@article{MTMT:33206793,
	title = {State and physiology behind personality in arthropods: a review},
	url = {https://m2.mtmt.hu/api/publication/33206793},
	author = {Rádai, Zoltán and Kiss, Johanna and Nagy, Nikoletta Andrea and Somogyi, Anna Ágnes and Fülöp, Attila and Tóth, Zsófia and Alexáné Babits, Melinda Dorottya and Németh, Zoltán},
	doi = {10.1007/s00265-022-03259-6},
	journal-iso = {BEHAV ECOL SOCIOBIOL},
	journal = {BEHAVIORAL ECOLOGY AND SOCIOBIOLOGY},
	volume = {76},
	unique-id = {33206793},
	issn = {0340-5443},
	abstract = {In the endeavour to understand the causes and consequences of the variation in animal personality, a wide range of studies were carried out, utilising various aspects to make sense of this biological phenomenon. One such aspect integrated the study of physiological traits, investigating hypothesised physiological correlates of personality. Although many of such studies were carried out on vertebrates (predominantly on birds and mammals), studies using arthropods (mainly insects) as model organisms were also at the forefront of this area of research. In order to review the current state of knowledge on the relationship between personality and the most frequently studied physiological parameters in arthropods, we searched for scientific articles that investigated this relationship. In our review, we only included papers utilising a repeated-measures methodology to be conceptually and formally concordant with the study of animal personality. Based on our literature survey, metabolic rate, thermal physiology, immunophysiology, and endocrine regulation, as well as exogenous agents (such as toxins) were often identified as significant affectors shaping animal personality in arthropods. We found only weak support for state-dependence of personality when the state is approximated by singular elements (or effectors) of condition. We conclude that a more comprehensive integration of physiological parameters with condition may be required for a better understanding of state’s importance in animal personality. Also, a notable knowledge gap persists in arthropods regarding the association between metabolic rate and hormonal regulation, and their combined effects on personality. We discuss the findings published on the physiological correlates of animal personality in arthropods with the aim to summarise current knowledge, putting it into the context of current theory on the origin of animal personality.},
	keywords = {physiology; Repeatability; Metabolic rate; hormonal regulation; State-dependent; condition; Consistent behaviour},
	year = {2022},
	eissn = {1432-0762},
	orcid-numbers = {Rádai, Zoltán/0000-0001-7011-5055; Fülöp, Attila/0000-0001-5337-336X}
}

@article{MTMT:32989738,
	title = {Seasonal variation of genotypes and reproductive plasticity in a facultative clonal freshwater invertebrate animal ( Hydra oligactis ) living in a temperate lake},
	url = {https://m2.mtmt.hu/api/publication/32989738},
	author = {Miklós, Máté and Laczkó, Levente and Sramkó, Gábor and Barta, Zoltán and Tökölyi, Jácint},
	doi = {10.1002/ece3.9096},
	journal-iso = {ECOL EVOL},
	journal = {ECOLOGY AND EVOLUTION},
	volume = {12},
	unique-id = {32989738},
	issn = {2045-7758},
	abstract = {Facultative sexual organisms combine sexual and asexual reproduction within a single
		life cycle, often switching between reproductive modes depending on environmental conditions. These organisms frequently inhabit variable seasonal environments,
		where favorable periods alternate with unfavorable periods, generating temporally
		varying selection pressures that strongly influence life history decisions and hence
		population dynamics. Due to the rapidly accelerating changes in our global environment today, understanding the population dynamics and genetic changes in facultative sexual populations inhabiting seasonal environments is critical to assess and
		prepare for additional challenges that will affect such ecosystems. In this study, we
		aimed at obtaining insights into the seasonal population dynamics of the facultative
		sexual freshwater cnidarian Hydra oligactis through a combination of restriction siteassociated sequencing (RAD-Seq) genotyping and the collection of phenotypic data
		on the reproductive strategy of field-collected hydra strains in a standard laboratory
		environment. We reliably detected 42 MlGs from the 121 collected hydra strains.
		Most of MLGs (N = 35, 83.3%) were detected in only one season. Five MLGs (11.9%)
		were detected in two seasons, one (2.4%) in three seasons and one (2.4%) in all four
		seasons. We found no significant genetic change during the 2 years in the study population. Clone lines were detected between seasons and even years, suggesting that
		clonal lineages can persist for a long time in a natural population. We also found that
		distinct genotypes differ in sexual reproduction frequency, but these differences did
		not affect whether genotypes reappeared across samplings. Our study provides key
		insights into the biology of natural hydra populations, while also contributing to understanding the population biology of facultative sexual species inhabiting freshwater
		ecosystems.},
	keywords = {phenotypic plasticity; RAD-seq; population genomics; Clonal reproduction},
	year = {2022},
	eissn = {2045-7758},
	orcid-numbers = {Miklós, Máté/0000-0001-8976-2359; Laczkó, Levente/0000-0002-9379-7527; Sramkó, Gábor/0000-0001-8588-6362; Barta, Zoltán/0000-0002-7121-9865}
}

