, Marina
PY  - 2022
UR  - http://radar.ibiss.bg.ac.rs/handle/123456789/4751
AB  - Once a widespread and common species across the region of southeast Europe, the Griffon vulture is now confined to small and isolated populations across the Balkan Peninsula. The population from Serbia with 290 couples represents its biggest and most viable population that can serve as an important reservoir of genetic diversity from which the birds can be used for the region’s reintroduction or recolonization programs. To estimate the level of genetic diversity, the mitochondrial Cytb gene from 58 unrelated birds sampled during the marking in the nests was sequenced and compared to the homologous Griffon vulture sequences available in publicly accessible online databases. Phylogeographic analysis based on Cytb sequences showed that the most frequent haplotype is found in all Griffon vulture populations and that each population possesses private haplotypes. Our data suggest that the Griffon vulture population from Serbia should be used as a source population for restocking and reintroduction programs in the region. The observed genetic differentiation between the populations from the Iberian and Balkan Peninsulas suggest that the introduction of foreign birds from remote populations should be avoided and that birds from indigenous or neighboring populations, if available, should be used instead.
PB  - Basel: MDPI
T2  - Life
T1  - Genetic Diversity Analysis of Mitochondrial Cytb Gene, Phylogeny and Phylogeography of Protected Griffon Vulture (Gyps fulvus) from Serbia
IS  - 2
VL  - 12
DO  - 10.3390/life12020164
SP  - 164
ER  - 

@article{
author = "Davidović, Slobodan and Marinković, Saša and Kukobat, Mila and Mihajlović, Milica and Tanasić, Vanja and Hribšek, Irena and Tanasković, Marija and Stamenković-Radak, Marina",
year = "2022",
abstract = "Once a widespread and common species across the region of southeast Europe, the Griffon vulture is now confined to small and isolated populations across the Balkan Peninsula. The population from Serbia with 290 couples represents its biggest and most viable population that can serve as an important reservoir of genetic diversity from which the birds can be used for the region’s reintroduction or recolonization programs. To estimate the level of genetic diversity, the mitochondrial Cytb gene from 58 unrelated birds sampled during the marking in the nests was sequenced and compared to the homologous Griffon vulture sequences available in publicly accessible online databases. Phylogeographic analysis based on Cytb sequences showed that the most frequent haplotype is found in all Griffon vulture populations and that each population possesses private haplotypes. Our data suggest that the Griffon vulture population from Serbia should be used as a source population for restocking and reintroduction programs in the region. The observed genetic differentiation between the populations from the Iberian and Balkan Peninsulas suggest that the introduction of foreign birds from remote populations should be avoided and that birds from indigenous or neighboring populations, if available, should be used instead.",
publisher = "Basel: MDPI",
journal = "Life",
title = "Genetic Diversity Analysis of Mitochondrial Cytb Gene, Phylogeny and Phylogeography of Protected Griffon Vulture (Gyps fulvus) from Serbia",
number = "2",
volume = "12",
doi = "10.3390/life12020164",
pages = "164"
}

Davidović, S., Marinković, S., Kukobat, M., Mihajlović, M., Tanasić, V., Hribšek, I., Tanasković, M.,& Stamenković-Radak, M.. (2022). Genetic Diversity Analysis of Mitochondrial Cytb Gene, Phylogeny and Phylogeography of Protected Griffon Vulture (Gyps fulvus) from Serbia. in Life
Basel: MDPI., 12(2), 164.
https://doi.org/10.3390/life12020164

Davidović S, Marinković S, Kukobat M, Mihajlović M, Tanasić V, Hribšek I, Tanasković M, Stamenković-Radak M. Genetic Diversity Analysis of Mitochondrial Cytb Gene, Phylogeny and Phylogeography of Protected Griffon Vulture (Gyps fulvus) from Serbia. in Life. 2022;12(2):164.
doi:10.3390/life12020164 .

Davidović, Slobodan, Marinković, Saša, Kukobat, Mila, Mihajlović, Milica, Tanasić, Vanja, Hribšek, Irena, Tanasković, Marija, Stamenković-Radak, Marina, "Genetic Diversity Analysis of Mitochondrial Cytb Gene, Phylogeny and Phylogeography of Protected Griffon Vulture (Gyps fulvus) from Serbia" in Life, 12, no. 2 (2022):164,
https://doi.org/10.3390/life12020164 . .

TY  - JOUR
AU  - Tanasković, Marija
AU  - Erić, Pavle
AU  - Patenković, Aleksandra
AU  - Erić, Katarina
AU  - Mihajlović, Milica
AU  - Tanasić, Vanja
AU  - Kusza, Szilvia
AU  - Oleksa, Andrzej
AU  - Stanisavljević, Ljubiša
AU  - Davidović, Slobodan
PY  - 2022
UR  - http://radar.ibiss.bg.ac.rs/handle/123456789/4806
AB  - Socioeconomic interests and beekeeper preferences have often taken precedence over the conservation of locally native honey bee subspecies, leading to the predominance of admixture populations in human-dominated areas. To assess the genetic diversity of contemporary managed Serbian honey bee colonies, we used 14 microsatellite loci and analyzed 237 worker bees from 46 apiaries in eight localities of northern and southern Serbia. Furthermore, we compared data for nine microsatellite loci with 338 individuals from Italy, Hungary, Poland, and Spain. The standard parameters of genetic diversity in Serbian honey bee populations were in line with other analyses, although somewhat smaller. STRUCTURE analysis showed the existence of two equally distributed genetic clusters and Analysis of molecular variances could not confirm the presence of a geographically discrete population but showed local differences. Discriminant analysis of principal components showed overlapping of worker bees from different parts of Serbia. Clear genetic differentiation can be observed when comparing all populations between geographical regions and their corresponding subspecies. The absence of the A. m. macedonica subspecies from its historical distribution range in southern Serbia as well as the lack of distinctive geographical groups suggest that selective breeding, queen import, and migratory beekeeping practices strongly influence the genetic structure and diversity of honey bees, leading to the genetic uniformization and creation of the admixture population.
PB  - Basel: MDPI
T2  - Insects
T1  - Further Evidence of Population Admixture in the Serbian Honey Bee Population
IS  - 2
VL  - 13
DO  - 10.3390/insects13020180
SP  - 180
ER  - 

@article{
author = "Tanasković, Marija and Erić, Pavle and Patenković, Aleksandra and Erić, Katarina and Mihajlović, Milica and Tanasić, Vanja and Kusza, Szilvia and Oleksa, Andrzej and Stanisavljević, Ljubiša and Davidović, Slobodan",
year = "2022",
abstract = "Socioeconomic interests and beekeeper preferences have often taken precedence over the conservation of locally native honey bee subspecies, leading to the predominance of admixture populations in human-dominated areas. To assess the genetic diversity of contemporary managed Serbian honey bee colonies, we used 14 microsatellite loci and analyzed 237 worker bees from 46 apiaries in eight localities of northern and southern Serbia. Furthermore, we compared data for nine microsatellite loci with 338 individuals from Italy, Hungary, Poland, and Spain. The standard parameters of genetic diversity in Serbian honey bee populations were in line with other analyses, although somewhat smaller. STRUCTURE analysis showed the existence of two equally distributed genetic clusters and Analysis of molecular variances could not confirm the presence of a geographically discrete population but showed local differences. Discriminant analysis of principal components showed overlapping of worker bees from different parts of Serbia. Clear genetic differentiation can be observed when comparing all populations between geographical regions and their corresponding subspecies. The absence of the A. m. macedonica subspecies from its historical distribution range in southern Serbia as well as the lack of distinctive geographical groups suggest that selective breeding, queen import, and migratory beekeeping practices strongly influence the genetic structure and diversity of honey bees, leading to the genetic uniformization and creation of the admixture population.",
publisher = "Basel: MDPI",
journal = "Insects",
title = "Further Evidence of Population Admixture in the Serbian Honey Bee Population",
number = "2",
volume = "13",
doi = "10.3390/insects13020180",
pages = "180"
}