@article{MTMT:32930486,
	title = {OpenBioMaps - self-hosted data management platform and distributed service for biodiversity related data},
	url = {https://m2.mtmt.hu/api/publication/32930486},
	author = {Bán, Miklós and Bóné, Gábor Máté and Bérces, Sándor and Barta, Zoltán and Kovács, István and Ecsedi, Kornel and Sipos, Katalin},
	doi = {10.1007/s12145-022-00818-3},
	journal-iso = {EARTH SCI INF},
	journal = {EARTH SCIENCE INFORMATICS},
	volume = {15},
	unique-id = {32930486},
	issn = {1865-0473},
	abstract = {Biodiversity related observational data are collected in a variety of ways and for a variety of purposes, mostly in the form of some sort of organised data collection action. Data management solutions are often developed to manage the data collection processes and organise the data, which may work well on their own but are less compatible with other data management tools. In a continuous development process, we have created the OpenBioMaps (OBM) biodiversity data management platform, which can be used as a self-hosted data management platform and as a free service, hosted by several institutions for biological database projects. OBM has the ability to integrate biological databases without any structural or functional constraints, allowing a high degree of flexibility in data management and development; it provides interfaces to facilitate communication between different end-user communities, including scientists, citizens, conservationists and educational staff. We have also established a network of OBM services based on collaboration between government, educational and scientific institutions and NGOs to provide a public service to those who lack the capacity or knowledge to set up or manage their own self-hosted servers. OpenBioMaps uniquely focuses on the entire data management process, from building the data structure to data collection, visualisation, sharing and processing.},
	keywords = {Biodiversity database data-workflow data-management repository data-collecting},
	year = {2022},
	eissn = {1865-0481},
	pages = {2007-2016},
	orcid-numbers = {Bán, Miklós/0000-0002-6275-7928; Bérces, Sándor/0000-0003-2920-8756; Barta, Zoltán/0000-0002-7121-9865; Kovács, István/0000-0002-9720-9825}
}