Tanasković, M., Erić, P., Patenković, A., Erić, K., Mihajlović, M., Tanasić, V., Kusza, S., Oleksa, A., Stanisavljević, L.,& Davidović, S.. (2022). Further Evidence of Population Admixture in the Serbian Honey Bee Population. in Insects
Basel: MDPI., 13(2), 180.
https://doi.org/10.3390/insects13020180

Tanasković M, Erić P, Patenković A, Erić K, Mihajlović M, Tanasić V, Kusza S, Oleksa A, Stanisavljević L, Davidović S. Further Evidence of Population Admixture in the Serbian Honey Bee Population. in Insects. 2022;13(2):180.
doi:10.3390/insects13020180 .

Tanasković, Marija, Erić, Pavle, Patenković, Aleksandra, Erić, Katarina, Mihajlović, Milica, Tanasić, Vanja, Kusza, Szilvia, Oleksa, Andrzej, Stanisavljević, Ljubiša, Davidović, Slobodan, "Further Evidence of Population Admixture in the Serbian Honey Bee Population" in Insects, 13, no. 2 (2022):180,
https://doi.org/10.3390/insects13020180 . .

TY  - DATA
AU  - Patenković, Aleksandra
AU  - Tanasković, Marija
AU  - Erić, Pavle
AU  - Erić, Katarina
AU  - Mihailović, Milica
AU  - Tanasić, Vanja
AU  - Stanisavljević, Ljubiša
AU  - Davidović, Slobodan
PY  - 2022
UR  - http://radar.ibiss.bg.ac.rs/handle/123456789/4954
AB  - Figure S5. 3D plot demonstrating genetic variability analyzed using DAPC method based on the data from 14 microsatellite loci (A7, A8, A14, A24, A28, A35, A43, A79, A88, A107, A113, Ap43, Ap249 and B124) for managed honey bees (Apis mellifera) colonies originating from stationary apiaries from the North (Fruška gora, Deliblatska peščara, Vršac, Subotica), South (Leskovac, Tromeđa, Vlasina, Stara planina) parts of Serbia including the Belgrade and for the feral honey bees that were found on different locations in Belgrade. In figure S5 the first three principal components (PC) are presented.
T1  - Supplementary Material "Urban ecosystem drives genetic diversity in feral honey bee"
UR  - https://hdl.handle.net/21.15107/rcub_ibiss_4954
ER  - 

@misc{
author = "Patenković, Aleksandra and Tanasković, Marija and Erić, Pavle and Erić, Katarina and Mihailović, Milica and Tanasić, Vanja and Stanisavljević, Ljubiša and Davidović, Slobodan",
year = "2022",
abstract = "Figure S5. 3D plot demonstrating genetic variability analyzed using DAPC method based on the data from 14 microsatellite loci (A7, A8, A14, A24, A28, A35, A43, A79, A88, A107, A113, Ap43, Ap249 and B124) for managed honey bees (Apis mellifera) colonies originating from stationary apiaries from the North (Fruška gora, Deliblatska peščara, Vršac, Subotica), South (Leskovac, Tromeđa, Vlasina, Stara planina) parts of Serbia including the Belgrade and for the feral honey bees that were found on different locations in Belgrade. In figure S5 the first three principal components (PC) are presented.",
title = "Supplementary Material "Urban ecosystem drives genetic diversity in feral honey bee"",
url = "https://hdl.handle.net/21.15107/rcub_ibiss_4954"
}

Patenković, A., Tanasković, M., Erić, P., Erić, K., Mihailović, M., Tanasić, V., Stanisavljević, L.,& Davidović, S.. (2022). Supplementary Material "Urban ecosystem drives genetic diversity in feral honey bee". .
https://hdl.handle.net/21.15107/rcub_ibiss_4954

Patenković A, Tanasković M, Erić P, Erić K, Mihailović M, Tanasić V, Stanisavljević L, Davidović S. Supplementary Material "Urban ecosystem drives genetic diversity in feral honey bee". 2022;.
https://hdl.handle.net/21.15107/rcub_ibiss_4954 .

Patenković, Aleksandra, Tanasković, Marija, Erić, Pavle, Erić, Katarina, Mihailović, Milica, Tanasić, Vanja, Stanisavljević, Ljubiša, Davidović, Slobodan, "Supplementary Material "Urban ecosystem drives genetic diversity in feral honey bee"" (2022),
https://hdl.handle.net/21.15107/rcub_ibiss_4954 .

TY  - DATA
AU  - Tanasković, Marija
AU  - Erić, Pavle
AU  - Patenković, Aleksandra
AU  - Erić, Katarina
AU  - Mihajlović, Milica
AU  - Tanasić, Vanja
AU  - Kusza, Szilvia
AU  - Oleksa, Andzrej
AU  - Stanisavljević, Ljubiša
AU  - Davidović, Slobodan
PY  - 2022
UR  - http://radar.ibiss.bg.ac.rs/handle/123456789/4779
AB  - Figure S1. 3D plot demonstrating genetic variability analyzed using DAPC method based on the data from 14 microsatellite loci (A7, A8, A14, A24, A28, A35, A43, A79, A88, A107, A113, Ap43, Ap249 and B124) for managed honey bees (Apis mellifera) colonies originating from stationary apiaries and 8 different localities from the North (Fruška gora, Deliblatska peščara, Vršac, Subotica) and South (Leskovac, Tromeđa, Vlasina, Stara planina) parts of Serbia. In figure S1 the first three principal components (PC) are presented.
Figure S7. 3D plot demonstrating genetic variability analyzed using DAPC method based on the data from 9 microsatellite loci (A7, A14, A24, A28, A35, A43, A88, A107 and A113) for managed honey bees (Apis mellifera) colonies originating from stationary apiaries and 8 different localities from the North (Fruška gora, Deliblatska peščara, Vršac, Subotica) and South (Leskovac, Tromeđa, Vlasina, Stara planina) parts of Serbia and four different European countries (Spain, Italy, Poland and Hungary). In this figure four different A. mellifera species are presented as well: A. m. iberica from Spain, A. m. ligustica from Italy, A. m. mellifera from Poland, A. m. carnica from Hungary, Poland and Serbia. In figure S7 the first three principal components (PC) are presented.
T2  - Insects
T1  - Supplementary material "Further evidence of population admixture in the Serbian honey bee population"
UR  - https://hdl.handle.net/21.15107/rcub_ibiss_4779
ER  - 

@misc{
author = "Tanasković, Marija and Erić, Pavle and Patenković, Aleksandra and Erić, Katarina and Mihajlović, Milica and Tanasić, Vanja and Kusza, Szilvia and Oleksa, Andzrej and Stanisavljević, Ljubiša and Davidović, Slobodan",
year = "2022",
abstract = "Figure S1. 3D plot demonstrating genetic variability analyzed using DAPC method based on the data from 14 microsatellite loci (A7, A8, A14, A24, A28, A35, A43, A79, A88, A107, A113, Ap43, Ap249 and B124) for managed honey bees (Apis mellifera) colonies originating from stationary apiaries and 8 different localities from the North (Fruška gora, Deliblatska peščara, Vršac, Subotica) and South (Leskovac, Tromeđa, Vlasina, Stara planina) parts of Serbia. In figure S1 the first three principal components (PC) are presented.
Figure S7. 3D plot demonstrating genetic variability analyzed using DAPC method based on the data from 9 microsatellite loci (A7, A14, A24, A28, A35, A43, A88, A107 and A113) for managed honey bees (Apis mellifera) colonies originating from stationary apiaries and 8 different localities from the North (Fruška gora, Deliblatska peščara, Vršac, Subotica) and South (Leskovac, Tromeđa, Vlasina, Stara planina) parts of Serbia and four different European countries (Spain, Italy, Poland and Hungary). In this figure four different A. mellifera species are presented as well: A. m. iberica from Spain, A. m. ligustica from Italy, A. m. mellifera from Poland, A. m. carnica from Hungary, Poland and Serbia. In figure S7 the first three principal components (PC) are presented.",
journal = "Insects",
title = "Supplementary material "Further evidence of population admixture in the Serbian honey bee population"",
url = "https://hdl.handle.net/21.15107/rcub_ibiss_4779"
}

Tanasković, M., Erić, P., Patenković, A., Erić, K., Mihajlović, M., Tanasić, V., Kusza, S., Oleksa, A., Stanisavljević, L.,& Davidović, S.. (2022). Supplementary material "Further evidence of population admixture in the Serbian honey bee population". in Insects.
https://hdl.handle.net/21.15107/rcub_ibiss_4779

Tanasković M, Erić P, Patenković A, Erić K, Mihajlović M, Tanasić V, Kusza S, Oleksa A, Stanisavljević L, Davidović S. Supplementary material "Further evidence of population admixture in the Serbian honey bee population". in Insects. 2022;.
https://hdl.handle.net/21.15107/rcub_ibiss_4779 .

Tanasković, Marija, Erić, Pavle, Patenković, Aleksandra, Erić, Katarina, Mihajlović, Milica, Tanasić, Vanja, Kusza, Szilvia, Oleksa, Andzrej, Stanisavljević, Ljubiša, Davidović, Slobodan, "Supplementary material "Further evidence of population admixture in the Serbian honey bee population"" in Insects (2022),
https://hdl.handle.net/21.15107/rcub_ibiss_4779 .

TY  - CONF
AU  - Davidović, Slobodan
AU  - Jelić, Mihailo
AU  - Marinković, Saša
AU  - Kukobat, Mila
AU  - Mihajlović, Milica
AU  - Tanasić, Vanja
AU  - Hribšek, Irena
AU  - Sušić, Goran
AU  - Dragićević, Milan
AU  - Tanasković, Marija
AU  - Stamenković-Radak, Marina
PY  - 2021
UR  - https://radar.ibiss.bg.ac.rs/handle/123456789/4254
AB  - Abstract
Once a widespread species across the region of Southeast Europe, the Griffon vulture is now confined to small and isolated populations across the Balkan Peninsula. The population from Serbia represents its biggest and most viable population that can serve as an important reservoir of genetic diversity from which the birds can be used for the region’s reintroduction programs. The available genetic data for this valuable population are scarce and it is necessary to assess its genetic diversity and inbreeding level if the population is going to be used for restocking and reintroduction.
To assess the genetic diversity we used microsatellite markers from ten loci and mitochondrial Cytb nucleotide sequences. The blood samples were collected from 58 unrelated birds during the marking in the nests. We have performed a comparative analysis of newly obtained data on microsatellites and Cytb with existing data. Genetic differentiation analysis between different native populations of French Pyrenees, Croatia and Israel identified two genetic clusters that differentiate populations from the Balkan and Iberian Peninsulas. Genetic diversity analysis based on microsatellites demonstrated similar levels among all populations while analysis of Cytb detected somewhat lower diversity in the population from Serbia. Further analyses demonstrated that all analyzed populations experienced a recent bottleneck event. Phylogeographic analysis based on Cytb sequences showed that the most frequent haplotype is found in all Griffon vulture populations and that each population possesses private haplotypes. Considering the serious recent bottleneck event which the population from Serbia experienced we estimated the overall relatedness among the birds from this population. The level of inbreeding was relatively high and on average it was 8,3% while the mean number of relatives for each bird was close to three.
Our data suggest that, even though a relatively high level of inbreeding can be detected among the individual birds, the Griffon vulture population from Serbia can be used as a source population for restocking and reintroduction programs in the region. The observed genetic differentiation between the populations from the Iberian and Balkan Peninsula suggest that the introduction of foreign birds should be avoided and that local birds should be used instead.
PB  - Novi Sad: Department of Biology and Ecology, Faculty of Sciences, University of Novi Sad
C3  - Belgrade BioInformatics Conference 2021: Book of Abstracts; 2021 Jun 21-25; Vinča, Serbia
T1  - Genetic diversity analysis of microsatellites and mitochondrial Cytb gene, relatedness estimates and Cytb phylogeography of protected Griffon vulture species from Serbia
IS  - 1
VL  - 43
SP  - 117
UR  - https://hdl.handle.net/21.15107/rcub_ibiss_4254
ER  - 

@conference{
author = "Davidović, Slobodan and Jelić, Mihailo and Marinković, Saša and Kukobat, Mila and Mihajlović, Milica and Tanasić, Vanja and Hribšek, Irena and Sušić, Goran and Dragićević, Milan and Tanasković, Marija and Stamenković-Radak, Marina",
year = "2021",
abstract = "Abstract
Once a widespread species across the region of Southeast Europe, the Griffon vulture is now confined to small and isolated populations across the Balkan Peninsula. The population from Serbia represents its biggest and most viable population that can serve as an important reservoir of genetic diversity from which the birds can be used for the region’s reintroduction programs. The available genetic data for this valuable population are scarce and it is necessary to assess its genetic diversity and inbreeding level if the population is going to be used for restocking and reintroduction.
To assess the genetic diversity we used microsatellite markers from ten loci and mitochondrial Cytb nucleotide sequences. The blood samples were collected from 58 unrelated birds during the marking in the nests. We have performed a comparative analysis of newly obtained data on microsatellites and Cytb with existing data. Genetic differentiation analysis between different native populations of French Pyrenees, Croatia and Israel identified two genetic clusters that differentiate populations from the Balkan and Iberian Peninsulas. Genetic diversity analysis based on microsatellites demonstrated similar levels among all populations while analysis of Cytb detected somewhat lower diversity in the population from Serbia. Further analyses demonstrated that all analyzed populations experienced a recent bottleneck event. Phylogeographic analysis based on Cytb sequences showed that the most frequent haplotype is found in all Griffon vulture populations and that each population possesses private haplotypes. Considering the serious recent bottleneck event which the population from Serbia experienced we estimated the overall relatedness among the birds from this population. The level of inbreeding was relatively high and on average it was 8,3% while the mean number of relatives for each bird was close to three.
Our data suggest that, even though a relatively high level of inbreeding can be detected among the individual birds, the Griffon vulture population from Serbia can be used as a source population for restocking and reintroduction programs in the region. The observed genetic differentiation between the populations from the Iberian and Balkan Peninsula suggest that the introduction of foreign birds should be avoided and that local birds should be used instead.",
publisher = "Novi Sad: Department of Biology and Ecology, Faculty of Sciences, University of Novi Sad",
journal = "Belgrade BioInformatics Conference 2021: Book of Abstracts; 2021 Jun 21-25; Vinča, Serbia",
title = "Genetic diversity analysis of microsatellites and mitochondrial Cytb gene, relatedness estimates and Cytb phylogeography of protected Griffon vulture species from Serbia",
number = "1",
volume = "43",
pages = "117",
url = "https://hdl.handle.net/21.15107/rcub_ibiss_4254"
}