@article{MTMT:32772139,
	title = {Biological Earth observation with animal sensors},
	url = {https://m2.mtmt.hu/api/publication/32772139},
	author = {Jetz, Walter and Tertitski, Grigori and Kays, Roland and Mueller, Uschi and Wikelski, Martin and Åkesson, Susanne and Anisimov, Yury and Antonov, Aleksey and Arnold, Walter and Bairlein, Franz and Baltà, Oriol and Baum, Diane and Beck, Mario and Belonovich, Olga and Belyaev, Mikhail and Berger, Matthias and Berthold, Peter and Bittner, Steffen and Blake, Stephen and Block, Barbara and Bloche, Daniel and Boehning-Gaese, Katrin and Bohrer, Gil and Bojarinova, Julia and Bommas, Gerhard and Bourski, Oleg and Bragin, Albert and Bragin, Alexandr and Bristol, Rachel and Brlík, Vojtěch and Bulyuk, Victor and Cagnacci, Francesca and Carlson, Ben and Chapple, Taylor K. and Chefira, Kalkidan F. and Cheng, Yachang and Chernetsov, Nikita and Cierlik, Grzegorz and Christiansen, Simon S. and Clarabuch, Oriol and Cochran, William and Cornelius, Jamie Margaret and Couzin, Iain and Crofoot, Margret C. and Cruz, Sebastian and Davydov, Alexander and Davidson, Sarah and Dech, Stefan and Dechmann, Dina and Demidova, Ekaterina and Dettmann, Jan and Dittmar, Sven and Dorofeev, Dmitry and Drenckhahn, Detlev and Dubyanskiy, Vladimir and Egorov, Nikolay and Ehnbom, Sophie and Ellis-Soto, Diego and Ewald, Ralf and Feare, Chris and Fefelov, Igor and Fiedler, Wolfgang and Flack, Andrea and Froböse, Magnus and Fufachev, Ivan and Futoran, Pavel and Gabyshev, Vyachaslav and Gagliardo, Anna and Garthe, Stefan and Gashkov, Sergey and Gibson, Luke and Goymann, Wolfgang and Gruppe, Gerd and Guglielmo, Chris and Hartl, Phil and Hedenström, Anders and Hegemann, Arne and Heine, Georg and Ruiz, Mäggi Hieber and Hofer, Heribert and Huber, Felix and Iannarilli, Fabiola and Illa, Marc and Isaev, Arkadiy and Jakobsen, Bent and Jenni, Lukas and Jenni-Eiermann, Susi and Jesmer, Brett and Jiguet, Frédéric and Karimova, Tatiana and Kasdin, N. Jeremy and Kazansky, Fedor and Kirillin, Ruslan and Klinner, Thomas and Knopp, Andreas and Kölzsch, Andrea and Kondratyev, Alexander and Krondorf, Marco and Ktitorov, Pavel and Kulikova, Olga and Kumar, R. Suresh and Künzer, Claudia and Larionov, Anatoliy and Larose, Christine and Liechti, Felix and Linek, Nils and Lohr, Ashley and Lushchekina, Anna and Mansfield, Kate and Matantseva, Maria and Markovets, Mikhail and Marra, Peter and Masello, Juan F. and Melzheimer, Jörg and Menz, Myles H.M. and Menzie, Stephen and Meshcheryagina, Swetlana and Miquelle, Dale and Morozov, Vladimir and Mukhin, Andrey and Müller, Inge and Mueller, Thomas and Navedo, Juan G. and Nathan, Ran and Nelson, Luke and Németh, Zoltán and Newman, Scott and Norris, Ryan and Okhlopkov, Innokentiy and Oleś, Wioleta and Oliver, Ruth and O’Mara, Teague and Palatitz, Peter and Partecke, Jesko and Pavlick, Ryan and Pedenko, Anastasia and Pham, Julie and Piechowski, Daniel and Pierce, Allison and Piersma, Theunis and Pitz, Wolfgang and Plettemeier, Dirk and Pokrovskaya, Irina and Pokrovskaya, Liya and Pokrovsky, Ivan and Pot, Morrison and Procházka, Petr and Quillfeldt, Petra and Rakhimberdiev, Eldar and Ramenofsky, Marilyn and Ranipeta, Ajay and Rapczyński, Jan and Remisiewicz, Magdalena and Rozhnov, Viatcheslav and Rienks, Froukje and Rozhnov, Vyacheslav and Rutz, Christian and Sakhvon, Vital and Sapir, Nir and Safi, Kamran and Schäuffelhut, Friedrich and Schimel, David and Schmidt, Andreas and Shamoun-Baranes, Judy and Sharikov, Alexander and Shearer, Laura and Shemyakin, Evgeny and Sherub, Sherub and Shipley, Ryan and Sica, Yanina and Smith, Thomas B. and Simonov, Sergey and Snell, Katherine and Sokolov, Aleksandr and Sokolov, Vasiliy and Solomina, Olga and Soloviev, Mikhail and Spina, Fernando and Spoelstra, Kamiel and Storhas, Martin and Sviridova, Tatiana and Swenson, George and Taylor, Phil and Thorup, Kasper and Tsvey, Arseny and Tucker, Marlee and Turner, Woody and van der Jeugd, Henk and van Schalkwyk, Louis and van Toor, Mariëlle and Viljoen, Pauli and Visser, Marcel E. and Volkmer, Tamara and Volkov, Andrei and Volkov, Sergey and Volkov, Oleg and von Rönn, Jan A.C. and Vorneweg, Bernd and Wachter, Bettina and Waldenström, Jonas and Wegmann, Martin and Wehr, Aloysius and Weinzierl, Rolf and Weppler, Johannes and Wilcove, David and Wild, Timm and Williams, Hannah J. and Wilshire, John and Wingfield, John and Wunder, Michael and Yachmennikova, Anna and Yanco, Scott and Yohannes, Elisabeth and Zeller, Amelie and Ziegler, Christian and Zięcik, Anna and Zook, Cheryl},
	doi = {10.1016/j.tree.2021.11.011},
	journal-iso = {TRENDS ECOL EVOL},
	journal = {TRENDS IN ECOLOGY & EVOLUTION},
	volume = {37},
	unique-id = {32772139},
	issn = {0169-5347},
	year = {2022},
	eissn = {1872-8383},
	pages = {293-298},
	orcid-numbers = {Jetz, Walter/0000-0002-1971-7277}
}