Davidović, S., Jelić, M., Marinković, S., Kukobat, M., Mihajlović, M., Tanasić, V., Hribšek, I., Sušić, G., Dragićević, M., Tanasković, M.,& Stamenković-Radak, M.. (2021). Genetic diversity analysis of microsatellites and mitochondrial Cytb gene, relatedness estimates and Cytb phylogeography of protected Griffon vulture species from Serbia. in Belgrade BioInformatics Conference 2021: Book of Abstracts; 2021 Jun 21-25; Vinča, Serbia
Novi Sad: Department of Biology and Ecology, Faculty of Sciences, University of Novi Sad., 43(1), 117.
https://hdl.handle.net/21.15107/rcub_ibiss_4254

Davidović S, Jelić M, Marinković S, Kukobat M, Mihajlović M, Tanasić V, Hribšek I, Sušić G, Dragićević M, Tanasković M, Stamenković-Radak M. Genetic diversity analysis of microsatellites and mitochondrial Cytb gene, relatedness estimates and Cytb phylogeography of protected Griffon vulture species from Serbia. in Belgrade BioInformatics Conference 2021: Book of Abstracts; 2021 Jun 21-25; Vinča, Serbia. 2021;43(1):117.
https://hdl.handle.net/21.15107/rcub_ibiss_4254 .

Davidović, Slobodan, Jelić, Mihailo, Marinković, Saša, Kukobat, Mila, Mihajlović, Milica, Tanasić, Vanja, Hribšek, Irena, Sušić, Goran, Dragićević, Milan, Tanasković, Marija, Stamenković-Radak, Marina, "Genetic diversity analysis of microsatellites and mitochondrial Cytb gene, relatedness estimates and Cytb phylogeography of protected Griffon vulture species from Serbia" in Belgrade BioInformatics Conference 2021: Book of Abstracts; 2021 Jun 21-25; Vinča, Serbia, 43, no. 1 (2021):117,
https://hdl.handle.net/21.15107/rcub_ibiss_4254 .

TY  - JOUR
AU  - Tanasković, Marija
AU  - Erić, Pavle
AU  - Patenković, Aleksandra
AU  - Erić, Katarina
AU  - Mihajlović, Milica
AU  - Tanasić, Vanja
AU  - Stanisavljević, Ljubiša
AU  - Davidović, Slobodan
PY  - 2021
UR  - https://radar.ibiss.bg.ac.rs/handle/123456789/4429
AB  - Local populations of Apis mellifera are rapidly changing by modern beekeeping through the introduction of nonnative queens, selection and migratory beekeeping. To assess the genetic diversity of contemporary managed honey bees in Serbia, we sequenced mitochondrial tRNAleu-cox2 intergenic region of 241 worker bees from 46 apiaries at eight localities. Nine haplotypes were observed in our samples, with C2d being the most common and widespread. To evaluate genetic diversity patterns, we compared our data with 1696 sequences from the NCBI GenBank from neighbouring countries and Serbia. All 32 detected haplotypes belonged to the Southeast Europe lineage C, with two newly described haplotypes from our sample. The most frequent haplotype was C2d, followed by C2c and C1a. To distinguish A. m. carnica from A. m. macedonica, both previously reported in Serbia, PCR-RFLP analysis on the COI gene segment of mtDNA was used, and the result showed only the presence of A.m. carnica subspecies. An MDS plot constructed on pairwise Fst values showed significant geographical stratification. Our samples are grouped together, but distant from the Serbian dataset from the GenBank. This, with the absence of A. m. macedonica subspecies from its historic range of distribution in southern Serbia, indicates that honey bee populations are changing rapidly due to the anthropogenic influence.
PB  - Basel: MDPI
T2  - Insects
T1  - MtDNA Analysis Indicates Human-Induced Temporal Changes of Serbian Honey Bees Diversity
IS  - 9
VL  - 12
DO  - 10.3390/insects12090767
SP  - 767
ER  - 

@article{
author = "Tanasković, Marija and Erić, Pavle and Patenković, Aleksandra and Erić, Katarina and Mihajlović, Milica and Tanasić, Vanja and Stanisavljević, Ljubiša and Davidović, Slobodan",
year = "2021",
abstract = "Local populations of Apis mellifera are rapidly changing by modern beekeeping through the introduction of nonnative queens, selection and migratory beekeeping. To assess the genetic diversity of contemporary managed honey bees in Serbia, we sequenced mitochondrial tRNAleu-cox2 intergenic region of 241 worker bees from 46 apiaries at eight localities. Nine haplotypes were observed in our samples, with C2d being the most common and widespread. To evaluate genetic diversity patterns, we compared our data with 1696 sequences from the NCBI GenBank from neighbouring countries and Serbia. All 32 detected haplotypes belonged to the Southeast Europe lineage C, with two newly described haplotypes from our sample. The most frequent haplotype was C2d, followed by C2c and C1a. To distinguish A. m. carnica from A. m. macedonica, both previously reported in Serbia, PCR-RFLP analysis on the COI gene segment of mtDNA was used, and the result showed only the presence of A.m. carnica subspecies. An MDS plot constructed on pairwise Fst values showed significant geographical stratification. Our samples are grouped together, but distant from the Serbian dataset from the GenBank. This, with the absence of A. m. macedonica subspecies from its historic range of distribution in southern Serbia, indicates that honey bee populations are changing rapidly due to the anthropogenic influence.",
publisher = "Basel: MDPI",
journal = "Insects",
title = "MtDNA Analysis Indicates Human-Induced Temporal Changes of Serbian Honey Bees Diversity",
number = "9",
volume = "12",
doi = "10.3390/insects12090767",
pages = "767"
}

Tanasković, M., Erić, P., Patenković, A., Erić, K., Mihajlović, M., Tanasić, V., Stanisavljević, L.,& Davidović, S.. (2021). MtDNA Analysis Indicates Human-Induced Temporal Changes of Serbian Honey Bees Diversity. in Insects
Basel: MDPI., 12(9), 767.
https://doi.org/10.3390/insects12090767

Tanasković M, Erić P, Patenković A, Erić K, Mihajlović M, Tanasić V, Stanisavljević L, Davidović S. MtDNA Analysis Indicates Human-Induced Temporal Changes of Serbian Honey Bees Diversity. in Insects. 2021;12(9):767.
doi:10.3390/insects12090767 .

Tanasković, Marija, Erić, Pavle, Patenković, Aleksandra, Erić, Katarina, Mihajlović, Milica, Tanasić, Vanja, Stanisavljević, Ljubiša, Davidović, Slobodan, "MtDNA Analysis Indicates Human-Induced Temporal Changes of Serbian Honey Bees Diversity" in Insects, 12, no. 9 (2021):767,
https://doi.org/10.3390/insects12090767 . .

TY  - CONF
AU  - Erić, Pavle
AU  - Patenković, Aleksandra
AU  - Erić, Katarina
AU  - Tanasić, Vanja
AU  - Mihajlović, Milica
AU  - Tanasković, Marija
AU  - Stanisavljević, Ljubiša
AU  - Davidović, Slobodan
PY  - 2021
UR  - https://radar.ibiss.bg.ac.rs/handle/123456789/4253
AB  - Abstract
Local populations of Apis mellifera are rapidly changing, with the gene pool of autochthonous breeds being depleted by beekeepers through the import of foreign queens not adapted to the local environment. To study their genetic structure and phylogenetic relationships, we gathered a large dataset from the Balkans and surrounding countries.
Our sample consisted of 246 honeybee colonies collected from 47 apiaries and 24 feral colonies divided into four subpopulations from southern Serbia, five from Vojvodina, and two from Belgrade. To evaluate genetic diversity patterns, we sequenced the mitochondrial tRNAleu-cox2 intergenic region. We compared our data to other published data on A.mellifera COI-COII intergenic region variability in the Balkans and neighboring countries. We pulled 1512 sequences from the NCBI GenBank, originating from 15 different populations. The 1782 mitochondrial sequences were grouped into 31 haplotypes, with two newly described haplotypes from our sample. All haplotypes belonged to the eastern Mediterranean C lineage. The most frequent haplotype was C2d, characteristic for A.m.macedonica, followed by C2c and C1a characteristic for A.m.carnica and A.m.ligustica respectively. In our samples 9 haplotypes were observed, with the C2d being the most common and widespread as it was detected in all 11 groups, followed by C2e that was detected in all but one group. C2c and C1a were a little less common than in the total sample but very widespread as they were present in seven groups.
When the Macedonia, Ukraine, and Belgrade honeybee populations which consisted of a single haplotype, were excluded, the haplotype diversity ranged from 0.0998 to 0.7477, nucleotide diversity ranged from the lowest value of 0.000114 to 0.003731. The mean number of pairwise differences for populations that had more than one haplotype ranged from 0.060577 to 2. MDS plot constructed on pairwise FST values shows significant geographical stratification, with our subpopulations being grouped together. Vojvodina being placed closer to Romania and Hungary datasets, while southern Serbia is closer to Bulgaria and Montenegro. Interestingly, our samples are not closely grouped with the Serbian dataset from the GenBank which indicates that honeybee populations are changing rapidly.
PB  - Novi Sad: Department of Biology and Ecology, Faculty of Sciences, University of Novi Sad
C3  - Belgrade BioInformatics Conference 2021: Book of Abstracts; 2021 Jun 21-25; Vinča, Serbia
T1  - Large scale mitochondrial DNA analysis of European Honey bee (Apis mellifera) populations from the Balkans, population genetics and phylogeographic perspective
IS  - 1
VL  - 43
SP  - 116
UR  - https://hdl.handle.net/21.15107/rcub_ibiss_4253
ER  - 

@conference{
author = "Erić, Pavle and Patenković, Aleksandra and Erić, Katarina and Tanasić, Vanja and Mihajlović, Milica and Tanasković, Marija and Stanisavljević, Ljubiša and Davidović, Slobodan",
year = "2021",
abstract = "Abstract
Local populations of Apis mellifera are rapidly changing, with the gene pool of autochthonous breeds being depleted by beekeepers through the import of foreign queens not adapted to the local environment. To study their genetic structure and phylogenetic relationships, we gathered a large dataset from the Balkans and surrounding countries.
Our sample consisted of 246 honeybee colonies collected from 47 apiaries and 24 feral colonies divided into four subpopulations from southern Serbia, five from Vojvodina, and two from Belgrade. To evaluate genetic diversity patterns, we sequenced the mitochondrial tRNAleu-cox2 intergenic region. We compared our data to other published data on A.mellifera COI-COII intergenic region variability in the Balkans and neighboring countries. We pulled 1512 sequences from the NCBI GenBank, originating from 15 different populations. The 1782 mitochondrial sequences were grouped into 31 haplotypes, with two newly described haplotypes from our sample. All haplotypes belonged to the eastern Mediterranean C lineage. The most frequent haplotype was C2d, characteristic for A.m.macedonica, followed by C2c and C1a characteristic for A.m.carnica and A.m.ligustica respectively. In our samples 9 haplotypes were observed, with the C2d being the most common and widespread as it was detected in all 11 groups, followed by C2e that was detected in all but one group. C2c and C1a were a little less common than in the total sample but very widespread as they were present in seven groups.
When the Macedonia, Ukraine, and Belgrade honeybee populations which consisted of a single haplotype, were excluded, the haplotype diversity ranged from 0.0998 to 0.7477, nucleotide diversity ranged from the lowest value of 0.000114 to 0.003731. The mean number of pairwise differences for populations that had more than one haplotype ranged from 0.060577 to 2. MDS plot constructed on pairwise FST values shows significant geographical stratification, with our subpopulations being grouped together. Vojvodina being placed closer to Romania and Hungary datasets, while southern Serbia is closer to Bulgaria and Montenegro. Interestingly, our samples are not closely grouped with the Serbian dataset from the GenBank which indicates that honeybee populations are changing rapidly.",
publisher = "Novi Sad: Department of Biology and Ecology, Faculty of Sciences, University of Novi Sad",
journal = "Belgrade BioInformatics Conference 2021: Book of Abstracts; 2021 Jun 21-25; Vinča, Serbia",
title = "Large scale mitochondrial DNA analysis of European Honey bee (Apis mellifera) populations from the Balkans, population genetics and phylogeographic perspective",
number = "1",
volume = "43",
pages = "116",
url = "https://hdl.handle.net/21.15107/rcub_ibiss_4253"
}

Erić, P., Patenković, A., Erić, K., Tanasić, V., Mihajlović, M., Tanasković, M., Stanisavljević, L.,& Davidović, S.. (2021). Large scale mitochondrial DNA analysis of European Honey bee (Apis mellifera) populations from the Balkans, population genetics and phylogeographic perspective. in Belgrade BioInformatics Conference 2021: Book of Abstracts; 2021 Jun 21-25; Vinča, Serbia
Novi Sad: Department of Biology and Ecology, Faculty of Sciences, University of Novi Sad., 43(1), 116.
https://hdl.handle.net/21.15107/rcub_ibiss_4253

Erić P, Patenković A, Erić K, Tanasić V, Mihajlović M, Tanasković M, Stanisavljević L, Davidović S. Large scale mitochondrial DNA analysis of European Honey bee (Apis mellifera) populations from the Balkans, population genetics and phylogeographic perspective. in Belgrade BioInformatics Conference 2021: Book of Abstracts; 2021 Jun 21-25; Vinča, Serbia. 2021;43(1):116.
https://hdl.handle.net/21.15107/rcub_ibiss_4253 .