@article{MTMT:32756575,
	title = {Range-wide phylogeography of the flightless steppe beetle Lethrus apterus (Geotrupidae) reveals recent arrival to the Pontic Steppes from the west},
	url = {https://m2.mtmt.hu/api/publication/32756575},
	author = {Sramkó, Gábor and Kosztolányi, András and Laczkó, Levente and Rácz, Rita and Szatmári, Lajos and Varga, Zoltán Sándor and Barta, Zoltán},
	doi = {10.1038/s41598-022-09007-0},
	journal-iso = {SCI REP},
	journal = {SCIENTIFIC REPORTS},
	volume = {12},
	unique-id = {32756575},
	issn = {2045-2322},
	year = {2022},
	eissn = {2045-2322},
	orcid-numbers = {Sramkó, Gábor/0000-0001-8588-6362; Kosztolányi, András/0000-0002-9109-5871; Barta, Zoltán/0000-0002-7121-9865}
}

@article{MTMT:32743334,
	title = {Population Differences and Host Species Predict Variation in the Diversity of Host-Associated Microbes in Hydra},
	url = {https://m2.mtmt.hu/api/publication/32743334},
	author = {Taubenheim, Jan and Miklós, Máté and Tökölyi, Jácint and Fraune, Sebastian},
	doi = {10.3389/fmicb.2022.799333},
	journal-iso = {FRONT MICROBIOL},
	journal = {FRONTIERS IN MICROBIOLOGY},
	volume = {13},
	unique-id = {32743334},
	issn = {1664-302X},
	year = {2022},
	eissn = {1664-302X},
	orcid-numbers = {Miklós, Máté/0000-0001-8976-2359}
}

@article{MTMT:32287496,
	title = {Tumors (re)shape biotic interactions within ecosystems: Experimental evidence from the freshwater cnidarian Hydra},
	url = {https://m2.mtmt.hu/api/publication/32287496},
	author = {Boutry, Justine and Mistral, Juliette and Berlioz, Laurent and Klimovich, Alexander and Tökölyi, Jácint and Fontenille, Laura and Ujvari, Beata and Dujon, Antoine M. and Giraudeau, Mathieu and Thomas, Frédéric},
	doi = {10.1016/j.scitotenv.2021.149923},
	journal-iso = {SCI TOTAL ENVIRON},
	journal = {SCIENCE OF THE TOTAL ENVIRONMENT},
	volume = {803},
	unique-id = {32287496},
	issn = {0048-9697},
	abstract = {While it is often assumed that oncogenic processes in metazoans can influence species interactions, empirical evidence is lacking. Here, we use the cnidarian Hydra oligactis to experimentally explore the consequences of tumor associated phenotypic alterations for its predation ability, relationship with commensal ciliates and vulnerability to predators. Unexpectedly, hydra's predation ability was higher in tumorous polyps compared to non-tumorous ones. Commensal ciliates colonized preferentially tumorous hydras than non-tumorous ones, and had a higher replication rate on the former. Finally, in a choice experiment, tumorous hydras were preferentially eaten by a fish predator. This study, for the first time, provides evidence that neoplastic growth has the potential, through effect(s) on host phenotype, to alter biotic interactions within ecosystems and should thus be taken into account by ecologists.},
	year = {2022},
	eissn = {1879-1026}
}

@article{MTMT:32549653,
	title = {Regulatory modules of human thermogenic adipocytes: functional genomics of large cohort and Meta-analysis derived marker-genes},
	url = {https://m2.mtmt.hu/api/publication/32549653},
	author = {Bartáné Tóth, Beáta and Barta, Zoltán and Barta, Ákos Barnabás and Fésüs, László},
	doi = {10.1186/s12864-021-08126-8},
	journal-iso = {BMC GENOMICS},
	journal = {BMC GENOMICS},
	volume = {22},
	unique-id = {32549653},
	issn = {1471-2164},
	year = {2021},
	eissn = {1471-2164},
	orcid-numbers = {Barta, Zoltán/0000-0002-7121-9865}
}