Erić, Pavle, Patenković, Aleksandra, Erić, Katarina, Tanasić, Vanja, Mihajlović, Milica, Tanasković, Marija, Stanisavljević, Ljubiša, Davidović, Slobodan, "Large scale mitochondrial DNA analysis of European Honey bee (Apis mellifera) populations from the Balkans, population genetics and phylogeographic perspective" in Belgrade BioInformatics Conference 2021: Book of Abstracts; 2021 Jun 21-25; Vinča, Serbia, 43, no. 1 (2021):116,
https://hdl.handle.net/21.15107/rcub_ibiss_4253 .

TY  - JOUR
AU  - Davidović, Slobodan
AU  - Jelić, Mihailo
AU  - Marinković, Saša
AU  - Mihajlović, Milica
AU  - Tanasić, Vanja
AU  - Hribšek, Irena
AU  - Sušić, Goran
AU  - Dragićević, Milan
AU  - Stamenković-Radak, Marina
PY  - 2020
UR  - https://radar.ibiss.bg.ac.rs/handle/123456789/4016
AB  - The Griffon vulture was once a widespread species across the region of Southeast Europe, but it is now endangered and in some parts is completely extinct. In the Balkan Peninsula the largest Griffon vulture inland population inhabits the territory of Serbia. We present, for the first time, the genetic data of this valuable population that could be a source for future reintroduction programs planned in South‑eastern Europe. To characterize the genetic structure of this population we used microsatellite markers from ten loci. Blood samples were collected from 57 chicks directly in the nests during the ongoing monitoring program. We performed a comparative analysis of the obtained data with the existing data from three native populations from French Pyrenees, Croatia, and Israel. We have assessed the genetic differentiation between different native populations and determined the existence of two genetic clusters that differentiate the populations from the Balkan and Iberian Peninsulas. Furthermore, we analysed whether the recent bottleneck events influenced the genetic structure of the populations studied, and we found that all native populations experienced a recent bottleneck event, and that the population of Israel was the least affected. Nevertheless, the parameters of genetic diversity suggest that all analysed populations have retained a similar level of genetic diversity and that the Griffon vulture population from Serbia exhibits the highest value for private alleles. The results of this study suggest that the Griffon vulture populations of the Balkan Peninsula are genetically differentiated from the populations of the Iberian Peninsula, which is an important information for future reintroduction strategies.
PB  - Nature Research
T2  - Scientific Reports
T1  - Genetic diversity of the Griffon vulture population in Serbia and its importance for conservation efforts in the Balkans
IS  - 1
VL  - 10
DO  - 10.1038/s41598-020-77342-1
SP  - 20394
ER  - 

@article{
author = "Davidović, Slobodan and Jelić, Mihailo and Marinković, Saša and Mihajlović, Milica and Tanasić, Vanja and Hribšek, Irena and Sušić, Goran and Dragićević, Milan and Stamenković-Radak, Marina",
year = "2020",
abstract = "The Griffon vulture was once a widespread species across the region of Southeast Europe, but it is now endangered and in some parts is completely extinct. In the Balkan Peninsula the largest Griffon vulture inland population inhabits the territory of Serbia. We present, for the first time, the genetic data of this valuable population that could be a source for future reintroduction programs planned in South‑eastern Europe. To characterize the genetic structure of this population we used microsatellite markers from ten loci. Blood samples were collected from 57 chicks directly in the nests during the ongoing monitoring program. We performed a comparative analysis of the obtained data with the existing data from three native populations from French Pyrenees, Croatia, and Israel. We have assessed the genetic differentiation between different native populations and determined the existence of two genetic clusters that differentiate the populations from the Balkan and Iberian Peninsulas. Furthermore, we analysed whether the recent bottleneck events influenced the genetic structure of the populations studied, and we found that all native populations experienced a recent bottleneck event, and that the population of Israel was the least affected. Nevertheless, the parameters of genetic diversity suggest that all analysed populations have retained a similar level of genetic diversity and that the Griffon vulture population from Serbia exhibits the highest value for private alleles. The results of this study suggest that the Griffon vulture populations of the Balkan Peninsula are genetically differentiated from the populations of the Iberian Peninsula, which is an important information for future reintroduction strategies.",
publisher = "Nature Research",
journal = "Scientific Reports",
title = "Genetic diversity of the Griffon vulture population in Serbia and its importance for conservation efforts in the Balkans",
number = "1",
volume = "10",
doi = "10.1038/s41598-020-77342-1",
pages = "20394"
}

Davidović, S., Jelić, M., Marinković, S., Mihajlović, M., Tanasić, V., Hribšek, I., Sušić, G., Dragićević, M.,& Stamenković-Radak, M.. (2020). Genetic diversity of the Griffon vulture population in Serbia and its importance for conservation efforts in the Balkans. in Scientific Reports
Nature Research., 10(1), 20394.
https://doi.org/10.1038/s41598-020-77342-1

Davidović S, Jelić M, Marinković S, Mihajlović M, Tanasić V, Hribšek I, Sušić G, Dragićević M, Stamenković-Radak M. Genetic diversity of the Griffon vulture population in Serbia and its importance for conservation efforts in the Balkans. in Scientific Reports. 2020;10(1):20394.
doi:10.1038/s41598-020-77342-1 .

Davidović, Slobodan, Jelić, Mihailo, Marinković, Saša, Mihajlović, Milica, Tanasić, Vanja, Hribšek, Irena, Sušić, Goran, Dragićević, Milan, Stamenković-Radak, Marina, "Genetic diversity of the Griffon vulture population in Serbia and its importance for conservation efforts in the Balkans" in Scientific Reports, 10, no. 1 (2020):20394,
https://doi.org/10.1038/s41598-020-77342-1 . .

TY  - DATA
AU  - Davidović, Slobodan
AU  - Jelić, Mihailo
AU  - Marinković, Saša
AU  - Mihajlović, Milica
AU  - Tanasić, Vanja
AU  - Hribšek, Irena
AU  - Sušić, Goran
AU  - Dragićević, Milan
AU  - Stamenković-Radak, Marina
PY  - 2020
UR  - https://radar.ibiss.bg.ac.rs/handle/123456789/4183
AB  - Table S1. Parameters of genetic diversity calculated per locus per populations including Hardy-Weinberg equilibrium test and Garza Williamson index. Legend: N - number of gene copies, A - number of alleles, Ho – observed heterozygosity, He – expected heterozygosity, H-W - test for Hardy-Weinberg equilibrium, Ae - effective number of alleles, Ar - allelic range, G-W Garza-Williamson index; Table S2. Number of alleles per locus per populations; Table S3. Tables of significant linkage disequilibrium (significance level p=0.0500, corrected using sequential Bonferroni test). Detected linkage disequlibrium is marked with pink colour; Table S1. Effective population sizes estimated for analysed populations. Legend: N - number of individuals in sample, Ne - effective population size; Table S5. Outcomes of AMOVA analysis based on the variability of 10 autosomal loci for different groups of populations.
PB  - Nature Research
T2  - Scientific Reports
T1  - Supplementary tables for the article: Davidović S, Jelić M, Marinković S, Mihajlović M, Tanasić V, Hribšek I, Sušić G, Dragićević M, Stamenković-Radak M. Genetic diversity of the Griffon vulture population in Serbia and its importance for conservation efforts in the Balkans. Sci Rep. 2020;10(1):20394.
IS  - 1
VL  - 10
SP  - 20394
UR  - https://hdl.handle.net/21.15107/rcub_ibiss_4183
ER  - 