@article{MTMT:32508569,
	title = {Conservation biology research priorities for 2050. A Central-Eastern European perspective},
	url = {https://m2.mtmt.hu/api/publication/32508569},
	author = {Csákvári, Edina and Fabók, Veronika and Bartha, Sándor and Barta, Zoltán and Batáry, Péter and Borics, Gábor and Botta-Dukát, Zoltán and Erős, Tibor and Gáspár, Judit and Hideg, Éva and Kovács-Hostyánszki, Anikó and Sramkó, Gábor and Standovár, Tibor and Lengyel, Szabolcs and Liker, András and Magura, Tibor and Márton, András and Molnár, V. Attila and Molnár, Zsolt and Oborny, Beáta and Ódor, Péter and Tóthmérész, Béla and Török, Katalin and Török, Péter and Valkó, Orsolya and Szép, Tibor and Vörös, Judit and Báldi, András},
	doi = {10.1016/j.biocon.2021.109396},
	journal-iso = {BIOL CONSERV},
	journal = {BIOLOGICAL CONSERVATION},
	volume = {264},
	unique-id = {32508569},
	issn = {0006-3207},
	year = {2021},
	eissn = {1873-2917},
	orcid-numbers = {Bartha, Sándor/0000-0001-6331-7521; Barta, Zoltán/0000-0002-7121-9865; Batáry, Péter/0000-0002-1017-6996; Botta-Dukát, Zoltán/0000-0002-9544-3474; Gáspár, Judit/0000-0003-1908-1616; Sramkó, Gábor/0000-0001-8588-6362; Standovár, Tibor/0000-0002-4686-3456; Lengyel, Szabolcs/0000-0002-7049-0100; Liker, András/0000-0001-8545-4869; Oborny, Beáta/0000-0003-2997-9921; Ódor, Péter/0000-0003-1729-8897; Valkó, Orsolya/0000-0001-7919-6293; Vörös, Judit/0000-0001-9707-1443; Báldi, András/0000-0001-6063-3721}
}

@article{MTMT:32237729,
	title = {Seasonal variation in sexual readiness in a facultatively sexual freshwater cnidarian with diapausing eggs},
	url = {https://m2.mtmt.hu/api/publication/32237729},
	author = {Tökölyi, Jácint and Gergely, Réka and Miklós, Máté},
	doi = {10.1002/ecs2.3713},
	journal-iso = {ECOSPHERE},
	journal = {ECOSPHERE},
	volume = {12},
	unique-id = {32237729},
	issn = {2150-8925},
	abstract = {Facultative sexuality combines clonal propagation with sexual reproduction within a single life cycle. Clonal propagation enables quick population growth and the occupancy of favorable habitats. Sex, on the contrary, results in the production of offspring that are more likely to survive adverse conditions (such as the resting eggs of many freshwater invertebrates). In seasonal environments, the timing of sex is often triggered by environmental cues signaling the onset of winter (e.g., temperature drop or changes in photoperiod). Organisms switching to sex to produce resting eggs under these conditions face a trade-off: Responding too early to an environmental cue increases the chances of missing out in clonal propagation, while having a delayed response to deteriorating conditions entails the risk of parental mortality before sexual reproduction could be completed. To mitigate these risks, increased sensitivity toward environmental cues with the onset of the winter might be an adaptive strategy. To test this hypothesis, we investigated sexual propensity and time to gonadogenesis in clonal strains derived from spring- and autumn-collected polyps of Hydra oligactis, a facultatively sexual freshwater cnidarian where sex only occurs prior to the onset of winter. We show that autumn-collected individuals and their asexual offspring have a higher propensity for sex and require less time for gonad development compared with strains established from spring-collected individuals that were kept under similar conditions in the laboratory. To see whether the above results can be explained by phenotypic plasticity in sexual readiness, we exposed cold-adapted laboratory strains to different lengths of warm periods. We found that sexual propensity increases with warm exposure. Our results suggest that reciprocal cold and warm periods are required for sex induction in H. oligactis, which would ensure proper timing of sex in this species. Increased sensitivity to environmental deterioration might help maximize fitness in environments that have both a predictable (seasonal) and an unpredictable component.},
	keywords = {seasonality; sexual development; PREDICTABILITY; Clonal reproduction; Hydra; Germline stem cells; EcoEvoDevo},
	year = {2021},
	eissn = {2150-8925},
	orcid-numbers = {Miklós, Máté/0000-0001-8976-2359}
}