@misc{
author = "Davidović, Slobodan and Jelić, Mihailo and Marinković, Saša and Mihajlović, Milica and Tanasić, Vanja and Hribšek, Irena and Sušić, Goran and Dragićević, Milan and Stamenković-Radak, Marina",
year = "2020",
abstract = "Table S1. Parameters of genetic diversity calculated per locus per populations including Hardy-Weinberg equilibrium test and Garza Williamson index. Legend: N - number of gene copies, A - number of alleles, Ho – observed heterozygosity, He – expected heterozygosity, H-W - test for Hardy-Weinberg equilibrium, Ae - effective number of alleles, Ar - allelic range, G-W Garza-Williamson index; Table S2. Number of alleles per locus per populations; Table S3. Tables of significant linkage disequilibrium (significance level p=0.0500, corrected using sequential Bonferroni test). Detected linkage disequlibrium is marked with pink colour; Table S1. Effective population sizes estimated for analysed populations. Legend: N - number of individuals in sample, Ne - effective population size; Table S5. Outcomes of AMOVA analysis based on the variability of 10 autosomal loci for different groups of populations.",
publisher = "Nature Research",
journal = "Scientific Reports",
title = "Supplementary tables for the article: Davidović S, Jelić M, Marinković S, Mihajlović M, Tanasić V, Hribšek I, Sušić G, Dragićević M, Stamenković-Radak M. Genetic diversity of the Griffon vulture population in Serbia and its importance for conservation efforts in the Balkans. Sci Rep. 2020;10(1):20394.",
number = "1",
volume = "10",
pages = "20394",
url = "https://hdl.handle.net/21.15107/rcub_ibiss_4183"
}

Davidović, S., Jelić, M., Marinković, S., Mihajlović, M., Tanasić, V., Hribšek, I., Sušić, G., Dragićević, M.,& Stamenković-Radak, M.. (2020). Supplementary tables for the article: Davidović S, Jelić M, Marinković S, Mihajlović M, Tanasić V, Hribšek I, Sušić G, Dragićević M, Stamenković-Radak M. Genetic diversity of the Griffon vulture population in Serbia and its importance for conservation efforts in the Balkans. Sci Rep. 2020;10(1):20394.. in Scientific Reports
Nature Research., 10(1), 20394.
https://hdl.handle.net/21.15107/rcub_ibiss_4183

Davidović S, Jelić M, Marinković S, Mihajlović M, Tanasić V, Hribšek I, Sušić G, Dragićević M, Stamenković-Radak M. Supplementary tables for the article: Davidović S, Jelić M, Marinković S, Mihajlović M, Tanasić V, Hribšek I, Sušić G, Dragićević M, Stamenković-Radak M. Genetic diversity of the Griffon vulture population in Serbia and its importance for conservation efforts in the Balkans. Sci Rep. 2020;10(1):20394.. in Scientific Reports. 2020;10(1):20394.
https://hdl.handle.net/21.15107/rcub_ibiss_4183 .

Davidović, Slobodan, Jelić, Mihailo, Marinković, Saša, Mihajlović, Milica, Tanasić, Vanja, Hribšek, Irena, Sušić, Goran, Dragićević, Milan, Stamenković-Radak, Marina, "Supplementary tables for the article: Davidović S, Jelić M, Marinković S, Mihajlović M, Tanasić V, Hribšek I, Sušić G, Dragićević M, Stamenković-Radak M. Genetic diversity of the Griffon vulture population in Serbia and its importance for conservation efforts in the Balkans. Sci Rep. 2020;10(1):20394." in Scientific Reports, 10, no. 1 (2020):20394,
https://hdl.handle.net/21.15107/rcub_ibiss_4183 .

TY  - DATA
AU  - Davidović, Slobodan
AU  - Jelić, Mihailo
AU  - Marinković, Saša
AU  - Mihajlović, Milica
AU  - Tanasić, Vanja
AU  - Hribšek, Irena
AU  - Sušić, Goran
AU  - Dragićević, Milan
AU  - Stamenković-Radak, Marina
PY  - 2020
UR  - https://radar.ibiss.bg.ac.rs/handle/123456789/4017
AB  - Figure  S1Matrix  of the average number of pairwise differences and Nei's distances detected in native  and  introduced  G.  fulvus  populations  based  on  the  analysis  of  microsatellite  loci.  The  average  number  of  pairwise  differences  between  populations  is  presented  above  diagonal,  the  average  number  of  pairwise  differences  within  the  population  is  presented  diagonal  and  Nei's  distances  are  presented  below  diagonal.  The  average  number  of  pairwise  differences  are  presented in Table 1.; Figure S2 Matrix of pairwise FSTdistances between the G. fulvus population of Serbia and other native  and  introduced  G.  fulvus  populations  based  on  the  analysis  of  10  microsatellite  loci.Statist ically significant FST values are marked with an asterisk (*). Population pairwise FSTvalues are presented in Table 3.; Figure S3 Ln values of probability for the assumed number of genetic clusters. Figure S4   (a) Proportions of inferred STRUCTURE clusters (K=2) from the native and introduced populations.(b) Proportions of the inferred STRUCTURE clusters (K=2) from the individuals.
PB  - Nature Research
T2  - Scientific Reports
T1  - Supplementary figures for the article: Davidović S, Jelić M, Marinković S, Mihajlović M, Tanasić V, Hribšek I, Sušić G, Dragićević M, Stamenković-Radak M. Genetic diversity of the Griffon vulture population in Serbia and its importance for conservation efforts in the Balkans. Sci Rep. 2020;10(1):20394.
IS  - 1
VL  - 10
SP  - 20394
UR  - https://hdl.handle.net/21.15107/rcub_ibiss_4017
ER  - 

@misc{
author = "Davidović, Slobodan and Jelić, Mihailo and Marinković, Saša and Mihajlović, Milica and Tanasić, Vanja and Hribšek, Irena and Sušić, Goran and Dragićević, Milan and Stamenković-Radak, Marina",
year = "2020",
abstract = "Figure  S1Matrix  of the average number of pairwise differences and Nei's distances detected in native  and  introduced  G.  fulvus  populations  based  on  the  analysis  of  microsatellite  loci.  The  average  number  of  pairwise  differences  between  populations  is  presented  above  diagonal,  the  average  number  of  pairwise  differences  within  the  population  is  presented  diagonal  and  Nei's  distances  are  presented  below  diagonal.  The  average  number  of  pairwise  differences  are  presented in Table 1.; Figure S2 Matrix of pairwise FSTdistances between the G. fulvus population of Serbia and other native  and  introduced  G.  fulvus  populations  based  on  the  analysis  of  10  microsatellite  loci.Statist ically significant FST values are marked with an asterisk (*). Population pairwise FSTvalues are presented in Table 3.; Figure S3 Ln values of probability for the assumed number of genetic clusters. Figure S4   (a) Proportions of inferred STRUCTURE clusters (K=2) from the native and introduced populations.(b) Proportions of the inferred STRUCTURE clusters (K=2) from the individuals.",
publisher = "Nature Research",
journal = "Scientific Reports",
title = "Supplementary figures for the article: Davidović S, Jelić M, Marinković S, Mihajlović M, Tanasić V, Hribšek I, Sušić G, Dragićević M, Stamenković-Radak M. Genetic diversity of the Griffon vulture population in Serbia and its importance for conservation efforts in the Balkans. Sci Rep. 2020;10(1):20394.",
number = "1",
volume = "10",
pages = "20394",
url = "https://hdl.handle.net/21.15107/rcub_ibiss_4017"
}

Davidović, S., Jelić, M., Marinković, S., Mihajlović, M., Tanasić, V., Hribšek, I., Sušić, G., Dragićević, M.,& Stamenković-Radak, M.. (2020). Supplementary figures for the article: Davidović S, Jelić M, Marinković S, Mihajlović M, Tanasić V, Hribšek I, Sušić G, Dragićević M, Stamenković-Radak M. Genetic diversity of the Griffon vulture population in Serbia and its importance for conservation efforts in the Balkans. Sci Rep. 2020;10(1):20394.. in Scientific Reports
Nature Research., 10(1), 20394.
https://hdl.handle.net/21.15107/rcub_ibiss_4017

Davidović S, Jelić M, Marinković S, Mihajlović M, Tanasić V, Hribšek I, Sušić G, Dragićević M, Stamenković-Radak M. Supplementary figures for the article: Davidović S, Jelić M, Marinković S, Mihajlović M, Tanasić V, Hribšek I, Sušić G, Dragićević M, Stamenković-Radak M. Genetic diversity of the Griffon vulture population in Serbia and its importance for conservation efforts in the Balkans. Sci Rep. 2020;10(1):20394.. in Scientific Reports. 2020;10(1):20394.
https://hdl.handle.net/21.15107/rcub_ibiss_4017 .

Davidović, Slobodan, Jelić, Mihailo, Marinković, Saša, Mihajlović, Milica, Tanasić, Vanja, Hribšek, Irena, Sušić, Goran, Dragićević, Milan, Stamenković-Radak, Marina, "Supplementary figures for the article: Davidović S, Jelić M, Marinković S, Mihajlović M, Tanasić V, Hribšek I, Sušić G, Dragićević M, Stamenković-Radak M. Genetic diversity of the Griffon vulture population in Serbia and its importance for conservation efforts in the Balkans. Sci Rep. 2020;10(1):20394." in Scientific Reports, 10, no. 1 (2020):20394,
https://hdl.handle.net/21.15107/rcub_ibiss_4017 .

TY  - JOUR
AU  - Andrejević, Marko
AU  - Keckarević Marković, Milica
AU  - Bursać, Biljana
AU  - Mihajlović, Milica
AU  - Tanasić, Vanja
AU  - Kecmanović, Miljana
AU  - Keckarevic, Dušan
PY  - 2019
UR  - http://link.springer.com/10.1007/s12024-019-00096-4
UR  - https://radar.ibiss.bg.ac.rs/handle/123456789/3289
AB  - Mitochondrial DNA (mtDNA), especially the gene for cytochrome b (MT-CYB), has been found to be highly informative for species identification. In this study, we present the results of the analysis of a 127 bp long fragment of MT-CYB, amplified using universal primers, variable enough to be used for species identification and discrimination, even in highly degraded animal samples. The total number of analyzed species in this study was 30, including 17 mammalian and 13 bird species. Using a newly created primer pair, we successfully amplified and sequenced the target sequence in almost all tested species. The amplification was incomplete in just two species, and as a result, partial, but still variable sequences, were obtained. Using the target fragment we successfully identified all tested samples. Initial results suggested that the intraspecies genetic diversity of the target region, in all tested species, was low - from 0 to 4.72%. The interspecies genetic diversity of the target region, crucial for successful discrimination, showed relatively high diversity, ranging from 8.36% to 42.52%. Given its short length, the target region should be used for species determination, particularly in samples that are degraded or are low in DNA quantity.
T2  - Forensic Science, Medicine, and Pathology
T1  - Identification of a broad spectrum of mammalian and avian species using the short fragment of the mitochondrially encoded cytochrome b gene.
DO  - 10.1007/s12024-019-00096-4
ER  - 

@article{
author = "Andrejević, Marko and Keckarević Marković, Milica and Bursać, Biljana and Mihajlović, Milica and Tanasić, Vanja and Kecmanović, Miljana and Keckarevic, Dušan",
year = "2019",
abstract = "Mitochondrial DNA (mtDNA), especially the gene for cytochrome b (MT-CYB), has been found to be highly informative for species identification. In this study, we present the results of the analysis of a 127 bp long fragment of MT-CYB, amplified using universal primers, variable enough to be used for species identification and discrimination, even in highly degraded animal samples. The total number of analyzed species in this study was 30, including 17 mammalian and 13 bird species. Using a newly created primer pair, we successfully amplified and sequenced the target sequence in almost all tested species. The amplification was incomplete in just two species, and as a result, partial, but still variable sequences, were obtained. Using the target fragment we successfully identified all tested samples. Initial results suggested that the intraspecies genetic diversity of the target region, in all tested species, was low - from 0 to 4.72%. The interspecies genetic diversity of the target region, crucial for successful discrimination, showed relatively high diversity, ranging from 8.36% to 42.52%. Given its short length, the target region should be used for species determination, particularly in samples that are degraded or are low in DNA quantity.",
journal = "Forensic Science, Medicine, and Pathology",
title = "Identification of a broad spectrum of mammalian and avian species using the short fragment of the mitochondrially encoded cytochrome b gene.",
doi = "10.1007/s12024-019-00096-4"
}

Andrejević, M., Keckarević Marković, M., Bursać, B., Mihajlović, M., Tanasić, V., Kecmanović, M.,& Keckarevic, D.. (2019). Identification of a broad spectrum of mammalian and avian species using the short fragment of the mitochondrially encoded cytochrome b gene.. in Forensic Science, Medicine, and Pathology.
https://doi.org/10.1007/s12024-019-00096-4

Andrejević M, Keckarević Marković M, Bursać B, Mihajlović M, Tanasić V, Kecmanović M, Keckarevic D. Identification of a broad spectrum of mammalian and avian species using the short fragment of the mitochondrially encoded cytochrome b gene.. in Forensic Science, Medicine, and Pathology. 2019;.
doi:10.1007/s12024-019-00096-4 .

Andrejević, Marko, Keckarević Marković, Milica, Bursać, Biljana, Mihajlović, Milica, Tanasić, Vanja, Kecmanović, Miljana, Keckarevic, Dušan, "Identification of a broad spectrum of mammalian and avian species using the short fragment of the mitochondrially encoded cytochrome b gene." in Forensic Science, Medicine, and Pathology (2019),
https://doi.org/10.1007/s12024-019-00096-4 . .